harvard university doctoral thesis

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Start with  HOLLIS  (HarvardKey login required for some full text, including theses & dissertations)

• Those presented for graduate degrees 
• Bowdoin prize essays 
• Undergraduate honors theses

How do you know if it's available online? 

• “View Online” button links out to full text.
• If there's no "View Online" button, the work probably has not been digitized.

What Harvard theses and dissertations can you expect to find online in full text? How do you get to them?

• Follow the links in HOLLIS.
• Not a Harvard affiliate? log in through the library of your academic institution OR
• you can usually purchase directly from  ProQuest Dissertations and Theses Express.  
• undergraduates are not required to submit theses or prizewinning papers to DASH
• Harvard Extension School ALM theses 2012-2016 were not entered into DASH. 
• Under certain circumstances dissertations may be embargoed by the author; DASH may be the only place this information is given.

If the work hasn't been digitized:

You can order PDFs or photocopies of most Harvard theses and dissertations (unless they're available through the Proquest database linked above) from 1873 through November 2011 (and ALM theses to 2016) 

• See our Reproduction Requests page to register
• When you submit the online order form, Imaging Services staff will reply with cost and delivery information.
• Questions about the online ordering process or pricing? Contact Imaging Services staff directly for additional information at 617/495-3995  or [email protected] (M-F, 9-5 Eastern) ​

For Extension School ALM theses  check out our  Library Guide for Harvard Extension School theses page

Want to view a dissertation or thesis at the library? Check with the archival collection location listed in HOLLIS.

Wondering what dissertations and theses have been submitted in the recent past?  Use DASH .

For more on undergraduate theses and dissertations, see our " How can I locate a Harvard undergraduate thesis?" FAQ.

Looking for non-Harvard theses & dissertations? See our "How can I find theses and dissertations?"  FAQ.

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Dissertations

Most Harvard PhD dissertations from 2012 forward are available online in DASH , Harvard’s central open-access repository and are linked below. Many older dissertations can be found on ProQuest Dissertation and Theses Search which many university libraries subscribe to.

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• ProQuest Dissertations and Theses Global (AKA Dissertation Abstracts) Full text of graduate works added since 1997, along with selected full text for works written prior to 1997 and citations for dissertations and theses dating from 1743-present.
• DASH (Digital Access to Scholarship at Harvard) A central, open-access repository of research (including dissertations and scholarly articles) by members of the Harvard community.
• Doctoral Dissertations in Musicology - Online (DDM) A bibliography of completed dissertations and proposed topics in musicology, music theory, ethnomusicology, and related disciplines. Maintained by the American Musicological Society.
• MTO Dissertation Index An index of dissertations in music theory, with abstracts and tables of contents, maintained by the Society for Music Theory.
• << Previous: Collected Works Editions
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Doctoral Thesis Guidelines

Introduction

Preparing to Submit the Thesis

Application for the Degree Oral Final Examination – Signature Page

Online Submission of the Thesis

ETDs @ ProQuest ORCID Harvard Author Agreement Redaction Embargoes Surveys

Distribution of the Thesis

Open Access After Submission Bound Thesis Fee Additional Bound Copies

Copyright and Publishing Considerations

Understanding Your Copyright and Fair Use Copyright Registration Acknowledging the Work of Others Use of Copyrighted Material Steps for Using Published and To-Be Published Work

Formatting Guidelines

Text Margins Pagination Title Title Page Abstract Body of Thesis Figures and Tables Footnotes Bibliography Supplemental Material  

Citation & Style Guides

Thesis Submission Checklist

INTRODUCTION All DrPH degree candidates at the Harvard Chan School are required to successfully complete and submit a thesis to qualify for degree conferral. This website provides information on the requirements for how to format your thesis, how to submit your thesis, and how your thesis will be distributed.  Please follow the submission and formatting guidelines provided here. Back to top

PREPARING TO SUBMIT THE THESIS The electronic submission of your thesis and the original Signature Page are due on the dates specified on the Harvard Chan School’s Academic Calendar Summary for each degree awarding period (November, March, and May). These items must be submitted using the ETDs @ ProQuest tool in order for the degree to be voted. No exceptions will be made to this rule. Back to top

Application for the Degree There are three degree granting periods: November, March, and May. To apply for graduation, students must complete the Application for Degree on the my.Harvard portal by the deadline posted on the Harvard Chan School’s Academic Calendar .

Deadline extensions are not possible. Students who miss the deadline must apply for the subsequent degree conferral date (November, March, or May). The student is responsible for meeting submission deadlines. Back to top

Oral Final Examination — Signature Page All Doctoral Committee members are required to sign the Signature Page at the time of the Doctoral Final Oral Examination indicating their final approval of the thesis.

A scanned copy of the Signature Page should appear before the title page of the PDF online submission of the thesis; no page number should be assigned to the Signature Page. The title on the Signature Page must read exactly as it does on the title page of the thesis. The Signature Page will be included in all copies of the thesis.

Click here for instructions on how to merge the Signature Page into the thesis PDF.

The Signature Page for DrPH students must be formatted as follows:

This Doctoral Thesis, [ Title of Doctoral Project ], presented by [ Student’s Name ], and Submitted to the Faculty of The Harvard T.H. Chan School of Public Health in Partial Fulfillment of the Requirements for the Degree of Doctor of Public Health , has been read and approved by:

______________________________________ (typed name below line – signature above)

________________________________________ (typed name below the line – signature above)

Date : [ Doctoral Project Official Approval Date (month day, year) ]

Back to top

ONLINE SUBMISSION OF THE THESIS  

ETDs @ ProQuest All DrPH candidates are required to submit a digital copy of the thesis to the Registrar’s Office as a PDF file via ETDs @ ProQuest by the deadline established for each degree conferral date. Theses must be submitted in their final format, as described in the section Formatting Guidelines . Students must check their formatting carefully before submitting. Formatting errors will prevent the students’ theses from being accepted and approved.

The online-submission tool can be found at:  http://www.etdadmin.com/hsph.harvard

A how-to video for submitting a thesis via ETDs is available on the Countway Library website .

ORCID ETDs @ ProQuest supports ORCIDs.  ORCIDs are persistent digital identifiers that link you to your professional activity.  You may register for an ORCID either before or during submission if you do not yet have one.  To do so, you may go here .

The Harvard Library ORCID page provides information about the value of having an ORCID iD and how Harvard plans to use ORCID data. Additionally, please visit the Harvard ORCID Connect site to connect your existing ORCID iD to Harvard University.

Harvard Author Agreement When submitting work through ETDs @ ProQuest, you will be consenting to the Harvard Author Agreement , which grants the University a non-exclusive license to preserve, reproduce, and display the work. This license, which is the same the Harvard Chan School faculty use under the School’s Open Access Policy, does not constrain your rights to publish your work subsequently. Back to top

Redaction Very few theses require redaction, which is the process of obscuring or removing sensitive information for distribution. ETDs @ ProQuest does support redacted versioning for these very rare cases where there is sensitive or potentially harmful material in the thesis (e.g., commercially sensitive information, sensitive personal data, risk of harmful retribution, etc.).

If your work is one such rare instance, then you may select the “I think I need to submit a redacted version of my thesis” on the file upload screen. You will then be prompted to contact the Office for Scholarly Communication, which will help you with your request. Back to top

Embargoes To forestall any potential challenges that a student may face in the publication process (e.g., if the candidate has a publication pending with a publisher or has previously published some of the content in the thesis and there is a publisher’s embargo that must be honored), the Harvard Chan School has instituted a default one-year embargo for submissions through ETDs @ ProQuest.   The embargo starts on the date of the thesis submission deadline. With an embargo, the full text of the thesis will be unavailable for view or download for a limited period of time.  The citation and abstract for the work, however, will be publicly available.

If a student would like to make her/his work available immediately by opting out of the embargo process, she/he may do so by selecting the No Embargo option during the submission process.

If, due to extenuating circumstances, a student is required to embargo part or all of their work beyond one year, she/he must request an extension during the submission process. An extension can be requested for up to two years. This request is subject to the approval of the student’s department chair(s) and the University Librarian.

Any embargo applied to the DASH version of the thesis will be applied to the Countway Library and Harvard Chan School department versions of the work.

Students do not need to take any action to remove an embargo.  The embargo will automatically be lifted in DASH at the end of the selected and approved period.  If a student would like to change the duration of his/her embargo request, then please contact the Registrar’s Office at [email protected] or 617-432-1032. Back to top

Surveys The School of Public Health is asked to participate in the Survey of Earned Doctorates. This is an annual census of research doctorate recipients in the United States.  Data collected from these surveys are used to make federal policy decisions regarding graduate education.

Students are required to complete the Survey of Earned Doctorates upon submission of their thesis. A Certificate of Completion will be sent to you, as well as to the Registrar’s Office.

Please click here to complete your survey.

DISTRIBUTION OF THE THESIS

Open Access For information on open access, we recommend the Office of Scholarly Communication’s (OSC) Director Peter Suber’s brief introduction . He has also written about providing open access to theses . The OSC has produced several videos of Harvard faculty and students discussing open access. Two may be of particular interest: the first features Professors Gary King and Stuart Shieber , and the second features a recent Harvard graduate, Ben Finio . Back to top

After Submission Once you have applied for your degree and submitted your thesis online, it is checked for compliance by the Registrar’s Office and, if accepted, is piped to the following downstream systems:

• DASH : Your work will be sent to DASH (Digital Access to Scholarship at Harvard), Harvard’s open access repository. Search engines index DASH, which means your work will be more discoverable and more frequently cited. You will be making DASH access decisions for your work at the point of submission. This will be the access copy of the thesis.
• HOLLIS : The metadata about your work will be sent to HOLLIS . This will make your work discoverable through the Harvard Library catalog.
• DRS2 : Your work will be stored in Harvard Library’s digital preservation repository, DRS2 . This will be the preservation copy of the thesis.

By default, theses will be made available through DASH one year after students submit their theses via ETDs @ Harvard for degree completion (see Embargoes ). DASH is operated by Harvard Library’s Office for Scholarly Communication and is the University’s central service for openly distributing Harvard’s scholarly output.

Note that any embargo applied to the DASH version of the thesis will be applied to the Countway Library and department versions of the work. Back to top

Bound Thesis Fee Currently we are not receiving bound thesis copies.  Doctoral students will not be charged bound thesis fees. Back to top

Additional Bound Copies Students may secure extra copies of their work for their own purposes.  These additional copies may be purchased through  Acme Bookbinding . or through ETDs @ ProQuest . Back to top

COPYRIGHT AND PUBLISHING CONSIDERATIONS

Understanding Your Copyright and Fair Use The Office for Scholarly Communication has created copyright-related resources for your reference.

The first addresses your copyrights and identifies some considerations when publishing (see “ Planning to publish? ”). It is important that you envision any future use you may like to make of your work. Any publishing contract you sign can affect your potential future uses, such as use in teaching, posting your work online on either a personal or departmental website, or any potential future publication. Before you sign a publication agreement, you can negotiate with a publisher to secure licensing terms that best suit your needs. It is important that you read any contract you sign and keep a copy for your own records.

The second resource discusses fair use (see “ Fair use ”), what it is, the laws that have determined its shape over time, and tips for ensuring that use of third-party material (including quotes, images, music, film, etc.) in your thesis is fair. Back to top

Copyright Registration Your work is copyrighted as soon as it is fixed in a tangible form. You are not required to register your copyright with the U.S. Copyright Office to enjoy protection of your work. However, if you choose to do so, you may register your work with the Copyright Office online . Back to top

Acknowledging the Work of Others Students are responsible for acknowledging any facts, ideas, or materials of others used in their own work. Students should refer to the statement on Academic Dishonesty and Plagiarism in the Harvard Chan School’s Student Handbook . Back to top

Use of Copyrighted Material A thesis is a scholarly work, and as such use of third party material is often essential. Fair use applies to the reproduction of any third party material, including your own previously published work, that you may use in your thesis.

If you have questions about copyright and fair use, please contact the Office for Scholarly Communication . Back to top

Steps for Using Published and To-Be Published Work When submitting an article for publication that you intend to use in your thesis, you should secure permission to do so (along with permission to reuse your own work as you would like) from your publisher in your publishing agreement. If the default contract does not let you retain these rights already, then you should use an author addendum to secure these rights (see “ Planning to publish? ”).

You may use your own previously published material as part of your thesis with the permission of the publisher. Again, refer to your publication agreement for details. If your contract does not specify these rights, then contact the publisher to negotiate this use. Back to top

FORMATTING GUIDELINES The following are instructions on how to format your thesis. If, after reading the instructions here, you have additional questions about the requirements, please contact the Registrar’s Office at (617) 432-1032; [email protected]. Back to top

Text   All text should be double-spaced on one side of the page with footnotes single-spaced. The font size should be at least 10 point, but no larger than 12 point.  The font and font size should be consistent throughout.  All text should be black. Back to top  |  Back to Formatting Guidelines

Margins The margins of the thesis must be 1 inch on all sides. Back to top  |  Back to Formatting Guidelines

Pagination Students’ theses must follow the pagination guidelines as illustrated below. It is customary not to have a page number on the page containing a chapter/paper heading. Drawings, charts, graphs, and photographs should be referred to as figures and should be numbered consecutively within the text of the thesis with Arabic numerals. Each figure should carry a suitable caption; e.g., Fig. 42. Arrangement of Experimental Equipment. Check pagination carefully and account for all pages.

All page numbers should be consecutive and centered at either the bottom or top of the page.
 Back to top  |  Back to Formatting Guidelines

Title The title of the thesis should be brief and should indicate the general subject treated. Nine words are usually sufficient to describe the investigation. Students are strongly encouraged to embed keywords into their title, so that the title will be retrievable on computerized listings. Back to top  |  Back to Formatting Guidelines

Title Page The title page must contain the following information, well-spaced and centered on the page:

For DrPH Students:

TITLE OF DOCTORAL THESIS

STUDENT’S NAME

A Doctoral Thesis Submitted to the Faculty of

The Harvard T.H. Chan School of Public Health

in Partial Fulfillment of the Requirements

for the Degree of Doctor of Public Health

Harvard University

Boston, Massachusetts.

Date (the month in which degree will be awarded, year of graduation (e.g., May 2021)

Back to top  |  Back to Formatting Guidelines

Abstract The abstract should not exceed 350 words. It should immediately follow the Title Page, and should state the problem, describe the methods and procedures used, and give the main results or conclusions of the research. The abstract should be double-spaced. The author’s name and the title of the thesis, as well as the name of the thesis advisor, should be included on the abstract page. The author’s name should be right justified, the title of the thesis centered, and “Thesis Advisor: Dr. ____________” should be left-justified at the top of the abstract page.

Thesis Advisor: Dr. [Advisor’s name]                                                    [Author’s name]

[Title of thesis]

           The text of the abstract, not to exceed 350 words, should be double-spaced.  The first line of each paragraph is indented.  Full justification of the text is not recommended.

Students will also be required to submit a text version of the abstract via the online-submission tool. Back to top  |  Back to Formatting Guidelines

Body of Thesis The thesis should consist of manuscripts suitable for publication in a scientific medium appropriate to the candidate’s field and/or approved reprints of the published work(s) (see Steps for Using Published and To-Be Published Work and Use of Copyrighted Material ).

Technical appendices should be added where necessary to demonstrate full development of the thesis material. Papers published under joint authorship are acceptable provided the candidate has contributed a major part to the investigation. The degree candidate is expected to be senior author on at least one of the papers. In the case of manuscripts published under joint authorship, the co-authors or the advisor may be consulted by the readers or the CAD to clarify the nature and extent of the candidate’s contribution. In addition to evaluating the quality and significance of the work, those responsible for accepting the thesis [the Department(s) and Doctoral Project Committee] may determine whether the format is suitable for publication in a scientific medium appropriate to the degree candidate’s field(s). Back to top  |  Back to Formatting Guidelines

Figures and Tables Figures and tables must be placed as close as possible to their first mention in the text. They may be placed on a page with no text above or below, or they may be placed directly in the text. If a figure or table is alone on a page with no narrative, it should be centered within the margins of the page.

Figures and tables referred to in the text may not be placed at the end of the chapter or at the end of the thesis. Figure and table numbering must be either continuous throughout the thesis or by paper (e.g., 1.1, 1.2, 2.1, 2.2). For example, there cannot be two figures designated in a thesis as “Figure 5.”

Headings of tables should be placed at the top of the table. While there are no specific rules for the format of table headings and figure captions, a consistent format must be used throughout the thesis. (See Citation and Style Guides )

Captions of figures should be placed at the bottom of the figure. If the figure takes up the entire page, the figure caption should be placed alone on the preceding page and centered vertically and horizontally within the margins. Each page receives a separate page number. When a figure or table title is on a preceding page, the second and subsequent pages of the figure or table should say, for example, “Figure 5 (Continued).” In such an instance, the list of figures or tables will list the page number containing the title. The word “Figure” should be written in full (not abbreviated), and the “F” should be capitalized (e.g., Figure 5). In instances where the caption continues on a second page, the “(Continued)” notation should appear on the second and any subsequent page. The figure/table and the caption are viewed as one entity and the numbering should show correlation between all pages. Each page must include a header.

Horizontal figures and tables must be positioned correctly and bound at the top, so that the top of the figure or table will be at the left margin (leave a 1 inch margin on the long edge of the paper above the top of the table).

Figure and table headings/captions are placed with the same orientation as the figure or table when on the same page. When on a separate page, headings/captions are always placed in vertical orientation, regardless of the orientation of the figure or table. Page numbers are always placed as if the figure were vertical on the page.

Figures created with software are acceptable if the figures are clear and legible. Legends and titles created by the same process as the figures will be accepted if they too are clear, legible, and run at least 10 or 12 characters per inch. Otherwise, legends and captions should be printed with the same font used in the text. Back to top  |  Back to Formatting Guidelines

Footnotes Footnotes are reserved for substantive additions to the text and should be indicated by an asterisk in the text. Extensive use of footnotes is not encouraged. The footnote should be placed at the bottom of the page. A horizontal line of at least two inches should be typed above the first footnote on any page. Footnotes should be placed so that at least one inch is left at the bottom of the page. Use single-spacing within footnotes. Back to top  |  Back to Formatting Guidelines

Bibliography To document the sources of information, a bibliography must be included at the end of the papers or thesis. References may be numbered or listed alphabetically. If references in the bibliography are numbered, then corresponding in-text references should be indicated by listing the number in parentheses after the name of the author.

Bibliographic Example:

23. Gibbs, C.S.: Filterable virus carriers. J. Bact., 23, 1932, 113.

In-Text Example:

“. . . as Gibbs (23) has stated.”

The initial number should be omitted if references are listed alphabetically.

Within any bibliographic section there should be consistency and adherence to an acceptable journal style for a bibliography. Each reference in the bibliography must contain the name of the author, title of the paper, name of publication, volume, date, and first page.

More than one publication by the same author in the same year should be indicated both in the bibliography and in the text by the use of underlined letters, etc., after the date of publication. The standard system of abbreviation used by the Quarterly Cumulative Index should be followed for the abbreviations of journal titles.

If students’ individual papers have different bibliographic styles, then it is not necessary to change the bibliographic style of one to match the other. Consistency within each bibliographic section is the most important element. Back to top  |  Back to Formatting Guidelines

Supplemental Material Supplemental figures and tables must be placed at the end of each chapter/paper in an appendix. If additional digital information (including text, audio, video, image, or datasets) will accompany the main body of the thesis, then it should be uploaded as supplemental material via the ETDs @ Harvard online submission tool. Back to top  |  Back to Formatting Guidelines

CITATION & STYLE GUIDES

• The Chicago Manual of Style. 16th ed. Chicago, IL: University of Chicago Press, 2003.
• Crews, Kenneth D. Copyright Law and the Doctoral Dissertation. Ann Arbor, MI: ProQuest, 2000.
• Day, Robert A. and Barbara Gastel. How to Write & Publish a Scientific Paper. 6th ed. Westport, CT: Greenwood, 2006.
• MLA Style Manual and Guide to Scholarly Publishing. 3rd ed. New York, NY: Modern Language Association of America, 2008. Strunk, William. The Elements of Style. 4th ed. New York, NY: Penguin Press, 2005.
• Publication Manual of the American Psychological Association. 6th ed. Washington, DC: American Psychological Association, 2010.
• Turabian, Kate L. A Manual for Writers of Term Papers, Theses, and Dissertations. Chicago
• Guides to Writing, Editing, and Publishing. 7th ed. Chicago, IL: University of Chicago Press, 2007.

THESIS SUBMISSION CHECKLIST ☐ Is the Signature Page unnumbered and positioned as the first page of the PDF file? ☐ Is there a blank page after the Signature Page? ☐ Does the body of the thesis begin with Page 1? ☐ Is the pagination continuous? Are all pages included? ☐ Is every page of the thesis correctly numbered? ☐ Is the placement of page numbers centered throughout the manuscript? ☐ Is the Title Page formatted correctly? ☐ Is the author’s name, in full, on the Title Page of the thesis and the abstract? ☐ Does the author’s name read the same on both and does it match the Signature Page? ☐ Is the abstract included after the Title Page? ☐ Does the abstract include the title of the thesis, the author’s name, and the thesis advisor(s)’ name? ☐ Is the title on the abstract the same as that on the title page? ☐ Are the margins 1” on all sides? ☐ Is the font size 10-12 point? ☐ Are all charts, graphs, and other illustrative materials perfectly legible? ☐ Do lengthy figures and tables include the “(Continued)” notation? ☐ Has all formatting been checked? ☐ Is the Survey of Earned Doctorates  completed? ☐ Has the Survey of Earned Doctorates’ confirmation email or certificate been uploaded to ETDs @ Harvard?

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Psychology Graduate Program

• Psychology Department
• Dissertation & Defense

The doctoral dissertation is the culmination of scholarly work in graduate school. Every PhD candidate in the Harvard Griffin Graduate School of Arts and Sciences is required to successfully complete and submit a dissertation to qualify for degree conferral. The dissertation must be submitted in one of two formats.  

• The traditional format is described in detail here .
• Three articles describing original empirical research that the dissertation committee deems “of publishable quality.”  The student must be the first author on each paper  or obtain approval from their committee to include papers for which they are not the first author . At least one of the three papers must be under review, in press, or published in a peer-reviewed journal. 
• An introductory chapter that thoroughly reviews the literature relevant to the three papers.
• A concluding chapter that describes what was learned from the three papers.

Post-prospectus changes :  If students would like to make substantive changes to the content and/or format of the dissertation after prospectus approval, they must revise their prospectus and obtain approval of the revised version from all committee members. Another meeting of the prospectus committee may be required if the changes are substantial.

If students would like to make changes to the composition of their dissertation committee after prospectus approval, they must obtain 1) approval from the primary advisor/ committee chair to make the change, and 2) approval of the prospectus by any new committee member(s). If the new member doesn't approve of the prospectus as written, the prospectus may need to be revised. If the revisions are substantial, students may need to have another full prospectus meeting to ensure the revised version of the prospectus is approved by every member of the committee.  

Dissertation Committee:  The Dissertation Committee comprises of the three members of the prospectus committee and an additional member—the outside examiner— who was not a member of the prospectus committee. The outside examiner must be approved by the CHD. Any tenured or tenure-track faculty member in the Psychology Department is automatically approved as an outside examiner.  Outside scholars require approval from your primary advisor and from the CHD. Students may ask the Graduate Program Coordinator if a particular scholar had already been approved in the past; if so, there is no further action needed by the student. If they have not been,  students should petition the CHD via email to the Graduate Program Coordinator; describe briefly why you are requesting the scholar and what they will add to the committee, i.e. "for their expertise in..." and include a copy of the scholar's CV.  

Dissertation Approval:   The dissertation must be approved by the student’s advisor before it is submitted to the dissertation committee. After the student sends the dissertation to the committee, they will have three weeks to read and assess the work. Each committee member should complete a  Dissertation Approval Form  and return it to the student and Graduate Office within three weeks. 

The committee members will receive an evaluation form, where they select among these options:

• Not acceptable in current form and cannot be corrected without major revisions and consultation of committee.
• Needs considerable revision, to be seen by me again. Needs committee consultation: [yes/no]
• Is acceptable with a few minor revisions, to be seen by me again.
• Is acceptable with voluntary minor revisions.
• Is acceptable as is.

If substantive revisions are required, the student will need to respond to these revisions, distribute a revised version to the committee, and the committee will have two more weeks to read and assess the revised version. All committee members must approve "as is" or "with voluntary minor revisions" before the defense can proceed.  

Dissertation Defense Date: Students are responsible for coordinating the schedule for their dissertation defense date. Due to the difficulty of coordinating schedules for several faculty, students are encouraged to find a mutually agreeable tentative date and time (we recommend a 2-hour duration) for the defense and ask committee members to pencil it in. However, it is crucial to recognize that this date will be confirmed only when the student has received approval from all members of their committee. In addition, the department must advertise the defense for two weeks before the date it can be held. Therefore, we strongly recommend the dissertation be submitted to the committee ten weeks before tentative defense date to accommodate time for rounds of revisions. The date will be pushed back if the student has not received approval from all members

Defenses can take place at any point in the year, as long as the committee agrees to convene. However, note there are deadlines to complete the defense in time for November, March, and May degree conferrals. The Department recommends that the defense be held at least 1-2 weeks prior to the dissertation submission deadline for that degree period. Deadlines for the current year can be found online in Harvard Griffin GSAS Policies in the Introduction section.

To submit: Email your dissertation as a single Word Doc or PDF file (or both) to your committee, cc’ing the Graduate Program coordinator. The Graduate Program Coordinator will follow up on this email by distributing the Dissertation Approval Form .  

Oral Defense:   Once the dissertation committee has approved the written dissertation, the student should book a room for the defense and send an abstract to the Graduate Office, which will announce the defense to the Department. WJH 1550 and 105, and NW 243 are the most common choices for a room. Students should submit a room request through FAS RoomBook . Committee members may participate remotely, if necessary, via Zoom or speakerphone. The Building Operations Office can lend a conference phone for this purpose. The Department does not have a budget to fly in committee members from other institutions except for former Harvard Psychology faculty members, although students should consult with their individual advisors to determine whether they would cover travel costs. We can provide a parking pass for committee members at nearby institutions.

The oral examination is moderated by the student's advisor, who is the Committee Chair. The advisor will introduce the student. The student gives a talk  about the work, and then the advisor will ask for questions from the committee. Talk times vary depending on area; please check in with your advisor to confirm. If there is time, the advisor may also choose to invite questions from the audience. The defense is a public event open to all. At the conclusion of the examination, the candidate and audience are dismissed, and the committee meets to make a final evaluation of the student's candidacy for a PhD. In cases of a positive evaluation, the committee members sign the Dissertation Acceptance Certificate .   

Dissertation Acceptance Certificate (DAC):   Students must complete a dissertation acceptance certificate (DAC), which includes the title of the dissertation and signatures of at least three readers approved by the student’s program. Prior to the oral defense, the Graduate Office will prepare a DAC, which includes the title of the dissertation, student name, and signature lines for each committee member The title on the DAC must read exactly as it does on the title page of the dissertation. A copy of the signed DAC should appear before the title page of the online dissertation submission; no page number should be assigned to the DAC. The DAC will be included in all copies of the dissertation.  

Dissertation Submission:   Following the successful oral defense, students must submit their dissertation in PDF format to the FAS Registrar’s Office through  ProQuest ETD by the deadline established for each degree conferral date (see the Harvard Griffin GSAS  Degree Calendar  or the  Registrar’s Office website ). Please carefully review the  dissertation formatting  before submitting online. Formatting errors may prevent students from receiving their degree. Harvard Griffin GSAS provides this helpful Dissertation Submission Checklist . The DAC must additionally be uploaded as a separate "Administrative Document" when submitting the electronic dissertation. The Registrar’s Office will review the dissertation for compliance and will contact the student to confirm acceptance or to request alterations. More details on the dissertation submission process can be found here .

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Harvard phd theses in physics, 2001-.

BAILEY, STEPHEN JOHN, B.S. (Washington) 1995. A Study of B → J/y K (*)0 X Decays. (Huth)

CHEN, LESTER HAO-LIN, B.S. (Duke) 1995. (Harvard) 1999. Charge-Iimaging Field-Effect Transistors for Scanned Probe Microscopy. (Westervelt)

CHOU, YI, B.S. (National Tsing Hua University) 1988. (National Tsing Hua University) 1990. Developments of EXITE2 and Timing Analysis of Ultra-Compact X-ray Binaries. (Papaliolios/Grindlay)

ERSHOV, ALEXEY, B.S. (Moscow Institute of Physics & Technology) 1996. Beauty Meson Decays to Charmonium. (Feldman)

FOX, DAVID CHARLES, A.B. (Princeton) 1991. (Harvard) 1994. The Structure of Clusters of Galaxies. (Loeb)

FUKUTO, MASAFUMI, B.S. (Oregon) 1994. (Harvard) 1997). Two-Dimensional Structures and Order of Nano-Objects on the Surface of Water: Synchrotron X-ray Scattering Studies. (Pershan)

HILL, MARC, B.S. (Illinois) 1994. Experimental Studies of W-band Accelerator Structures at High Field. (Huth)

KANNAPPAN, SHEILA, A.B. (Harvard) 1991. (Harvard, History of Science) 2001. Kinematic Clues to the Formation and Evolution of Galaxies. (Horowitz)

LAU, CHUN-NING, B.A. (Chicago) 1994. (Harvard) 1997. Quantum Phase Slips in Superconducting Nanowires. (Tinkham)

OSWALD, JOSEPH ANTON, B.S. (Duke) 1992. (Harvard) 1995. Metallo-dielectric Photonic Crystal Filters for Infrared Applications. (Verghese/Tinkham)

SCHAFFER, CHRISTOPHER BRIAN, B.S. (Florida) 1995. Interaction of Femtosecond Laser Pulses with Transparent Materials. (Mazur)

SPRADLIN, MARCUS BENJAMIN, B.A. (Princeton) 1996. (Harvard) 1999. AdS 2 Black Holes and Soliton Moduli Spaces. (Strominger)

WU, CLAUDIA, Diplom (Hannover) 1991. (Harvard) 1995. Femtosecond Laser-Gas-Solid Interactions. (Mazur)

BOZOVIC, DOLORES, B.S. ( Stanford University ) 1995. (Harvard) 1997. Defect Formation and Electron Transport in Carbon Nanotubes. (Tinkham)

BRITTO-PACUMIO, RUTH ALEXANDRA, B.S. (MIT) 1996. (Harvard) 1998. Bound States of Supersymmetric Black Holes. (Strominger)

CACHAZO, FREDDY ALEXANDER, B.S. (Simon Bolivar University) 1996. Dualities in Field Theory from Geometric Transitions in String Theory. (Vafa)

CHOU, YI, B.S. ( National Tsing Hua University ) 1988. ( National Tsing Hua University ) 1990. Developments of EXITE2 and Timing Analysis of Ultra-Compact X-ray Binaries. (Papaliolios/Grindlay)

COLDWELL, CHARLES MICHAEL, A.B. (Harvard) 1992. A Search for Interstellar Communications at Optical Wavelengths. (Horowitz)

DUTTON, ZACHARY JOHN, B.A. (University of California Berkeley) 1996. (Harvard) 2002. Ultra-slow Stopped, and Compressed Light in Bose-Einstein Condensates. (Hau)

FOX, DAVID CHARLES, A.B. ( Princeton ) 1991. (Harvard) 1994. The Structure of Clusters of Galaxies. (Shapiro)

GOEL, ANITA, B.S. (Stanford) 1995. Single Molecule Dynamics of Motor Enzymes Along DNA. (Herschbach/ Wilson)

HALL, CARTER, B.S. (Virginia Polytechnic Institute and State Univ.) 1996. Measurement of the isolated direct photon cross section with conversions in proton-antiproton collisions at sqrt (s) = 1.8 TeV. (Franklin)

JANZEN, PAUL HENRY, B. Sc., (University of Windsor) 1992. (Harvard) 1994. An Experiment to Measure Electron Impact Excitation of Ions that have Metastable States. (Horowitz/Kohl)

KIM, Daniel Young-Joon, AB/AM (Harvard) 1995. Properties of Inclusive B → psi Production. (Wilson/Brandenburg)

LANDHUIS, DAVID PAUL, B.S. (Stanford) 1994. (Harvard) 1997. Studies with Ultracold Metastable Hydrogen. (Gabrielse/Kleppner)  

LAU, CHUN-NING, B.A. ( Chicago ) 1994. (Harvard) 1997. Quantum Phase Slips in Superconducting Nanowires . (Tinkham)

LEE, CHUNGSOK, B.A. ( University of California , Berkeley ) 1995. ( Harvard University ) 2002. Control and Manipulation of Magnetic Nanoparticles and Cold Atoms Using Micro-electromagnets. (Westervelt)

 LUBENSKY, DAVID KOSLAN, A.B. ( Princeton University ) 1994. (Harvard) 1997. Theoretical Studies of Polynucleotide Biophysics. (Nelson)

MATTONI, CARLO EGON HEINRICH, A.B. ( Harvard College ) 1995. (Harvard University ) 1998. Magnetic Trapping of Ultracold Neutrons Produced Using a Monochromatic Cold Neutron Beam. (Doyle)

MCKINSEY, DANIEL NICHOLAS, B.S. (University of Michigan) 1995. (Harvard) 1998. Detecting Magnetically Trapped Neutrons: Liquid Helium As a Scintillator. (Doyle)

OZEL, FERYAL, B.S. (Columbia University) 1996. The Effects of Strong Magnetic and Gravitational Fields on Emission Properties of Neutron Stars. (Narayan)

PAUTOT, SOPHIE, B.S. (University of Bordeaux I and II) 1995. (University of Bordeaux I and II) 1996. Lipids behavior at dodecane-water interface. (Weitz)  

PRASAD, VIKRAM, B. Tech. (Indian Institute of Technology) 1996. ( University of Pennsylvania ) 1999. Weakly interacting colloid-polymer mixtures. (Weitz)

SALWEN, NATHAN KALMAN, A.B. (Harvard) 1994. Non-perturbative Methods in Modal Field Theory. (Coleman)

SCHWARZ, JENNIFER MARIE, B.S., B.A. (University of Maryland) 1994. Depinning with Elastic Waves: Criticality, Hysteresis, and Even Pseudo-Hysteresis. (Fisher)

SHAW, SCOT ELMER JAMES, B.A. (Lawrence University) 1998. Propagation in Smooth Random Potentials. [PDF: ~7.44MB] ( Heller)

SQUIRES, TODD MICHAEL, B.S. (UCLA) 1995. Hydrodynamics and Electrokinetics in Colloidal and Microfluidic Systems. (Fisher/Brenner)

VOLOVICH, ANASTASIA, A.M. (Moscow State) 1998. Holography for Coset Spaces and Noncommutative Solitions. (Strominger)

WEINSTEIN, JONATHAN DAVID, B.S. (Caltech) 1995. (Harvard) 1998. Magnetic Trapping of Atomic Chromium and Molecular Calcium Monohydride. (Doyle)  

 WONG, GLENN PATRICK, B.S. (Stanford) 1993. (Harvard) 1995. Nuclear Magnetic Resonance Experiments Using Laser-Polarized Noble Gas . (Shapiro)

YESLEY, PETER SPOOR, B.S. (MIT) 1995. The Road to Antihydrogen. (Gabrielse)

 *YOUNKIN, REBECCA JANE, A.B. ( Mt. Holyoke ) 1993. (Harvard) 1996. Surface Studies and Microstructure Fabrication Using Femtosecond. (Mazur)

ASHCOM, JONATHAN BENJAMIN, B.S. (Brown University) 1996. (Harvard) 2000. The role of focusing in the interaction of femtosecond laser pulses with transparent materials. (Mazur)

CHAN, IAN HIN-YUN , B.S. ( Sanford University ) 1994. Quantum dot circuits: single-electron switch and few-electron quantum dots . (Westervelt)

CREMERS, JACOB NICO HENDRIK JAN, B.S. (MIT) 1994. (Harvard) 2002. Pumping and Spin-Orbit Coupling in Quantum Dots. (Halperin)

deCARVALHO, ROBERT, B.S. (University of Arizona) 1996. (Harvard) 1999. Inelastic Scattering of Magnetically Trapped Atomic Chromium. (Doyle)

D’URSO, BRIAN RICHARD, B.S. (California Institute of Technology) 1998. Cooling and Self-Excitation of a One-Electron Oscillator. (Gabrielse)

FIETE, GREGORY ALAN, B.S. (Purdue University) 1997. (Harvard) 1999. Theory of Kondo Effect in Nanoscale Systems and Studies of III-V Diluated Magnetic Semiconductors. (Heller)

GABEL, CHRISTOPHER VAUGHN, A.B. (Princeton University) 1996. The speed of the flagellar rotary motor of Escherichia coli varies linearly with protonmotive force. (Berg)

GORDON, VERNITA DIANE, B.S. (Vanderbilt University) 1996. (Harvard) 2001. Measuring and Engineering Microscale Mechanical Responses and Properties of Bio-Relevant Materials. (Weitz)

HAILU, GIRMA, B.S. (Addis Ababa University). (Addis Ababa University) 1992. (Harvard) 1999. Chiral orbifold Construction of Field Theories with Extra Dimensions. (Georgi)

HEADRICK, MATTHEW PETER, B.A. (Princeton University) 1994. (Harvard) 1998. Noncummutative Solitons and Closed String Tachyons. (Minwalla)

HUMPHREY, MARC ANDREW, B.S. (Western Michigan University). 1997 (Harvard) 2000. Precision measurements with atomic hydrogen masers. (Walsworth)

LEPORE, NATASHA, B.S. (University of Montreal) Diffraction and Localization in Quantum Billiards. [Postscript: ~5.8MB] (Heller)

LEROY, BRIAN JAMES, Imaging Coherent Electron Flow Through Semiconductor Nanostructures. [PDF: ~10.17MB] (Westervelt)

LOPATNIKOVA, ANNA, B.S. (MIT) 1997. Spontaneously symmetry-broken states in the quantum Hall regime. (Halperin/Wen)

MADRAK, ROBYN LEIGH, B.A. (Cornell University) 1995 Measurement of the LambdaB Lifetime in the Decay Mode LambdaB-> Jpsi Lambda . (Franklin)

MALONEY, ALEXANDER DEWITT, Time-Dependent Backgrounds of String Theory . [PDF: ~6.73MB] (Strominger)

MAOZ, LIAT, B.S. (Hebrew University) 1995. Supersymmetric Configurations in the Rotating D1-D5 System and PP-Waves. [PDF: ~7.16 MB] (Maldacena/ Strominger)

MARINELLI, LUCA, Laurea ( University of Genova ) 1995. ( Harvard University ) 1997. Analysis of quasiparticles in the mixed state of a d-wave superconductor and NMR in pores with surface relaxation. (Halperin)

REFAEL, GIL, B.S. (Tel Aviv University) 1997. (Harvard) 2001. Randomness, Dissipation, and Quantum Fluctuations in Spin Chains and Mesoscopic Superconductor Arrays. (Fisher/Demler)

SHEN, NAN, B.A. (Rhode Island College) 1996. Photodisruption in biological tissues using femtosecond laser pulses . (Mazur)

TSERKOVNYAK, YAROSLAV, (University of British Columbia) 1999. (Harvard) 2001. Spin and Charge Transfer in Selected Nanostructures. [PDF: ~6.96MB] (Halperin)

VALENTINE, MEGAN THERESA, B.S. (Leigh University) 1997. (University of Pennsylvania) 1999. Mechanical and Microstructural Properties of Biological Materials . [PDF: ~3.5 MB] (Weitz)

VANICEK, JIRI JOSEPH LADISLAV, A.B. (Harvard College). (Harvard) 2000. Uniform semiclassical approximations and their applications . [PDF: 936 KB] (Heller)

WIJNHOLT, MARTIJN PAUL, B.S. (University of Warwick) 1996. Investigations in the physics of solitons in string theory. (Vafa)

ZABOW, GARY, B.S. (University of Cape Town) 1994. Charged-particle optics for neutral particles. (Prentiss)

ZIELINSKI, LUKASZ JOZEF, B.S. (Stanford University) 1997. Restriction and inhomogeneous magnetic fields in the nuclear magnetic resonance study of diffusion. (Halperin/Sen)

ABRAHAM, MATHEW CHEERAN, B.S. (Haverford College) 1997 (Harvard University) 2000. Hot Electron Transpoort and Current Sensing. (Westervelt)

BOWDEN, NATHANIEL SEAN, B.S., M.S. (University of Auckland) 1996. Production of Cold Antihydrogen During the Positron Cooling of Antiprotons. (Gabrielse)

CHANG, SPENCER, B.S. (Stanford University) 1999. (Harvard) 2001. Topics in Little Higgs Physics . [PDF: 467 KB] (Georgi)

DZHOSYUK, SERGEI N., B.S.(Moscow Institute of Physics and Technology)1995.(Moscow Institute of Physics and Technology)1997. M agnetic trapping of neutrons for measurement of the neutron lifetime. (Doyle)

EGOROV, DMITRO MIKHAILOVICH, B.S. (Moscow Institute of Physics and Technology) 1998. Buffer-Gas Cooling of Diatomic Molecules . [PDF: ~4.1 MB] (Doyle)

FIETE, ILA RANI, B.S. (University of Michigan) 1997. (Harvard University) 2000. Learning and coding in biological neural networks . (Fisher/Seung)

GARDEL, MARGARET LISE, B.A. (Brown University) 1998. (Harvard University) 2003. Elasticity of F-actin Networks. (Weitz)

HSU, MING F., A.B. ( Princeton University) 1999. Charged Colloidal Particles in Non-polar Solvents and Self-assembled Colloidal Model Systems . (Weitz)

KING, GAVIN MCLEAN, B.S. (Bates College) 1997 (Dartmouth college) 2001. Probing the Longitudinal Resolution of a Solid State nanopore Microscope with Nanotubes. (Golovchenko)

MANLEY, SULIANA, B.A.(Rice University) 1997. (Harvard University) 2001. Mechanical stability of fractal colloid gels. (Weitz)

MICHNIAK,JR.,ROBERT ALLEN, B.S. (University of Michigan) 1997. (Harvard University) 2001. Enhanced Buffer Gas Loading: Cooling and Trapping of Atoms with Low Effective Magnetic Moments. (Doyle)

MODY, AREEZ MINOO, B.S. (Caltech) 1994. Thermodynamics of ultracold singly charged particles. (Heller)

ODOM, BRIAN CARL, B.S. (Stanford University) 1995. (Harvard University) 1999. Measurement of the Electron g-Factor in a Sub-Kelvin Cylindrical Cavity . (Gabrielse)

OXLEY, PAUL KEVIN, B.A. (Oxford University) 1994. Production of Slow Antihydrogen from Cold Antimatter Plasmas . [PDF: ~5.9 MB](Gabrielse)

ROESER, CHRISTOPHER ALLAN DEWALD, B.A. (University of Chicago) 1998. Ultrafast Dynamics and Optical Control of Coherent Phonons in Tellurium. (Mazur)

SHPYRKO, OLEG GRIGORY, B.S. (Moscow Institute of Physics and Technology) 1995. Experimental X-Ray Studies of Liquid Surfaces. (Pershan)

SON, JOHN SANG WON, B.A. (Columbia University) 1996. Superstring Theory in AdS_3 and Plane Waves . [PDF: ~450 KB](Minwalla)

ZELEVINSKY, TANYA, S.B. (MIT) 1999. (Harvard University) 2001. Helium 2^3 P Fine Structure Measurement in a Discharge Cell. (Gabrielse)

ZUMBÜHL, DOMINIK MAX, Diploma, M.S. (Swiss Federal Institute of Technology), 1998. Coherence and Spin in GaAs Quantum Dots . [PDF: ~2.7 MB] (Marcus)

ANDRÉ, AXEL PHILIPPE, M.S. (Imperial College) 1997. (HarvardUniversity) 1999. Nonclassical States of Light and Atomic Ensembles: Generation and New Applications. (Lukin)

BIERCUK, MICHAEL JORDAN, Local Gate Control in Carbon Nanotube Quantum Devices. (Marcus)

CHEN, HAOYU HENRY, (University Maryland) 1998. (Harvard University) 2000. Surfaces in Solid Dynamics and Fluid Statics . [PDF: ~2.5 MB] (Brenner)

CONRAD, JACINTA CARMEL, S.B. (University of Chicago) 1999. ( Harvard University) 2002. Mechanical Response and Dynamic Arrest in Colloidal Glasses and Gels. (Weitz)

DASGUPTA, BIVASH R., B.S.C. (Presidency College) 1995. (Indian Institute of Technology) 1997. Microrheology and Dynamic Light Scattering Studies of Polymer Solutions. (Weitz)

HANCOX, CINDY IRENE, B.A. (University of California, Berkeley) 1997. ( Harvard University) 2002. Magnetic trapping of transition-metal and rare-earth atoms using buffer-gas loading. (Doyle)

HOUCK, ANDREW A., B.S.E. (Princeton University) 2000. Novel Techniques Towards Nuclear Spin Detection. (Marcus/Chuang)

LEE, HAK-HO, B.S. (Seoul National University) 1998. Microelectronic/Microfluidic Hybrid System for the Manipulation of Biological Cells. (Westervelt).

NEITZKE, ANDREW M., A.B. (Princeton University) 1998. Toward a Nonperturbative Topological String. (Vafa)

PODOLSKY, DANIEL, B.S. ( Stanford University) 1998. (Harvard University) 2000. Interplay of Magnetism and Superconductivity in Strongly Correlated Electron Systems. (Demler)  

RAPPOCCIO, SALVATORE ROCCO, B.A. (Boston University ) 2000. Measurement of the ttbar Production Cross Section in ppbar Collisions at sqrt (s) = 1.96 TeV. (Foland)

SPECK, ANDREW J., (Williams College) 2000. (Harvard) 2002. Two Techniques Produce Slow Antihydrogen . [PDF: ~9.2 MB] (Gabrielse)

TEE, SHANG YOU, B.S. ( Columbia University) 1995. (Stevens Institute of Technology) 1997. Velocity Fluctuations in Sedimentation and Fluidized Beds. (Weitz)

THOMPSON, DAVID MATTOON, (Yale) 1999 B.S./M.S. Holography and Related Topics in String Theory . [PDF: ~440 KB] (Strominger)

ZHU, CHENG, B.S. ( Tsinghua University) 1996. (Chinese Science and Technology University) 1997. Gas phase atomic and molecular process . (Lukin/Dalgarno)

BABICH, DANIEL MICHAEL, A.B. ( Princeton University) 2002. ( Harvard University) 2005. Cosmological Non-Gaussianity and Reionization . (Loeb)

BARNETT, RYAN LEE, B.S. ( Ohio State University) 2000. ( Harvard University) 2002. Studies of Strongly correlated Systems: From First Principles Computations to Effective Hamiltonians and Novel Quantum Phases. (Demler)

BOWLES, ANITA MARIE, B.S. ( University of Colorado) 1996. ( Harvard University) 1998. Stress Evolution in Thin Films of a Polymer . (Weitz/Spaepen)

CHIJIOKE, AKOBUIJE DOUGLAS EZIANI, B.S.E. ( Duke University) 1996. (Massachusetts Institute of Technology) 1998. Infrared absorption of compressed hydrogen deuteride and calibration of the ruby pressure gauge . [PDF: ~2.6 MB](Silvera)  

CYRIER, MICHELLE CHRISTINE, B.S. ( University of California , Berkeley) 2000. Physics From Geometry: Non-Kahler Compactifications, Black Rings and dS/CFT. (Strominger)

DESAI, MICHAEL MANISH, B.A. ( Princeton University ) 1999. ( University of Cambridge ) 2000. Evolution in Large Asexual Populations. (Murray/Fisher)

EISAMAN, MATTHEW D, A.B. (Princeton) 2000. (Harvard University) 2004. Generation, Storage and Retrieval of Nonclassical States of Light Using Atomic Ensembles . [PDF: ~7 MB] (Lukin)

HOLLOWAY, AYANA TAMU, A.B. ( Princeton University) 1998. The First Direct Limit on the t Quark Lifetime. ( Franklin)

HOWARD, ANDREW WILLIAM, S.B. (Massachusetts Institute of Technology) 1998. (Harvard University) 2001. Astronomical Searches for Nanosecond Optical Pulses. (Horowitz)

HUANG, JIAN, BS (Jilin University, P.R.China)1998. Theories of Imaging Electrons in Nanostructures . [PDF: ~8.4 MB] (Heller)

JONES, GREGORY CHAPMAN, B.S. (University of Missouri, Columbia) 2001. Time-dependent solutions in gravity . (Strominger)

KILIC, CAN, B.S. ( Bogazici University) 2000. Naturalness of Unknown Physics: Theoretical Models and Experimental Signatures. (Arkani-Hamed)  

 LAKADAMYALI, MELIKE, B.S. ( University of Texas , Austin ) 2001. Real-Time Imaging of Viral Infection and Intracellular Transport in Live Cells. (Zhuang)

MAHBUBANI, RAKHI, MSci (University of Bristol) 2000. Beyond the Standard Model: The Pragmatic Approach to the Gauge Hierarchy Problem . [PDF: ~1.5 MB] (Arkani-Hamed)

MARSANO, JOSEPH DANIEL, B.S. (University of Michigan) 2001. (Harvard University) 2004. The Phase Structure of Yang-Mills Theories and their Gravity Duals. (Minwalla)

NGUYEN, SCOTT VINH, B.S. (University of Texan, Austin) 2000. Buffer gas loading and evaporative cooling in the multi-partial-wave regeime. (Doyle)  

PAPADODIMAS, KYRIAKOS, B.A. ( University of Athens ) 2000. Phase Transitions in Large N Gauge Theories and String Theory Duals. (Minwalla)

PARROTT, ROBERT ELLIS, B.A. (Dartmouth College) 1997. (Dartmouth College) 1999. Topics in Electron Dynamics in Moderate Magnetic Fields . (Heller)  

POTOK, RONALD MICHAEL, B.S. ( University of Texas Austin) 2000. Probing Many Body Effects in Semiconductor Nanostructures. (Goldhaber-Gordon/Marcus)

RUST, MICHAEL JOSEPH, B.S. ( Harvey Mudd College ). Fluorescence Techniques for Single Virus Particle Tracking and Sub-Diffraction Limit Imaging. (Zhuang)

SAGE, JENNIFER NICOLE FUES, B.A. ( Washington University ) 1997. ( Harvard University ) 2000. Measurements of Lateral Boron Diffusion in Silicon and Stress Effects on Epitaxial Growth . (Aziz/Kaxiras)

TAYLOR, JACOB MASON, A.B. ( Harvard College ) 2000. Hyperfine Interactions and Quantum Information Processing in Quantum Dots. (Lukin)

THALER, JESSE KEMPNER, S.B. (Brown University). ( Harvard University) 2004. Symmetry Breaking at the Energy Frontier . (Arkani-Hamed)

THAMBYAHPILLAI, SHIYAMALA NAYAGI, M.S. (Imperial College) 1999. Brane Worlds and Deconstruction. (Randall)

VAISHNAV, JAY Y., B.S. (University of Maryland) 2000. ( Harvard University) 2002. Topics in Low Energy Quantum Scattering Theory. [PDF:  ~3.8 MB] (Heller)

VITELLI, VINCENZO, B.S. (Imperial College) 2000. Crystals , Liquid Crystals and Superfluid Helium on Curved Surfaces. (Nelson)  

WALKER, DEVIN GEORGE EDWARD, B.S. (Hampton University) 1998. ( Harvard University ) 2001. Theories on the Origin of Mass and Dark Matter. (Arkani-Hamed/Georgi)

WHITE, OLIVIA LAWRENCE, B.S. ( Stanford University ) 1997. Towards Real Spin Glasses: Ground States and Dynamics. (Fisher)

YIN, XI, B.S. (University of Science and Technology of China) 2001. Black Holes, Anti de Sitter Space, and Topological Strings. (Strominger)

YANG, LIANG, B.S. (Yale University) 1999. ( Harvard University) 2002. Towards Precision Measurement of the Neutron Lifetime using Magnetically Trapped Neutrons. (Doyle)

YAVIN, ITAY, B. Sc. (York University, Ontario) 2002. Spin Determination at the Large Hadron Collider. [PDF: ~662 KB] (Arkani-Hamed)

CHILDRESS, LILIAN ISABEL, B.A. (Harvard College) 2001. Coherent manipulation of single quantum systems in the solid state . (Lukin)

CLARK, DAMON ALISTAIR Biophysical Analysis of Thermostatic Behavior in C. elegans . (Samuel) 

ERNEBJERG, MORTEN, MPhys (University of Oxford) 2002. Field Theory Methods in Two-Dimensional and Heterotic String Theories . (Strominger)

FARKAS, DANIEL MARTIN, B.S. (Yale University) 2000. An Optical Reference and Frequency Comb for Improved Spectroscopy of Helium . (Gabrielse)

GINSBERG, NAOMI SHAUNA, B.A. (University of Toronto) 2000. (Harvard University) 2002. Manipulations with spatially compressed slow light pulses in Bose-Einstein condensates. (Hau)

HOFFMAN, LAUREN K., B.S. (California Institute of Technology) 2002. Orbital Dynamics in Galaxy Mergers . (Loeb)

HUANG, LISA LI FANG, B.S. (UCLA) 1999. Black Hole Attractors and Gauge Theories . (Strominger)

HUNT, THOMAS PETER, B.S. (Stanford University) 2000. Integrated Circuit / Microfluidic Chips for Dielectric Manipulation . (Westervelt)

IMAMBEKOV, ADILET, B.S. (Moscow Institute of Physics and Technology) 2002. Strongly Correlated Phenomena with Ultracold Atomic Gases . (Demler)

JAFFERIS, DANIEL LOUIS, B.S. (Yale) 2001. Topological String Theory from D-Brane Bound States . (Vafa)

JENKS, ROBERT A., B.A. (Williams College) 1998. Mechanical and neural representations of tactile information in the awake behaving rat somatosensory system . (Stanley/Weitz)

LEBEDEV, ANDRE, B.S. (University of Virginia) 1999. Ratio of Pion Kaon Production in Proton Carbon Interactions . (Feldman) 

LIU, JIAYU, B.S. (Nanjing University of China) 2002. (Harvard) 2004. Microscopic origin of the elasticity of F-actin networks . (Weitz)

MATHEY, LUDWIG GUENTER, Vordiplom (University of Heidelberg) 1998. Quantum phases of low-dimensional ultra-cold atom systems. (Castro-Neto/Halperin)

MAXWELL, STEPHEN EDWARD Buffer Gas Cooled Atoms and Molecules: Production, Collisional Studies, and Applications. (Doyle)

MO, YINA, B.S. (University of Science and Technology China) 2002. Theoretical Studies of Growth Processes and Electronic Properties of Nanostructures on Surfaces. (Kaxiras)

PARUCHURI, SRINIVAS S., B. S. (Cornell) 2000. (Harvard University) 2002. Deformations of Free Jets . (Brenner//Weitz)

QIAN, JIANG Localization in a Finite Inhomogeneous Quantum Wire and Diffusion through Random Spheres with Partially Absorbing Surfaces. (Halperin)

RITTER, WILLIAM GORDON, B.A. (University of Chicago) 1999. Euclidean Quantum Field Theory: Curved Spacetimes and Gauge Fields. (Jaffe)

SARAIKIN, KIRILL ANATOLYEVICH, B.S. (Moscow Institute for Physics and Technology) 1999. Black Holes, Entropy Functionals, and Topological Strings. (Vafa)

SCHULZ, ALEXIA EIRINN, B.A. (Boston University ) 1998. (Harvard University) 2000. Astrophysical Probes of Dark Energy. (White/Huth)

SCHUSTER, PHILIP CHRISTIAN, S.B. (Massachusetts Institute of Technology) 2003. ( Harvard University ) 2006. Uncovering the New Standard Model at the LHC . (Arkani-Hamed)

SEUN, SIN MAN, B.A. (Smith College) 2000.  B.E. (Dartmouth College) 2000. Measurement of p-K Ratios from the NuMI Target . (Feldman)

SHERMAN, DANIEL JOSEPH, B.A. (University of Pennsylvania ) 2001. Measurement of the Top Quark Pair Production Cross Section with 1.12 fb -1 of pp Collisions at sqrt (s) = 1.96 TeV. ( Franklin )

SIMONS, AARON, B.S. (California Institute of Technology) 2002. Black Hole Superconformal Quantum Mechanics. (Strominger)

SLOWE, CHRISTOPHER BRIAN, AB/AM (Harvard University). Experiments and Simulations in Cooling and Trapping of a High Flux Rubidium Beam. (Hau)

STRIEHL, PIERRE SEBASTIAN, Diploma (University of Heidelberg) 2004. A high-flux cold-atom source for area-enclosing atom interferometry. (Prentiss)

TORO, NATALIA, S.B. (Massachusetts Institute of Technology) 2003. Fundamental Physics at the Threshold of Discovery . (Arkani-Hamed) 

WISSNER-GROSS, ALEXANDER DAVID, S.B. (Massachusetts Institute of Technology) 2003. (Harvard University ) 2004. Physically Programmable Surfaces. (Kaxiras)

WONG, WESLEY PHILIP, B.S. (University of British Columbia) 1999. Exploring single-molecule interactions through 3D optical trapping and tracking: from thermal noise to protein refolding . (Evans/Nelson)

ZAW, INGYIN, B.A. (Harvard College) 2001.  (Harvard University) 2003. Search for the Flavor Changing Neutral Current Decay t → qZ in  pp Collisions at √s = 1.96 TeV. (Franklin)

BRAHMS, NATHANIEL CHARLES, Sc.B. (Brown University) 2001. Trapping of 1 μ β Atoms Using Buffer Gas Loading . (Doyle, Greytak)

BURBANK, KENDRA S., B.A. (Bryn Mawr College) 2000. (Harvard University) 2004. Self-organization mechanisms in the assembly and maintenance of bipolar spindles. (Fisher/Mitchison)

CAMPBELL, WESLEY C., B.S. (Trinity University) 2001. Magnetic Trapping of Imidogen Molecules . (Doyle)

CHAISANGUANTHUM, KRIS SOMBOON, B.S. (Harvard University ) 2001. An Enquiry Concerning Charmless Semileptonic Decays of Bottom Mesons . (Morii)

CHANG, DARRICK, B.S. (Stanford University) 2001. Controlling atom-photon interactions in nano-structured media. (Lukin)

CHOU, JOHN PAUL, A.B. (Princeton University) 2002. (Harvard University) 2006. Production Cross Section Measurement using Soft Electron Tagging in pp Collisions at √s  = 1.96 TeV . (Franklin)

DEL MAESTRO, ADRIAN GIUSEPPE, B.S. (University of Waterloo) 2002,  (University of Waterloo) 2003. The Superconductor-Metal Quantum Phase Transition in Ultra-Narrow Wires . (Sachdev)

DI CARLO, LEONARDO, B.S. (Stanford University) 1999. (Stanford University) 2000. Mesocopic Electronics Beyond DC Transport . (Marcus)

DUNKEL, EMILY REBECCA, B.S. (University of California Los Angeles) 2001. Quantum Phenomena in Condensed Phase Systems . (Sachdev/Coker)

FINKLER, ILYA GRIGORYEVICH, B.S. (Ohio State University) 2001. Nonlinear Phenomena in Two-Dimensional and Quasi-Two-Dimensional Electron Systems. (Halperin)

FITZPATRICK, ANDREW LIAM, B.S. (University of Chicago) 2004. (Harvard University) 2005. Broken Symmetries and Signatures . (Randall)

GARG, ARTI, A.B., B.S. (Stanford University) 2000. (Stanford University) 2001. (University of Washington) 2002. Microlensing Candidate Selection and Detection Efficiency for the Super MACHO Dark Matter Search . (Stubbs)

GERSHOW, MARC HERMAN, B.S. (Stanford University) 2001. Trapping Single Molecules with a Solid State Nanopore . (Golovchenko)

GRANT, LARS, B.S. (McGill University) 2001. Aspects of Quantization in AdS/CFT . (Vafa/Minwalla)

GUICA, MONICA MARIA, B.A. (University of Chicago) 2003. Supersymmetric Attractors, Topological Strings, and the M5-Brane CFT . (Strominger)

HANNEKE, DAVID ANDREW, B.S. (Case Western) 2001. (Harvard University) 2003. Cavity Control in a Single-Electron Quantum Cyclotron: An Improved Measurement of the Electron Magnetic Moment. (Gabrielse) 

HATCH, KRISTI RENEE, B.S. (Brigham Young University) 2004 Probing the mechanical stability of DNA by unzipping and rezipping the DNA at constant force. (Prentiss)

HOHLFELD, EVAN BENJAMIN, B.S. (Stanford University) 2001. Creasing, Point-bifurcations, and the Spontaneous Breakdown of Scale-invariance . (Weitz/Mahadevan)

KATIFORI, ELENI, Ptichion (University of Athens) 2002.  (Harvard University) 2004. Vortices, rings and pollen grains: Elasticity and statistical physics in soft matter .  (Nelson)

LAPAN, JOSHUA MICHAEL, B.S. (Massachusetts Institute of Technology) 2002.  (Harvard University) 2006. Topics in Two-Dimensional Field Theory and Heterotic String Theory .  (Strominger)

LE SAGE, DAVID ANTHONY, B.S. (University of California Berkeley) 2002. First Antihydrogen Production within a Combined Penning-Ioffe Trap . (Gabrielse)

LI, WEI, B.S. (Peking University) 1999. (Peking University) 2002. Gauge/Gravity Correspondence and Black Hole Attractors in Various Dimensions . (Strominger)

LU, PETER JAMES, B.A. (Princeton University) 2000.  (Harvard University) 2002. Gelation and Phase Separation of Attractive Colloids . (Weitz)

MUNDAY, JEREMY NATHAN, B.S. (Middle Tennessee State University) 2003.  (Harvard University) 2005. Attractive, repulsive, and rotational QED forces: experiments and calculations . (Hau/Capasso)

RAJU, SUVRAT, B.S. (St. Stephen’s College) 2002.  (Harvard University) 2003. Supersymmetric Partition Functions in the AdS/CFT Conjecture . (Arkani-Hamed/Denef/Minwalla)

RISTROPH, TRYGVE GIBBENS, B.S. (University of Texas at Austin) 1999. Capture and Ionization Detection of Laser-Cooled Rubidium Atoms with a Charged Suspended Carbon Nanotube . (Hau)

SVACHA, GEOFFRY THOMAS, B.S. (University of Michigan) 2002. Nanoscale nonlinear optics using silica nanowires . (Mazur)

TURNER, ARI M., B.A. (Princeton University) 2000. Vortices Vacate Vales and other Singular Tales . (Demler)

BAUMGART, MATTHEW TODD, B.S. (University of Chicago) 2002.  The Use of Effective Variables in High Energy Physics . (Georgi/Arkani-Hamed)

BOEHM, JOSHUA ADAM ALPERN, B.S.E. (Case Western Reserve University) 2003. (Harvard University) 2005. A Measurement of Electron Neutrino Appearance with the MINOS Experimen t. (Feldman)

CHEUNG, CLIFFORD WAYNE, B.S. (Yale University) 2004. (Harvard University) 2006. From the Action to the S-Matrix . (Georgi/Arkani-Hamed)

DORET, STEPHEN CHARLES B.A. (Williams College) 2002, A.M. (Harvard University) 2006. A buffer-gas cooled Bose-Einstein condensate . (Doyle)

FALK, ABRAM LOCKHART, B.A. (Swarthmore College) 2003. (Harvard University) 2004. Electrical Plasmon Detection and Phase Transitions in Nanowires . (Park)

HAFEZI, MOHAMMAD, (Sharif University of Technology, Tehran - Ecole Polytechnique, Paris) 2003. (Harvard University) 2005, Strongly interacting systems in AMO physics . (Lukin)

HECKMAN, JONATHAN JACOB, A.B. (Princeton University) 2004. (Harvard University) 2005 F-theory Approach to Particle Physics . (Vafa)

HICKEN, MALCOLM STUART, B.S. (Brigham Young University) 1999. (Harvard University) 2001. Doubling the Nearby Supernova Type Ia Sample . (Stubbs/Kirshner)

HOHENSEE, MICHAEL ANDREW, B.A. (New York University) 2002. (Harvard University) 2004. Testing Fundamental Lorentz Symmetries of Light . (Walsworth)

JIANG, LIANG, B.S. (California Institute of Technology) 2004.  T owards Scalable Quantum Communication and Computation: Novel Approaches and Realizations . (Lukin)

KAPLAN, JARED DANIEL, B.S. (Stanford University) 2005. Aspects of Holography . (Georgi/Arkani-Hamed)

KLEIN, MASON JOSEPH, B.S. (Calvin College) 2002. Slow and Stored Light in Atomic Vapor Cells . (Walsworth)

KRICH, JACOB JONATHAN, B.A. (Swarthmore College) 2000, MMath (Oxford University) 2003. (Harvard University) 2004. Electron and Nuclear Spins in Semiconductor Quantum Dots . (Halperin)

LAHIRI, SUBHANEIL, M.A. (Oxford University) 2003. Black holes from fluid mechanics. (Yin/Minwalla)

LIN, YI-CHIA, B.S. (National Taiwan Normal University) 1999. (National Tsing Hua University) 2001. Elasticity of Biopolymer Networks. (Weitz)

LUO, LINJIAO, B.S. (University of Science and Technology China) 2003. Thermotactic behavior in C. elegans and Drosophila larvae. (Samuel)

PADI, MEGHA, B.S. (Massachusetts Institute of Technology) 2003. A Black Hole Quartet: New Solutions and Applications to String Theory. (Strominger)

PASTRAS, GEORGIOS, DIPLOMA (University of Patras) 2002. (Harvard University) 2004. Thermal Field Theory Applications in Modern Aspects of High Energy Physics.  (Denef/Arkani-Hamed)

PEPPER, RACHEL E., B.S. (Cambridge) 2004. Splashing, Feeding, Contracting: Drop impact and fluid dynamics of Vorticella (Stone)

SHAFEE, REBECCA, B.S. (California Institute of Technology) 2002. (Harvard University) 2004. Measuring Black Hole Spin. (Narayan/McClintock)

WANG, CHRISTINE YI-TING, B.S. (National Taiwan University) 2002. (Harvard University) 2004. Multiode dynamics in Quantum Cascade Lasers: from coherent instability to mode locking. (Hoffman/Capasso)

ZHANG, YIMING, B.S. (Peking University) 2003. (Harvard University) 2006. Waves, Particles, and Interactions in Reduced Dimensions . (Marcus)

BARTHEL, CHRISTIAN, Diploma (University of Kaiserslautern) 2005. Control and Fast Measurement of Spin Qubits . (Marcus)

CAVANAUGH, STEVEN, B.S. (Rutgers College) 2005. (Harvard University) 2006. A Measurement of Electron Neutrino Appearance in the MINOS Experiment after Four Years of Data . (Feldman)

CHERNG, ROBERT, WEN-CHIEH, B.S. (Massachusetts Institute of Technology) 2004. Non-Equilibrium Dynamics and Novel Quantum Phases of Multicomponent Ultracold Atoms . (Demler)

FOLETTI, SANDRA ELISABETTA, Diploma (Federal Institute of Technology Zurich) 2004. Manipulation and Coherence of a Two-Electron Logical Spin Qubit Using GaAs Double Quantum Dots . (Yacoby)

GIRASH, JOHN ANDREW, B.S. (University of Western Ontario) 1990. (University of Western Ontario) 1993. A Fokker-Planck Study of Dense Rotating Stellar Clusters . (Stubbs/Field)

GOODSELL, ANNE LAUREL, B.A. (Bryn Mawr College) 2002. (Harvard University) 2004. Capture of Laser-Cooled Atoms with a Carbon Nanotube . (Hau)

GORSHKOV, ALEXEY VYACHESLAVOVICH, A.B. (Harvard College) 2004. (Harvard University) 2006. Novel Systems and Methods for Quantum Communication, Quantum Computation, and Quantum Simulation . (Lukin)

GUISE, NICHOLAS DAMIEN SUN-WO, B.S. (California Institute of Technology) 2003. Spin-Flip Resolution Achieved with a One-Proton Self-Excited Oscillator. (Gabrielse)

HARTMAN, THOMAS EDWARD, A.B. (Princeton University) 2004. Extreme Black Hole Holography. (Strominger)

HIGH, FREDRICK WILLIAM, B.A. (University of California Berkeley) 2004. The Dawn of Wide-Field Sunyaev-Zel’dovich Cluster Surveys: Efficient Optical Follow-Up. (Stubbs)

HOOGERHEIDE, DAVID PAUL, B.S. (Western Michigan University) 2004. Stochastic Processes in Solid State Nanoporers. (Golovchenko)

HUMMON, MATTHEW TAYLOR, B.A. (Amherst College) 2002, (Harvard University) 2005. Magnetic trapping of atomic nitrogen and cotrapping of NH. (Doyle)

KATS, YEVGENY, B.S. (Bar-Ilan University) 2003. (Bar-Ilan University) 2005. Physics of Conformal Field Theories. (Georgi/Arkani-Hamed)

KOROLEV, KIRILL SERGEEVICH, B.S. (Moscow Institute of Physics and Technology) 2004. Statistical Physics of Topological Emulsions and Expanding Populations. (Nelson)

LAIRD, EDWARD ALEXANDER, M.Phys (University of Oxford) 2002. (Harvard University) 2005. Electrical Control of Quantum Dot Spin Qubits . (Marcus)

LAROCHELLE, PHILIPPE, B.S. (Massachusetts Institute of Technology) 2003. Machines and Methods for Trapping Antihydrogen. (Gabrielse)

LI, GENE-WEI, B.S. (National Tsinghua University) 2004. Single-Molecule Spatiotemporal Dynamics in Living Bacteria. (Nelson/Xie)

MAZE RIOS, JERONIMO, B.S. (Pont Catholic University), 2002. (Pont Catholic University) 2004. Quantum Manipulation of Nitrogen-Vacancy Centers in Diamond: from Basic Properties to Applications. (Lukin)

PATTERSON, DAVID, A.B. (Harvard College) 1997. Buffer Gas Cooled Beams and Cold Molecular Collisions. (Doyle)  

PENG, AMY WAN-CHIH, B.Sc. (University of Auckland), (Australian National University) 2005. Optical Lattices with Quantum Gas Microscope . (Greiner)

QI, YANG, B.S. (Tsinghua University) 2005. Spin and Charge Fluctuations in Strongly Correlated Systems . (Sachdev)

ROJAS, ENRIQUE ROBERTSON, B.A. (University of Pennsylvania) 2003. The Physics of Tip-Growing Cells. (Nelson/Dumais)

SEO, JIHYE, B.S. (Korea Adv. Inst. of Science & Technology) 2003. (Harvard University) 2010. D-Branes, Supersymmetry Breaking, and Neutrinos . (Vafa)

SIMON, JONATHAN, B.S. (California Institute of Technology) 2004. Cavity QED with Atomic Ensembles. (Lukin/Vuletic)

SLATYER, TRACY ROBYN, Ph.B. (Australian National University) 2005. (Harvard University) 2008. Signatures of a New Force in the Dark Matter Sector. (Finkbeiner)

TAFVIZI, ANAHITA, B.S. (Sharif University of Technology) 2004. Single-Molecule and Computational Studies of Protein-DNA Interactions. (Cohen/Mirny/van Oijen)

WINKLER, MARK THOMAS, B.S.E. (Case Western Reserve) 2004. Non-Equilibrium Chalcogen Concentrations in Silicon: Physical Structure, Electronic Transport, and Photovoltaic Potential. (Mazur)

ANNINOS, DIONYSIOS Theodoros,B.A. (Cornell University) 2006, (Harvard University) 2008. Classical and Quantum Symmetries of de Sitter Space . (Strominger) >

BAKR, WASEEM S., B.S. (Massachusetts Institute of Technology) 2005. Microscopic studies of quantum phase transitions in optical lattices . (Greiner)

BARAK, GILAD, B.S. (Hebrew University) 2000, (Tel Aviv University) 2006. Momentum resolved tunneling study of interaction effects in ID electron systems .(Yacoby)

BARANDES, JACOB AARON, B.A. (ColumbiaUniversity) 2004. Exploring Supergravity Landscapes . (Denef)

BISWAS, RUDRO RANA, B.S. (Calcutta University) 2003, (Harvard University) 2011. Explorations in Dirac Fermions and Spin Liquids . (Sachdev)

CHEN, PEIQIU, B.S. (University of Science and Technology China) 2004, (Harvard University) 2005. Molecular evolution and thermal adaptation . (Nelson/Shakhnovich)

FREUDIGER, CHRISTIAN WILHELM, Diploma (Technische Universitat of München) 2005, (Harvard University) 2007. Stimulated Raman Scattering (SRS) Microscopy . (Zhuang/Xie)

GALLICCHIO, JASON RICHARD, B.S. (University of Illinois at Urbana Champaign) 1999, (University of Illinois at Urbana Champaign) 2001. A Multivariate Approach to Jet Substructure and Jet Superstructure . (Schwartz)

GLENDAY, ALEXANDER, B.A. (Williams College) 2002. Progress in Tests of Fundamental Physics Using  a 3He and 129Xe Zeeman Maser . (Stubbs/Walsworth)

GOLDMAN, JOSHUA DAVID, A.B. (Cornell University) 2002, (University of Cambridge) 2003, (Imperial College London) 2004. Planar Penning Traps with Anharmonicity Compensation for Single-Electron Qubits. (Gabrielse)

HUH, YEJIN, B.S. (Yale University) 2006, (Harvard University) 2008. Quantum Phase Transitions in d-wave Superconductors and Antiferromagnetic Kagome Lattices . (Sachdev)

KASHIF, LASHKAR, B.S. (Yale University) 2003. Measurement of the Z boson cross-section in the dimuon channel in pp collisions at sqrt{s} = 7 TeV . (Huth)

KAZ, DAVID MARTIN, B.S. (University of Arizona) 2003, (Harvard University) 2008. Colloidal Particles and Liquid Interfaces: A Spectrum of Interactions. (Manoharan)

KOLTHAMMER, WILLIAM STEVEN, B.S. (Harvey Mudd College) 2004, (Harvard University) 2006. Antimatter Plasmas Within a Penning-Ioffe Trap . (Gabrielse)

LEE-BOEHM, CORRY LOUISE, B.S.E. (University of Colorado) 2004, (Harvard University) 2011. B0 Meson Decays to rho0 K*0, f0 K*0, and rho- K*+, Including Higher K* Resonances . (Morii)

MARTINEZ-OUTSCHOORN, VERENA INGRID, B.A. (Harvard University) 2004, (Harvard University) 2007. Measurement of the Charge Asymmetry of W Bosons Produced in pp Collisions at sqrt(s) = 7 TeV with the ATLAS Detector . (Guimaraes da Costa)

MCCONNELL, ROBERT PURYEAR, B.S. (Stanford University) 2005, (Harvard University) 2007. Laser-Controlled Charge-Exchange Production of Antihydrogen . (Gabrielse)

MCGORTY, RYAN, B.S. (University of Massachusetts) 2005, (Harvard University) 2008. Colloidal Particles at Fluid Interfaces and the Interface of Colloidal Fluids . (Manoharan)

METLITSKI, MAXIM A., B.Sc. (University of British Columbia) 2003, (University of British Columbia) 2005. Aspects of Critical Behavior of Two Dimensional Electron Systems . (Sachdev)

MOON, EUN GOOK, B.S. (Seoul National University) 2005 Superfluidity in Strongly Correlated Systems . (Sachdev)

PETERSON, COURTNEY MARIE, B.S. (Georgetown University) 2002,(University of Cambridge) 2003, (Imperial College London) 2004, (Harvard University) 2007. Testing Multi-Field Inflation . (Stubbs/Tegmark)

PIELAWA, SUSANNE, Diploma (UNIVERSITY OF ULM) 2006, (Harvard University) 2009. Metastable Phases and Dynamics of Low-DimensionalStrongly-Correlated Atomic Quantum Gases . (Sachdev)

PRASAD, SRIVAS, A.B. (Princeton University) 2005, (Harvard University) 2007. Measurement of the Cross-Section of W Bosons Produced in pp Collisions at √s=7 TeV With the ATLAS Detector . (Guimaraes da Costa)

ROMANOWSKY, MARK, B.A. (Swarthmore College) 2003. High Throughput Microfluidics for Materials Synthesis . (Weitz)

SMITH, BEN CAMPBELL, B.A. (Harvard University) 2005. Measurement of the Transverse Momentum Spectrum of W Bosons Produced at √s = 7 TeV using the ATLAS Detector . (Morii)

TANJI, HARUKA, B.S. (University of Tokyo) 2002, (University of Tokyo) 2005, (Harvard University) 2009. Few-Photon Nonlinearity with an Atomic Ensemble in an Optical Cavity . (Lukin/Vuletic)

TRODAHL, HALVAR JOSEPH, B. Sc. (Victoria University) 2005, (Harvard University) 2008. Low Temperature Scanning Probe Microscope for Imaging Nanometer Scale Electronic Devices. (Westervelt)

WILLIAMS, TESS, B.Sc. (Stanford University) 2005. Nanoscale Electronic Structure of Cuprate Superconductors Investigated with Scanning Tunneling Spectroscopy. (Hoffman)

ANDERSEN, JOSEPH, B.S. (Univ. of Queensland) 1999. Investigations of the Convectively Coupled Equatorial Waves and the Madden-Julian Oscillation. (Huth)

BREDBERG, IRENE, M.PHYS., M.Sc. (Univ. of Oxford) 2006, 2007. The Einstein and the Navier-Stokes Equations:  Connecting the Two . (Strominger)

CHURCHILL, HUGH, B.A., B.M. (Oberlin College) 2006. Quantum Dots in Gated Nanowires and Nanotubes. (Marcus)

CONNOLLY, COLIN Inelastic Collisions of Atomic Antimony, Aluminum, Eerbium and Thulium Below . (Doyle)

CORDOVA, CLAY, B.A. (Columbia University) 2007. Supersymmetric Spectroscopy. (Vafa)

DILLARD, COLIN, S.B. (Massachusetts Institute of Technology) 2006. Quasiparticle Tunneling and High Bias Breakdown in the Fractional Quantum Hall Effect. (Kastner/Silvera)

DOWD, JASON, A.B. (Washington Univ.) 2006;(Harvard Univ.) 2008. Interpreting Assessments of Student Learning in the Introductory Physics Classroom and Laboratory. (Mazur)

GOLDSTEIN, GARRY Applications of Many Body Dynamics of Solid State Systems to Quantum Metrology and Computation (Chamon/Sachdev)

GUREVICH, YULIA, B.S. (Yale University) 2005. Preliminary Measurements for an Electron EDM Experiment in ThO. (Gabrielse)

KAGAN, MICHAEL, B.S. (Univ. of Michigan) 2006; (Harvard Univ.) 2008. Measurement of the W ± Z production cross section and limits on anomalous triple gauge couplings at √S = 7 TeV using the ATLAS detector. (Morii)

LIN, TONGYAN, S.B. (Massachusetts Institute of Technology) 2007; (Harvard Univ.) 2009. Signals of Particle Dark Matter. (Finkbeiner)

McCLURE, DOUGLAS, B.A. (Harvard University) 2006; (Harvard University) 2008. Interferometer-Based Studies of Quantum Hall Phenomena. (Marcus)

MAIN, ELIZABETH, B.S.(Harvey Mudd College) 2004; (Harvard Univ.) 2006. Investigating Atomic Scale Disordered Stripes in the Cuprate Superconductors with Scanning Tunneling Microscopy. (Hoffman)

MASON, DOUGLAS Toward a Design Principle in Mesoscopic Systems . (Heller/Kaxiras)

MULUNEH, MELAKU, B.A. (Swarthmore College) 2003. Soft colloids from p(NIPAm-co-AAc): packing dynamics and structure. (Weitz)

PIVONKA, ADAM Nanoscale Imaging of Phase Transitions with Scanning Force Microscopy . (Hoffman)

REAL, ESTEBAN, A.B. (Harvard University) 2002; (Harvard University) 2007. Models of visual processing by the retina. (Meister/Franklin)

RICHERME, PHILIP, S.B. (Massachusetts Institute of Technology) 2006; (Harvard University) 2008. Trapped Antihydrogen in Its Ground State. (Gabrielse)

SANTOS, LUIZ, B.S. (Univ. Fed. Do Espito Santo) 2004. Topological Properties of Interacting Fermionic Systems. (Chamon/Halperin)

SCHLAFLY, EDWARD, B.S. (Stanford University) 2007; (Harvard University) 2011. Dust in Large Optical Surveys. (Finkbeiner)

SETIAWAN, WIDAGDO, B.S. (Massachusetts Institute of Technology) 2007. Fermi Gas Microscope . (Greiner)

SHUVE, BRIAN, B.A.Sc. (University of Toronto) 2007; (Harvard University) 2011. Dark and Light: Unifying the Origins of Dark and Visible Matter. (Randall)

SIMMONS-DUFFIN, DAVID, A.B., A.M. (Harvard University) 2006. Carving Out the Space of Conformal Field Theories. (Randall)

TEMPEL, DAVID, B.A. (Hunter College) 2007. Time-dependent density functional theory for open quantum systems and quantum computation. (Aspuru-Guzik/Cohen)  

VENKATCHALAM, VIVEK, S.B. (Massachusetts Institute of Technology) 2006. Single Electron Probes of Fractional Quantum Hall States. (Yacoby)  

VLASSAREV, DIMITAR, B.S. (William and Mary) 2005; (Harvard University) 2007. DNA Characterization with Solid-State Nanopores and Combined Carbon Nanotube across Solid-State Nanopore Sensors . (Golovchenko)  

WANG, WENQIN, B.S. (Univ. of Science and Technology of China) 2006. Structures and dynamics in live bacteria revealed by super-resolution fluorescence microscopy. (Zhuang)

WANG, YIHUA Laser-Based Angle-Resolved Photoemission Spectroscopy of Topological Insulators. (Gedik / Hoffman)

WISSNER-GROSS, ZACHARY Symmetry Breaking in Neuronal Development. (Yanik /Levine)

YONG, EE HOU, B.Sc. (Stanford University) 2003. Problems at the Nexus of Geometry and Soft Matter: Rings, Ribbons and Shells. (Mahadevan)

ANOUS, TAREK Explorations in de Sitter Space and Amorphous Black Hole Bound States in String Theory . (Strominger)

BABADI, MEHRTASH Non-Equilibrium Dynamics of Artificial Quantum Matter . (Demler)

BRUNEAUX, LUKE Multiple Unnecessary Protein Sources and Cost to Growth Rate in E.coli. (Prentiss)

CHIEN, YANG TING Jet Physics at High Energy Colliders Matthew . (Schwartz)

CHOE, HWAN SUNG Choe Modulated Nanowire Structures for Exploring New Nanoprocessor Architectures and Approaches to Biosensing. (Lieber/Cohen)

COPETE, ANTONIO BAT Slew Survey (BATSS): Slew Data Analysis for the Swift-BAT Coded Aperture Imaging Telescope . (Stubbs)

DATTA, SUJIT Getting Out of a Tight Spot: Physics of Flow Through Porous Materials . (Weitz)

DISCIACCA, JACK First Single Particle Measurements of the Proton and Antiproton Magnetic Moments . (Gabrielse)

DORR, JOSHUA Quantum Jump Spectroscopy of a Single Electron in a New and Improved Apparatus . (Gabrielse )

DZYABURA, VASILY Pathways to a Metallic Hydrogen . (Silvera)

ESPAHBODI, SAM 4d Spectra from BPS Quiver Dualities. (Vafa)

FANG, JIEPING New Methods to Create Multielectron Bubbles in Liquid Helium . (Silvera)

FELDMAN, BEN Measurements of Interaction-Driven States in Monolayer and Bilayer Graphene . (Yacoby)

FOGWELL HOOGERHEIDE, SHANNON Trapped Positrons for High-Precision Magnetic Moment Measurements . (Gabrielse)

FUNG, JEROME Measuring the 3D Dynamics of Multiple Colloidal Particles with Digital Holographic Microscopy . (Manoharan)

GULLANS, MICHAEL Controlling Atomic, Solid-State and Hybrid Systems for Quantum Information Processing. (Lukin)

JAWERTH, LOUISE MARIE The Mechanics of Fibrin Networks and their Alterations by Platelets . (Weitz)

JEANTY, LAURA Measurement of the WZ Production Cross Section in Proton-Proton Collision at √s = 7 TeV and Limits on Anomalous Triple Gauge Couplings with the ATLAS Detector . (Franklin)

JENSEN, KATHERINE Structure and Defects of Hard-Sphere Colloidal Crystals and Glasses . (Weitz)

KAHAWALA, DILANI S Topics on Hadron Collider Physics . (Randall)

KITAGAWA, TAKUYA New Phenomena in Non-Equilibrium Quantum Physics . (Demler)

KOU, ANGELA Microscopic Properties of the Fractional Quantum Hall Effect . (Halperin)

LIN, TINA Dynamics of Charged Colloids in Nonpolar Solvents . (Weitz)

MCCORMICK, ANDREW Discrete Differential Geometry and Physics of Elastic Curves . (Mahadevan)

REDDING, JAMES Medford Spin Qubits in Double and Triple Quantum Dots . (Marcus/Yacoby)

NARAYAN, GAUTHAM Light Curves of Type Ia Supernovae and Preliminary Cosmological Constraints from the ESSENCE Survey . (Stubbs)

PAN, TONY Properties of Unusually Luminous Supernovae . (Loeb)

RASTOGI, ASHWIN Brane Constructions and BPS Spectra . (Vafa)

RUEL, JONATHAN Optical Spectroscopy and Velocity Dispersions of SZ-selected Galaxy Clusters . (Stubbs)

SHER, MENG JU Intermediate Band Properties of Femtosecond-Laser Hyperdoped Silicon . (Mazur)

TANG, YIQIAO Chirality of Light and Its Interaction with Chiral Matter . (Cohen)

TAYCHATANAPAT, THITI From Hopping to Ballistic Transport in Graphene-Based Electronic Devices . (Jarillo-Herrero/Yacoby)

VISBAL, ELI  Future Probes of Cosmology and the High-Redshift Universe . (Loeb)

ZELJKOVIC, ILIJA Visualizing the Interplay of Structural and Electronic Disorders in High-Temperature Superconductors using Scanning Tunneling Microscopy . (Hoffman)

ZEVI DELLA PORTA, GIOVANNI Measurement of the Cross-Section for W Boson Production in Association With B-Jets in Proton-Proton Collisions at √S = 7 Tev at the LHC Using the ATLAS Detector . (Franklin)

AU, YAT SHAN LinkInelastic collisions of atomic thorium and molecular thorium monoxide with cold helium-3. (Doyle)

BARR, MATTHEW Coherent Scattering in Two Dimensions: Graphene and Quantum Corrals . (Heller)

CHANG, CHI-MING Higher Spin Holography. (Yin)

CHU, YIWEN Quantum optics with atom-like systems in diamond. (Lukin)

GATANOV, TIMUR Data-Driven Analysis of Mitotic Spindles . (Needleman/Kaxiras)

GRINOLDS, MICHAEL Nanoscale magnetic resonance imaging and magnetic sensing using atomic defects in diamond. (Yacoby)

GUERRA, RODRIGO Elasticity of Compressed Emulsions . (Weitz)

HERRING, PATRICK LinkLow Dimensional Carbon Electronics. (Jarillo-Herrero/Yacoby)

HESS, PAUL W. LinkImproving the Limit on the Electron EDM: Data Acquisition and Systematics Studies in the ACME Experiment. (Gabrielse)

HOU, JENNIFER Dynamics in Biological Soft Materials . (Cohen)

HUBER, FLORIAN Site-Resolved Imaging with the Fermi Gas Microscope. (Greiner)

HUTZLER, NICHOLAS A New Limit on the Electron Electric Dipole Moment . (Doyle)

KESTIN, GREG Light-Shell Theory Foundations. (Georgi)

LYSOV, VYACHESLAV From Petrov-Einstein to Navier-Stokes. (Strominger)

MA, RUICHAO Engineered Potentials and Dynamics of Ultracold Quantum Gases under the Microscope. (Greiner)

MAURER, PETER Coherent control of diamond defects for quantum information science and quantum sensing. (Lukin)

NG, GIM SENG Aspects of Symmetry in de Sitter Space. (Strominger)

NICOLAISEN, LAUREN Distortions in Genealogies due to Purifying Selection. (Desai)

NURGALIEV, DANIYAR A Study of the Radial and Azimuthal Gas Distribution in Massive Galaxy Clusters. (Stubbs)

RUBIN, DOUGLAS Properties of Dark Matter Halos and Novel Signatures of Baryons in Them . (Loeb)

RUSSELL, EMILY Structure and Properties of Charged Colloidal Systems. (Weitz)

SHIELDS, BRENDAN Diamond Platforms for Nanoscale Photonics and Metrology. (Lukin)

SPAUN, BENJAMIN A Ten-Fold Improvement to the Limit of the Electron Electric Dipole Moment. (Gabrielse)

YAO, NORMAN Topology, Localization, and Quantum Information in Atomic, Molecular and Optical Systems. (Lukin)

YEE, MICHAEL Scanning Tunneling Spectroscopy of Topological Insulators and Cuprate Superconductors. (Hoffman)

BENJAMIN, DAVID ISAIAH Impurity Physics in Resonant X-Ray Scattering and Ultracold Atomic Gases . (Demler)

BEN-SHACH, GILAD Theoretical Considerations for Experiments to Create and Detect Localised Majorana Modes in Electronic Systems. (Halperin/Yacoby)

CHANG, WILLY Superconducting Proximity Effect in InAs Nanowires . (Marcus/Yacoby)

CHUNG, HYEYOUN Exploring Black Hole Dynamics . (Randall)

INCORVIA, JEAN ANNE CURRIVAN Nanoscale Magnetic Materials for Energy-Efficient Spin Based Transistors. (Westervelt)

FEIGE, ILYA ERIC ALEXANDER Factorization and Precision Calculations in Particle Physics. (Schwartz)

FRENZEL, ALEX Terahertz Electrodynamics of Dirac Fermions in Graphene. (Hoffman)

HSU, CHIA WEI Novel Trapping and Scattering of Light in Resonant Nanophotonic Structures. (Cohen)

JORGOLLI, MARSELA Integrated nanoscale tools for interrogating living cells. (Park)

KALRA, RITA RANI An Improved Antihydrogen Trap. (Gabrielse)

KOLKOWITZ, SHIMON JACOB Nanoscale Sensing with Individual Nitrogen-Vacancy Centers in Diamond. (Lukin)

LAVRENTOVICH, MAXIM OLEGOVICH Diffusion, Absorbing States, and Nonequilibrium Phase Transitions in Range Expansions and Evolution. (Nelson)

LIU, BO Selected Topics in Scattering Theory: From Chaos to Resonance. (Heller)

LOCKHART, GUGLIELMO PAUL Self-Dual Strings of Six-Dimensional SCFTs . (Vafa)

MAGKIRIADOU, SOFIA Structural Color from Colloidal Glasses. (Manoharan)

MCIVER, JAMES W. Nonlinear Optical and Optoelectronic Studies of Topological Insulator Surfaces. (Hoffman)

MEISNER, AARON MICHAEL Full-sky, High-resolution Maps of Interstellar Dust. (Finkbeiner)

MERCURIO, KEVIN MICHAEL A Search for the Higgs Boson Produced in Association with a Vector Boson Using the ATLAS Detector at the LHC. (Huth)

NOWOJEWSKI, ANDRZEJ KAZIMIERZ Pathogen Avoidance by Caenorhabditis Elegans is a Pheromone-Mediated Collective Behavior. (Levine)

PISKORSKI, JULIA HEGE Cooling, Collisions and non-Sticking of Polyatomic Molecules in a Cryogenic Buffer Gas Cell. (Doyle)

SAJJAD, AQIL An Effective Theory on the Light Shell. (Georgi)

SCHADE, NICHOLAS BENJAMIN Self-Assembly of Plasmonic Nanoclusters for Optical Metafluids. (Manoharan)

SHULMAN, MICHAEL DEAN Entanglement and Metrology with Singlet-Triplet Qubits. (Yacoby)

SPEARMAN, WILLIAM R. Measurement of the Mass and Width of the Higgs Boson in the H to ZZ to 4l Decay Channel Using Per-Event Response Information. (Guimaraes da Costa)

THOMPSON, JEFFREY DOUGLAS A Quantum Interface Between Single Atoms and Nanophotonic Structures. (Lukin)

WANG, TOUT TAOTAO Small Diatomic Alkali Molecules at Ultracold Temperatures. (Doyle)

WONG, CHIN LIN Beam Characterization and Systematics of the Bicep2 and Keck Array Cosmic Microwave Background Polarization Experiments. (Kovac)

AGARWAL, KARTIEK Slow Dynamics in Quantum Matter: the Role of Dimensionality, Disorder and Dissipation. (Demler)

ALLEN, MONICA Quantum electronic transport in mesoscopic graphene devices. (Yacoby)

CHAE, EUNMI Laser Slowing of CaF Molecules and Progress towards a Dual-MOT for Li and CaF. (Doyle)

CHOTIBUT, THIPARAT Aspects of Statistical Fluctuations in Evolutionary and Population Dynamics. (Nelson)

CHOWDHURY, DEBANJAN Interplay of Broken Symmetries and Quantum Criticality in Correlated Electronic Systems. (Sachdev)

CLARK, BRIAN Search for New Physics in Dijet Invariant Mass Spectrum. (Huth)

FARHI, DAVID Jets and Metastability in Quantum Mechanics and Quantum Field Theory. (Schwartz)

FORSYTHE, MARTIN Advances in Ab Initio Modeling of the Many-Body Effects of Dispersion Interactions in Functional Organic Materials. (Aspuru-Guzik/Ni)

GOOD, BENJAMIN Molecular evolution in rapidly evolving populations. (Desai)

HART, SEAN Electronic Phenomena in Two-Dimensional Topological Insulators. (Yacoby)

HE, YANG Scanning Tunneling Microscopy Study on Strongly Correlated Materials. (Hoffman)

HIGGINBOTHAM, ANDREW Quantum Dots for Conventional and Topological Qubits. (Marcus/Westervelt)

HUANG, DENNIS Nanoscale Investigations of High-Temperature Superconductivity in a Single Atomic Layer of Iron Selenide. (Hoffman)

ISAKOV, ALEXANDER The Collective Action Problem in a Social and a Biophysical System. (Mahadevan)

KLALES, ANNA A classical perspective on non-diffractive disorder. (Heller)

KOBY, TIMOTHY Development of a Trajectory Model for the Analysis of Stratospheric Water Vapor. (Anderson/Heller)

KOMAR, PETER Quantum Information Science and Quantum Metrology: Novel Systems and Applications. (Lukin)

KUCSCKO, GEORG Coupled Spins in Diamond: From Quantum Control to Metrology and Many-Body Physics. (Lukin)

LAZOVICH, TOMO Observation of the Higgs boson in the WW* channel and search for Higgs boson pair production in the bb ̅bb ̅ channel with the ATLAS detector. (Franklin)

LEE, JUNHYUN Novel quantum phase transitions in low-dimensional systems. (Sachdev)

LIN, YING-HSUAN Conformal Bootstrap in Two Dimensions. (Yin)

LUCAS, ANDREW Transport and hydrodynamics in holography, strange metals and graphene. (Sachdev)

MACLAURIN, DOUGAL Modeling, Inference and Optimization with Composable Differentiable Procedures. (Adams/Cohen)

PARSONS, MAXWELL Probing the Hubbard Model with Single-Site Resolution. (Greiner)

PATEJ, ANNA Distributions of Gas and Galaxies from Galaxy Clusters to Larger Scales. (Eisenstein/Loeb/Finkbeiner)

PITTMAN, SUZANNE The Classical-Quantum Correspondence of Polyatomic Molecules. (Heller)

POPA, CRISTINA Simulating the Cosmic Gas: From Globular Clusters to the Most Massive Haloes. (Randall)

PORFYRIADIS, ACHILLEAS Gravitational waves from the Kerr/CFT correspondence . (Strominger)

PREISS, PHILIPP Atomic Bose-Hubbard systems with single-particle control. (Greiner)

SHAO, SHU-HENG Supersymmetric Particles in Four Dimensions. (Yin)

YEN, ANDY Search for Weak Gaugino Production in Final States with One Lepton, Two b-jets Consistent with a Higgs Boson, and Missing Transverse Momentum with the ATLAS detector. (Huth)

BERCK, MATTHEW ELI Reconstructing and Analyzing the Wiring Diagram of the Drosophila Larva Olfactory System. (Samuel)

COUGHLIN, MICHAEL WILLIAM Gravitational Wave Astronomy in the LSST Era. (Stubbs)

DIMIDUK, THOMAS Holographic Microscopy for Soft Matter and Biophysics. (Manoharan)

FROST, WILLIAM THOMAS Tunneling in Quantum Field Theory and the Fate of the Universe. (Schwartz)

JERISON, ELIZABETH Epistasis and Pleiotropy in Evolving Populations. (Desai)

KAFKA, GARETH A Search for Sterile Neutrinos at the NOνA Far Detector. (Feldman)

KOSHELEVA, EKATERINA Genetic Draft and Linked Selection in Rapidly Adapting Populations. (Desai)

KOSTINSKI, SARAH VALERIE Geometrical Aspects of Soft Matter and Optical Systems. (Brenner)

KOZYRYEV, IVAN Laser Cooling and Inelastic Collisions of the Polyatomic Radical SrOH. (Doyle)

KRALL, REBECCA Studies of Dark Matter and Supersymmetry. (Reece)

KRAMER, ERIC DAVID Observational Constraints on Dissipative Dark Matter. (Randall)

LEE, LUCY EUNJU Network Analysis of Transcriptome to Reveal Interactions Among Genes and Signaling Pathways. (Levine)

LOVCHINSKY, IGOR Nanoscale Magnetic Resonance Spectroscopy Using Individual Spin Qubits. (Lukin)

LUPSASCA, ALEXANDRU The Maximally Rotating Black Hole as a Critical Point in Astronomy. (Strominger)

MANSURIPUR, TOBIAS The Effect of Intracavity Field Variation on the Emission Properties of Quantum Cascade Lasers. (Capasso/Yacoby)

MARANTAN, ANDREW WILLIAM The Roles of Randomness in Biophysics: From Cell Growth to Behavioral Control. (Mahadevan)

MASHIAN, NATALIE Modeling the Constituents of the Early Universe. (Loeb/Stubbs)

MAZURENKO, ANTON Probing Long Range Antiferromagnetism and Dynamics in the Fermi-Hubbard Model. (Greiner)

MITRA, PRAHAR Asymptotic Symmetries in Four Dimensional Gauge and Gravity Theories. (Strominger)

NEAGU, IULIA ALEXANDRA Evolutionary Dynamics of Infection. (Nowak/Prentiss)

PETRIK WEST, ELIZABETH A Thermochemical Cryogenic Buffer Gas Beam Source of ThO for Measuring the Electric Dipole Moment of the Electron. (Doyle)

RUDELIUS, THOMAS Topics in the String Landscape and the Swampland. (Vafa)

SAKLAYEN, NABIHA Laser-Activated Plasmonic Substrates for Intracellular Delivery. (Mazur)

SIPAHIGIL, ALP Quantum Optics with Diamond Color Centers Coupled to Nanophotonic Devices. (Lukin)

SUN, SIYUAN Search for the Supersymmetric Partner to the Top Quark Using Recoils Against Strong Initial State Radiation. (Franklin)

TAI, MING ERIC Microscopy of Interacting Quantum Systems. (Greiner)

TOLLEY, EMMA Search for Evidence of Dark Matter Production in Monojet Events with the ATLAS Detector. (Morii)

WILSON, ALYSSA MICHELLE New Insights on Neural Circuit Refinement in the Central Nervous System: Climbing Fiber Synapse Elimination in the Developing Mouse Cerebellum Studied with Serial-Section Scanning Electron Microscopy. (Lichtman/Samuel)

BAUCH, ERIK Optimizing Solid-State Spins in Diamond for Nano- to Millimeter scale Magnetic Field Sensing. (Walsworth)

BRACHER, DAVID OLMSTEAD Development of photonic crystal cavities to enhance point defect emission in silicon carbide. (Hu: SEAS)

CHAN, STEPHEN KAM WAH Orthogonal Decompositions of Collision Events and Measurement Combinations in Standard Model $VH\left(b\bar{b}\right)$ Searches with the ATLAS Detector. (Huth)

CHATTERJEE, SHUBHAYU Transport and symmetry breaking in strongly correlated matter with topological order. (Sachdev)

CHOI, SOONWON Quantum Dynamics of Strongly Interacting Many-Body Systems. (Lukin)

CONNORS, JAKE Channel Length Scaling in Microwave Graphene Field Effect Transistors. (Kovac)

DAHLSTROM, ERIN KATRINA Quantifying and modeling dynamics of heat shock detection and response in the intestine of Caenorhabditis elegans. (Levine)

DAYLAN, TANSU A Transdimensional Perspective on Dark Matter. (Finkbeiner)

DOVZHENKO, YULIYA Imaging of Condensed Matter Magnetism Using an Atomic-Sized Sensor. (Yacoby)

EVANS, RUFFIN ELEY An integrated diamond nanophotonics platform for quantum optics. (Lukin)

FLEMING, STEPHEN Probing nanopore - DNA interactions with MspA. (Golovchenko)

FRYE, CHRISTOPHER Understanding Jet Physics at Modern Particle Colliders. (Schwartz)

FU, WENBO The Sachdev-Ye-Kitaev model and matter without quasiparticles. (Sachdev)

GOLDMAN, MICHAEL LURIE Coherent Optical Control of Atom-Like Defects in Diamond: Probing Internal Dynamics and Environmental Interactions. (Lukin)

HE, TEMPLE MU On Soft Theorems and Asymptotic Symmetries in Four Dimensions. (Strominger)

HOYT, ROBERT Understanding Catalysts with Density Functional Theory and Machine Learning. (Kaxiras)

KAPEC, DANIEL STEVEN Aspects of Symmetry in Asymptotically Flat Spacetimes. (Strominger)

LEE, ALBERT Mapping the Relationship Between Interstellar Dust and Radiation in the Milky Way. (Finkbeiner)

LEE, JAEHYEON Prediction and Inference Methods for Modern Astronomical Surveys (Eisenstein, Finkbeiner)

LUKIN, ALEXANDER Entanglement Dynamics in One Dimension -- From Quantum Thermalization to Many-Body Localization (Greiner)

NOVITSKI, ELISE M. Apparatus and Methods for a New Measurement of the Electron and Positron Magnetic Moments. (Gabrielse)

PATHAK, ABHISHEK Holography Beyond AdS/CFT: Explorations in Kerr/CFT and Higher Spin DS/CFT. (Strominger)

PETERMAN, NEIL Sequence-function models of regulatory RNA in E. coli. (Levine)

PICK, ADI Spontaneous Emission in Nanophotonics. (Johnson: MIT)

PO, HOI CHUN Keeping it Real: An Alternative Picture for Symmetry and Topology in Condensed Matter Systems. (Vishwanath)

REN, HECHEN Topological Superconductivity in Two-Dimensional Electronic Systems. (Yacoby)

ROXLO, THOMAS Opening the black box of neural nets: case studies in stop/top discrimination. (Reece)

SHTYK, OLEKSANDR Designing Singularities in Electronic Dispersions (Chamon, Demler)

TONG, BAOJIA Search for pair production of Higgs bosons in the four b quark final state with the ATLAS detector. (Franklin)

WHITSITT, SETH Universal non-local observables at strongly interacting quantum critical points. (Sachdev)

YAN, KAI Factorization in hadron collisions from effective field theory. (Schwartz)

AMATOGRILL, JESSE A Fast 7Li-based Quantum Simulator (Ketterle, Greiner)

BARON, JACOB Tools for Higher Dimensional Study of the Drosophila Larval Olfactory System (Samuel)

BUZA, VICTOR Constraining Primordial Gravitational Waves Using Present and Future CMB Experiments (Kovac)

CHAEL, ANDREW Simulating and Imaging Supermassive Black Hole Accretion Flows (Narayan, Dvorkin)

CHIU, CHRISTIE Quantum Simulation of the Hubbard Model (Greiner)

DIPETRILLO, KARRI Search for Long-Lived, Massive Particles in Events with a Displaced Vertex and a Displaced Muon Using sqrt{s} = 13 TeV pp-Collisions with the ATLAS Detector (Franklin)

FANG, SHIANG Multi-scale Theoretical Modeling of Twisted van der Waals Bilayers (Kaxiras)

GAO, PING Traversable Wormholes and Regenesis (Jafferis)

GONSKI, JULIA Probing Natural Supersymmetry with Initial State Radiation: the Search for Stops and Higgsinos at ATLAS (Morii)

HARVEY, SHANNON Developing Singlet-Triplet Qubits in Gallium Arsenide as a Platform for Quantum Computing (Yacoby)

JEFFERSON, PATRICK Geometric Deconstruction of Supersymmetric Quantum Field Theories (Vafa)

KANG, MONICA JINWOO Two Views on Gravity: F-theory and Holography (Jafferis)

KATES-HARBECK, JULIAN Tackling Complexity and Nonlinearity in Plasmas and Networks Using Artificial Intelligence and Analytical Methods  (Desai, Nowak)

KLEIN, ELLEN Structure and Dynamics of Colloidal Clusters (Manoharan)

LEVIN, ANDREI Single-Electron Probes of Two-Dimensional Materials (Yacoby)

LIU, XIAOMENG Correlated Electron States in Coupled Graphene Double-Layer Heterostructures (Kim)

LIU, LEE Building Single Molecules – Reactions, Collisions, and Spectroscopy of Two Atoms (Ni)

MARABLE, KATHRYN Progress Towards a Sub-ppb Measurement of the Antiproton Magnetic Moment (Gabrielse)

MARSHALL, MASON New Apparatus and Methods for the Measurement of the Proton and Antiproton Magnetic Moments (Gabrielse)

MCNAMARA, HAROLD Synthetic Physiology: Manipulating and Measuring Biological Pattern Formation with Light (Cohen)

MEMET, EDVIN Parking, Puckering, and Peeling in Small Soft Systems (Mahadevan)

MUKHAMETZHANOV, BAURZHAN Bootstrapping High-Energy States in Conformal Field Theories (Jafferis)

OLSON, JOSEPH Plasticity and Firing Rate Dynamics in Leaky Integrate-and-Fire Models of Cortical Circuits (Kreiman)

PANDA, CRISTIAN Order of Magnitude Improved Limit on the Electric Dipole Moment of the Electron (Gabrielse)

PASTERSKI, SABRINA Implications of Superrotations (Strominger)

PATE, MONICA Aspects of Symmetry in the Infrared (Strominger)

PATEL, AAVISHKAR Transport, Criticality, and Chaos in Fermionic Quantum Matter at Nonzero Density (Sachdev)

PHELPS, GREGORY A Dipolar Quantum Gas Microscope (Greiner)

RISPOLI, MATTHEW Microscopy of Correlations at a Non-Equilibrium Phase Transition (Greiner)

ROLOFF, JENNIFER Exploring the Standard Model and beyond with jets from proton-proton collisions at sqrt(s)=13 TeV with the ATLAS Experiment (Huth)

ROWAN, MICHAEL Dissipation of Magnetic Energy in Collisionless Accretion Flows (Narayan and Morii)

SAFIRA, ARTHUR NV Magnetic Noise Sensing and Quantum Information Processing, and Llevitating Micromagnets over Type-II Superconductors (Lukin)

SHI, YICHEN Analytical Steps Towards the Observation of High-Spin Black Holes (Strominger)

THOMSON, ALEXANDRA Emergent Dapless Fermions in Strongly-Correlated Phases of Matter and Quantum Critical Points (Sachdev)

WEBB, TATIANA The Nanoscale Structure of Charge Order in Cuprate Superconductor Bi2201 (Hoffman)

WESSELS, MELISSA Progress Toward a Single-Electron Qubit in an Optimized Planar Penning Trap (Gabrielse)

WILLIAMS, MOBOLAJI Biomolecules, Combinatorics, and Statistical Physics (Shakhnovich, Manoharan)

XIONG, ZHAOXI Classification and Construction of Topological Phases of Quantum Matter (Vishwanath)

ZOU, LIUJUN An Odyssey in Modern Quantum Many-Body Physics (Todadri, Sachdev)

ANDEREGG, LOÏC Ultracold molecules in optical arrays: from laser cooling to molecular collisions (Doyle)

BALTHAZAR, BRUNO 2d String Theory and the Non-Perturbative c=1 Matrix Model (Yin)

BAUM, LOUIS Laser cooling and 1D magneto-optical trapping of calcium monohydroxide (Doyle)

CARR, STEPHEN Moiré patterns in 2D materials (Kaxiras)

COLLIER, SCOTT Aspects of local conformal symmetry in 1+1 dimensions (Yin)

DASGUPTA, ISHITA Algorithmic approaches to ecological rationality in humans and machines (Mahadevan)

DILLAVOU, SAMUEL Hidden Dynamics of Static Friction (Manoharan)

FLAMANT, CEDRIC Methods for Converging Solutions of Differential Equations: Applying Imaginary Time Propagation to Density Functional Theory and Unsupervised Neural Networks to Dynamical Systems (Kaxiras)

HUANG, KO-FAN (KATIE) Superconducting Proximity Effect in Graphene (Kim)

JONES, NATHAN Toward Antihydrogen Spectroscopy (Gabrielse)

KABCENELL, AARON Hybrid Quantum Systems with Nitrogen Vacancy Centers and Mechanical Resonators (Lukin)

KATES-HARBECK, JULIAN Tackling complexity and nonlinearity in plasmas and networks using artificial intelligence and analytical methods (Desai)

KIVLICHAN, IAN Faster quantum simulation of quantum chemistry with tailored algorithms and Hamiltonian s (Aspuru-Guzik, Lukin)

KOSOWSKY, MICHAEL Topological Phenomena in Two-Dimensional Electron Systems (Yacoby)

KUATE DEFO, RODRICK Modeling Formation and Stability of Fluorescent Defects in Wide-Bandgap Semiconductors (Kaxiras)

LEE, JONG YEON Fractionalization, Emergent Gauge Dynamics, and Topology in Quantum Matter (Vishwanath)

MARABLE, KATHRYN Progress towards a sub-ppb measurement of the antiproton magnetic moment (Gabrielse)

MCNAMARA, HAROLD Synthetic Physiology: Manipulating and measuring biological pattern formation with light (Cohen)

MEMET, EDVIN Parking, puckering, and peeling in small soft systems (Mahadevan)

NGUYEN, CHRISTIAN Building quantum networks using diamond nanophotonics (Lukin)

OLSON, JOSEPH Plasticity and Firing Rate Dynamics in Leaky Integrate-and-Fire Models of Cortical Circuits (Samuel)

ORONA, LUCAS Advances In The Singlet-Triplet Spin Qubit (Yacoby)

RACLARIU, ANA-MARIA On Soft Symmetries in Gravity and Gauge Theory (Strominger)

RAVI, AAKASH Topics in precision astrophysical spectroscopy (Dvorkin)

SHI, JING Quantum Hall Effect-Mediated Josephson Junctions in Graphene (Kim)

SHI, ZHUJUN Manipulating light with multifunctional metasurfaces (Capasso, Manoharan)

STEINBERG, JULIA Universal Aspects of Quantum-Critical Dynamics In and Out of Equilibrium  (Sachdev)

WILD, DOMINIK Algorithms and Platforms for Quantum Science and Technology (Lukin)

WU, HAI-YIN Biophysics of Mitotic Spindle Positioning in Caenorhabditis elegans Early Embryos (Needleman)

YU, LI Quantum Dynamics in Various Noise Scenarios (Heller)

BARKLEY, SOLOMON Applying Bayesian Inference to Measurements of Colloidal Dynamics (Manoharan)

BHASKAR, MIHIR Diamond Nanophotonic Quantum Networks (Lukin)

BINTU, BOGDAN Genome-scale imaging: from the subcellular structure of chromatin to the 3D organization of the peripheral olfactory system (Dulac,  Zhuang,  Nelson)

CHEN, MINGYUE On knotted surfaces in R 4   (Taubes,  Vafa)

CHO, MINJAE Aspects of string field theory (Yin)

DIAZ RIVERO, ANA Statistically Exploring Cracks in the Lambda Cold Dark Matter Model (Dvorkin)

DWYER, BO NV centers as local probes of two-dimensional materials (Lukin)

GATES, DELILAH Observational Electromagnetic Signatures of Spinning Black Holes (Strominger)

HANNESDOTTIR, HOFIE Analytic Structure and Finiteness of Scattering Amplitudes (Schwartz)

HART, CONNOR Experimental Realization of Improved Magnetic Sensing and Imaging in Ensembles of Nitrogen Vacancy Centers in Diamond (Walsworth, Park)

HÉBERT, ANNE A Dipolar Erbium Quantum Gas Microscope (Greiner)

JI, GEOFFREY Microscopic control and dynamics of a Fermi-Hubbard system (Greiner)

JOE, ANDREW Interlayer Excitons in Atomically Thin van der Waals Semiconductor Heterostructures (Kim)

KEESLING, ALEXANDER Quantum Simulation and Quantum Information Processing with Programmable Rydberg Atom Arrays (Lukin)

KRAHN, AARON Erbium gas quantum microscope (Greiner)

LANGELLIER, NICHOLAS Analytical and Statistical Models for Laboratory and Astrophysical Precision Measurements (Walsworth, Dvorkin)

LEMMA, BEZIA Hierarchical phases of filamentary active matter  (Dogic, Needleman)

LEVINE, HARRY Quantum Information Processing and Quantum Simulation with Programmable Rydberg Atom Arrays (Lukin)

LEVONIAN, DAVID A Quantum Network Node Based on the Silicon Vacancy Defect in Diamond (Lukin)

LIN, ALBERT Characterizing chemosensory responses of C. elegans with multi-neuronal imaging (Samuel)

LIU, SHANG Symmetry, Topology and Entanglement in Quantum Many-Body Systems (Vishwanath)

LIU, YU Bimolecular chemistry at sub-microkelvin temperatures (Ni)

MACHIELSE, BART Electronic and Nanophotonic Integration of a Quantum Network Node in Diamond (Lukin)

MELISSA, MATTHEW Divergence and diversity in rapidly evolving populations (Desai)

MILBOURNE, TIMOTHY All Features Great and Small: Distinquishing the effects of specific magnetically active features on radial-velocity exoplanet detections  (Walsworth)

MITCHELL, JAMES Investigations into Resinicolous Fungi (Pfister, Samuel)

MONDRIK, NICHOLAS Calibration Hardware and Methodology for Large Photometric Surveys (Stubbs)

NANDE, ANJALIKA Mathematical modeling of drug resistance and the transmission of SARS-CoV-2 (Hill, Desai)

PLUMMER, ABIGAIL Reactions and instabilities in fluid layers and elastic sheets (Nelson)

RODRIGUEZ, VICTOR Perturbative and Non-Perturbative Aspects of Two-Dimensional String Theory (Yin)

ROSENFELD, EMMA Novel techniques for control and transduction of solid-state spin qubits (Lukin)

SAMUTPRAPHOOT, POLNOP A quantum network node based on a nanophotonic interface for atoms in optical tweezers (Lukin)

SCHITTKO, ROBERT A method of preparing individual excited eigenstates of small quantum many-body systems  (Greiner)

SCHNEIDER, ELLIOT Stringy ER = EPR (Jafferis)

SONG, XUE-YANG Emergent and topological phenomena in many-body systems: Quantum spin liquids and beyond  (Vishwanath)

ST. GERMAINE, TYLER Beam Systematics and Primordial Gravitational Wave Constraints from the BICEP/Keck Array CMB Experiments (Kovac)

TORRISI, STEVEN Materials Informatics for Catalyst Stability & Functionality (Kaxiras, Kozinsky)

TURNER, MATTHEW Quantum Diamond Microscopes for Biological Systems and Integrated Circuits (Walsworth)

URBACH, ELANA Nanoscale Magnetometry with Single Spin Qubits in Diamond  (Lukin)

VENKAT, SIDDHARTH Modeling Excitons in Transition Metal Dichalcogenide Monolayers (Heller)

VENKATRAMANI, ADITYA Quantum nonlinear optics: controlling few-photon interactions (Lukin, Vuletić)

WANG, ANN A search for long-lived particles with large ionization energy loss in the ATLAS silicon pixel detector using 139 fb^{−1} of sqrt{s} = 13 TeV pp collisions (Franklin)

WILBURN, GREY An Inverse Statistical Physics Method for Biological Sequence Analysis (Eddy, Nelson)

XU, LINDA Searching for Dark Matter in the Early and Late Universe (Randall)

YI, KEXIN Neural Symbolic Machine Reasoning in the Physical World (Mahadevan, Finkbeiner)

YIN, JUN Improving our view of the Universe using Machine Learning  (Finkbeiner)

YU, YICHAO Coherent Creation of Single Molecules from Single Atoms (Ni)

ZHANG, JESSIE Assembling an array of polar molecules with full quantum-state control (Ni)

ZHAO, FRANK The Physics of High-Temperature Superconducting Cuprates in van der Waals Heterostructures (Kim)

ZHOU, LEO Complexity, Algorithms, and Applications of Programmable Quantum Many-Body Systems (Lukin)

ANDERSEN, TROND Local electronic and optical phenomena in two-dimensional materials (Lukin)

ANDERSON, LAUREL Electrical and thermoelectric transport in mixed-dimensional graphitic mesoscopic systems (Kim)

AUGENBRAUN, BENJAMIN Methods for Direct Laser Cooling of Polyatomic Molecules (Doyle)

BALL, ADAM Aspects of Symmetry in Four Dimensions (Strominger)

BOETTCHER, CHARLOTTE New avenues in circuit QED: from quantum information to quantum sensing (Yacoby)

BORGNIA, DAN The Measure of a Phase (Vishwanath)

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CHALUPNIK, MICHELLE Quantum and photonic information processing with non-von Neumann architectures (Lončar)

CHEN, YU-TING A Platform for Cavity Quantum Electrodynamics with Rydberg Atom Arrays (Vuletić)

CONWAY, WILL Biophysics of Kinetochore Microtubules in Human Mitotic Spindles (Needleman)

DIETERLE, PAUL Diffusive waves, dynamic instability, and chromosome missegregation: dimensionality, discreteness, stochasticity (Amir)

DORDEVIC, TAMARA A nanophotonic quantum interface for atoms in optical tweezers (Lukin)

ENGELKE, REBECCA Structure and Properties of Moiré Interfaces in Two Dimensional Materials (Kim)

FAN, XING An Improved Measurement of the Electron Magnetic Moment (Gabrielse)

FOPPIANI, NICOLÒ Testing explanations of short baseline neutrino anomalies (Guenette)

GHEORGHE, ANDREI Methods for inferring dynamical systems from biological data with applications to HIV latency and genetic drivers of aging (Hill)

HAEFNER, JONATHAN Improving Kr-83m Calibration and Energy Resolution in NEXT Neutrinoless Double Beta Decay Detectors (Guenette)

KOLCHMEYER, DAVID Toy Models of Quantum Gravity (Jafferis)

MCNAMARA, JAKE The Kinematics of Quantum Gravity (Vafa)

MENKE, TIM Classical and quantum optimization of quantum processors (Aspuru-Guzik, Oliver)

MICHAEL, MARIOS Parametric resonances in Floquet materials (Demler)

OBIED, GEORGES String Theory and its Applications in Cosmology and Particle Physics (Dvorkin, Vafa)

PARIKH, ADITYA Theoretical & Phenomenological Explorations of the Dark Sector (Reece)

PATTI, TAYLOR Quantum Systems for Computation and Vice Versa (Yelin)

PIERCE, ANDREW Local thermodynamic signatures of interaction-driven topological states in graphene (Yacoby)

PIRIE, HARRIS Interacting quantum materials and their acoustic analogs (Hoffman)

REZAI, KRISTINE Probing dynamics of a two-dimensional dipolar spin ensemble (Sushkov)

SAMAJDAR, RHINE Topological and symmetry-breaking phases of strongly correlated systems: From quantum materials to ultracold atoms (Sachdev)

SCURI, GIOVANNI Quantum Optics with Excitons in Atomically Thin Semiconductors (Park)

SHEN, YINAN Mechanics of Interpenetrating Biopolymer Networks in the Cytoskeleton and Biomolecular Condensates (Weitz)

SON, HYUNGMOK Collisional Cooling and Magnetic Control of Reactions in Ultracold Spin-polarized NaLi+Na Mixture (Ketterle)

SUSHKO, ANDREY Structural imaging and electro-optical control of two dimensional semiconductors (Lukin)

TANTIVASADAKARN, NATHANAN Exploring exact dualities in lattice models of topological phases of matter (Vishwanath)

VANDERMAUSE, JONATHAN Active Learning of Bayesian Force Fields (Kozinsky)

ZHOU, HENGYUN Quantum Many-Body Physics and Quantum Metrology with Floquet-Engineered Interacting Spin Systems (Lukin)

ZHU, ZOE Multiscale Models for Incommensurate Layered Two-dimensional Materials (Kaxiras)

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ANG, DANIEL Progress towards an improved measurement of the electric dipole moment of the electron (Gabrielse)

BADEA, ANTHONY Search for massive particles producing all hadronic final states in proton-proton collisions at the LHC with the ATLAS detector (Huth)

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BURCHESKY, SEAN Engineered Collisions, Molecular Qubits, and Laser Cooling of Asymmetric Top Molecules (Doyle)

CONG, IRIS Quantum Machine Learning, Error Correction, and Topological Phases of Matter (Lukin)

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DEPORZIO, NICK Dark Begets Light: Exploring Physics Beyond the Standard Model with Cosmology (Dvorkin, Randall)

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GABAI, BARAK From the S-matrix to the lattice: bootstrapping QFTs (Yin)

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HIMWICH, MINA Aspects of Symmetry in Classical and Quantum Gravity (Strominger)

HU, YAOWEN Coupled-resonators on thin-film lithium niobate: Photonic multi-level system with electro-optic transition (Lončar)

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LI, CHENYUAN Quantum Criticality and Superconductivity in Systems Without Quasiparticles (Sachdev)

MILLER, NOAH Gravity and Lw_{1 + infinity} symmetry (Strominger)

OZTURK, SUKRU FURKAN A New Spin on the Origin of Biological Homochirality (Sasselov)

PAN, GRACE Atomic-scale design and synthesis of unconventional superconductors (Mundy)

POLLACK, DANIEL Synthesis, characterization, and chemical stability analysis of quinones for aqueous organic redox flow batteries (Gordon)

SAYDJARI, ANDREW Statistical Models of the Spatial, Kinematic, and Chemical Complexity of Dust (Finkbeiner)

SHACKLETON, HENRY Fractionalization and disorder in strongly correlated systems (Sachdev)

SKRZYPEK, BARBARA The Case of the Missing Neutrino: Astrophysical Messengers of Planck-Scale Physics (Argüelles-Delgado)

TSANG, ARTHUR Strong Lensing, Dark Perturbers, and Machine Learning (Dvorkin)

XU, MUQING Quantum phases in Fermi Hubbard systems with tunable frustration (Greiner)

YE, BINGTIAN Out-of-equilibrium many-body dynamics in Atomic, Molecular and Optical systems (Yao)

ZAVATONE-VETH, JACOB Statistical mechanics of Bayesian inference and learning in neural networks (Pehlevan)

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PhD Thesis Guide

This phd thesis guide will guide you step-by-step through the thesis process, from your initial letter of intent to submission of the final document..

All associated forms are conveniently consolidated in the section at the end.

Deadlines & Requirements

Students should register for HST.ThG during any term in which they are conducting research towards their thesis. Regardless of year in program students registered for HST.ThG in a regular term (fall or spring) must meet with their research advisor and complete the  Semi-Annual PhD Student Progress Review Form to receive credit.

Years 1 - 2

• Students participating in lab rotations during year 1, may use the optional MEMP Rotation Registration Form , to formalize the arrangement and can earn academic credit by enrolling in HST.599. 
• A first letter of intent ( LOI-1 ) proposing a general area of thesis research and research advisor is required by April 30th of the second year of registration.
• A second letter of intent ( LOI-2 ) proposing a thesis committee membership and providing a more detailed description of the thesis research is required by April 30th of the third year of registration for approval by the HST-IMES Committee on Academic Programs (HICAP).

Year 4 

• Beginning in year 4, (or after the LOI-2 is approved) the student must meet with their thesis committee at least once per semester.
• Students must formally defend their proposal before the approved thesis committee, and submit their committee approved proposal to HICAP  by April 30 of the forth year of registration.
• Meetings with the thesis committee must be held at least once per semester. 

HST has developed these policies to help keep students on track as they progress through their PhD program. Experience shows that students make more rapid progress towards graduation when they interact regularly with a faculty committee and complete their thesis proposal by the deadline.

Getting Started

Check out these resources  for finding a research lab.

The Thesis Committee: Roles and Responsibilities

Students perform doctoral thesis work under the guidance of a thesis committee consisting of at least three faculty members from Harvard and MIT (including a chair and a research advisor) who will help guide the research. Students are encouraged to form their thesis committee early in the course of the research and in any case by the end of the third year of registration. The HST IMES Committee on Academic Programs (HICAP) approves the composition of the thesis committee via the letter of intent and the thesis proposal (described below). 

Research Advisor

The research advisor is responsible for overseeing the student's thesis project. The research advisor is expected to:

• oversee the research and mentor the student;
• provide a supportive research environment, facilities, and financial support;
• discuss expectations, progress, and milestones with the student and complete the  Semi-Annual PhD Student Progress Review Form each semester;
• assist the student to prepare for the oral qualifying exam;
• guide the student in selecting the other members of the thesis committee;
• help the student prepare for, and attend, meetings of the full thesis committee, to be held at least once per semester;
• help the student prepare for, and attend, the thesis defense;
• evaluate the final thesis document.

The research advisor is chosen by the student and must be a faculty member of MIT* or Harvard University and needs no further approval.  HICAP may approve other individuals as research advisor on a student-by-student basis. Students are advised to request approval of non-faculty research advisors as soon as possible.  In order to avoid conflicts of interest, the research advisor may not also be the student's academic advisor. In the event that an academic advisor becomes the research advisor, a new academic advisor will be assigned.

The student and their research advisor must complete the Semi-Annual PhD Student Progress Review during each regular term in order to receive academic credit for research.  Download Semi Annual Review Form

*MIT Senior Research Staff are considered equivalent to faculty members for the purposes of research advising. No additional approval is required.

Thesis Committee Chair

Each HST PhD thesis committee is headed administratively by a chair, chosen by the student in consultation with the research advisor. The thesis committee chair is expected to:

• provide advice and guidance concerning the thesis research; 
• oversee meetings of the full thesis committee, to be held at least once per semester;
• preside at the thesis defense; 
• review and evaluate the final thesis document.

The thesis committee chair must be well acquainted with the academic policies and procedures of the institution granting the student's degree and be familiar with the student's area of research. The research advisor may not simultaneously serve as thesis committee chair.

For HST PhD students earning degrees through MIT, the thesis committee chair must be an MIT faculty member. A select group of HST program faculty without primary appointments at MIT have been pre-approved by HICAP to chair PhD theses awarded by HST at MIT in cases where the MIT research advisor is an MIT faculty member.**

HST PhD students earning their degree through Harvard follow thesis committee requirements set by the unit granting their degree - either the Biophysics Program or the School of Engineering and Applied Sciences (SEAS).

** List of non-MIT HST faculty approved to chair MIT thesis proposals when the research advisor is an MIT faculty member.

In addition to the research advisor and the thesis committee chair, the thesis committee must include one or more readers. Readers are expected to:

• attend meetings of the full thesis committee, to be held at least once per semester;
• attend the thesis defense; 

Faculty members with relevant expertise from outside of Harvard/MIT may serve as readers, but they may only be counted toward the required three if approved by HICAP.

The members of the thesis committee should have complementary expertise that collectively covers the areas needed to advise a student's thesis research. The committee should also be diverse, so that members are able to offer different perspectives on the student's research. When forming a thesis committee, it is helpful to consider the following questions: 

• Do the individuals on the committee collectively have the appropriate expertise for the project?
• Does the committee include at least one individual who can offer different perspectives on the student's research?  The committee should include at least one person who is not closely affiliated with the student's primary lab. Frequent collaborators are acceptable in this capacity if their work exhibits intellectual independence from the research advisor.
• If the research has a near-term clinical application, does the committee include someone who can add a translational or clinical perspective?  
• Does the committee conform to HST policies in terms of number, academic appointments, and affiliations of the committee members, research advisor, and thesis committee chair as described elsewhere on this page?

[Friendly advice: Although there is no maximum committee size, three or four is considered optimal. Committees of five members are possible, but more than five is unwieldy.]

Thesis Committee Meetings

Students must meet with their thesis committee at least once each semester beginning in the fourth year of registration. It is the student's responsibility to schedule these meetings; students who encounter difficulties in arranging regular committee meetings can contact Julie Greenberg at jgreenbe [at] mit.edu (jgreenbe[at]mit[dot]edu) .

The format of the thesis committee meeting is at the discretion of the thesis committee chair. In some cases, the following sequence may be helpful:

• The thesis committee chair, research advisor, and readers meet briefly without the student in the room;
• The thesis committee chair and readers meet briefly with the student, without the advisor in the room;
• The student presents their research progress, answers questions, and seeks guidance from the members of the thesis committee;

Please note that thesis committee meetings provide an important opportunity for students to present their research and respond to questions. Therefore, it is in the student's best interest for the research advisor to refrain from defending the research in this setting.

Letters of Intent

Students must submit two letters of intent ( LOI-1 and LOI-2 ) with applicable signatures. 

In LOI-1, students identify a research advisor and a general area of thesis research, described in 100 words or less. It should include the area of expertise of the research advisor and indicate whether IRB approval (Institutional Review Board; for research involving human subjects) and/or IACUC approval (Institutional Animal Care and Use Committee; for research involving vertebrate animals) will be required and, if so, from which institutions. LOI-1 is due by April 30 of the second year of registration and and should be submitted to HICAP, c/o Traci Anderson in E25-518. 

In LOI-2, students provide a description of the thesis research, describing the Background and Significance of the research and making a preliminary statement of Specific Aims (up to 400 words total). In LOI-2, a student also proposes the membership of their thesis committee. In addition to the research advisor, the proposed thesis committee must include a chair and one or more readers, all selected to meet the specified criteria . LOI-2 is due by April 30th of the third year of registration and should be submitted to HICAP, c/o Traci Anderson in E25-518.

LOI-2 is reviewed by the HST-IMES Committee on Academic Programs (HICAP) to determine if the proposed committee meets the specified criteria and if the committee members collectively have the complementary expertise needed to advise the student in executing the proposed research. If HICAP requests any changes to the proposed committee, the student must submit a revised LOI-2 for HICAP review by September 30th of the fourth year of registration. HICAP must approve LOI-2 before the student can proceed to presenting and submitting their thesis proposal. Any changes to the thesis committee membership following HICAP approval of LOI-2 and prior to defense of the thesis proposal must be reported by submitting a revised LOI-2 form to HICAP, c/o tanderso [at] mit.edu (Traci Anderson) . After final HICAP approval of LOI-2, which confirms the thesis committee membership, the student may proceed to present their thesis proposal to the approved thesis committee, as described in the next section.

Students are strongly encouraged to identify tentative thesis committee members and begin meeting with them as early as possible to inform the direction of their research. Following submission of LOI-2, students are required to hold at least one thesis committee meeting per semester. Students must document these meetings via the Semi- Annual PhD Student Progress Review form in order to receive a grade reflecting satisfactory progress in HST.ThG.

Thesis Proposal and Proposal Presentation

For MEMP students receiving their degrees through MIT, successful completion of the Oral Qualifying Exam is a prerequisite for the thesis proposal presentation. For MEMP students receiving their degrees through Harvard, the oral qualifying exam satisfies the proposal presentation requirement.

Proposal Document

Each student must present a thesis proposal to a thesis committee that has been approved by HICAP via the LOI-2 and then submit a full proposal package to HICAP by April 30th of the fourth year of registration. The only exception is for students who substantially change their research focus after the fall term of their third year; in those cases the thesis proposal must be submitted within three semesters of joining a new lab. Students registering for thesis research (HST.THG) who have not met this deadline may be administratively assigned a grade of "U" (unsatisfactory) and receive an academic warning.

The written proposal should be no longer than 4500 words, excluding references. This is intended to help students develop their proposal-writing skills by gaining experience composing a practical proposal; the length is comparable to that required for proposals to the NIH R03 Small Research Grant Program. The proposal should clearly define the research problem, describe the proposed research plan, and defend the significance of the work. Preliminary results are not required. If the proposal consists of multiple aims, with the accomplishment of later aims based on the success of earlier ones, then the proposal should describe a contingency plan in case the early results are not as expected.

Proposal Presentation

The student must formally defend the thesis proposal before the full thesis committee that has been approved by HICAP.

Students should schedule the meeting and reserve a conference room and any audio visual equipment they may require for their presentation. To book a conference room in E25, please contact Joseph Stein ( jrstein [at] mit.edu (jrstein[at]mit[dot]edu) ).

Following the proposal presentation, students should make any requested modifications to the proposal for the committee members to review. Once the committee approves the proposal, the student should obtain the signatures of the committee members on the forms described below as part of the proposal submission package.

[Friendly advice: As a professional courtesy, be sure your committee members have a complete version of your thesis proposal at least one week in advance of the proposal presentation.]

Submission of Proposal Package

When the thesis committee has approved the proposal, the student submits the proposal package to HICAP, c/o Traci Anderson in E25-518, for final approval. HICAP may reject a thesis proposal if it has been defended before a committee that was not previously approved via the LOI-2.

The proposal package includes the following: 

• the proposal document
• a brief description of the project background and significance that explains why the work is important;
• the specific aims of the proposal, including a contingency plan if needed; and
• an indication of the methods to be used to accomplish the specific aims.
• signed research advisor agreement form(s);
• signed chair agreement form (which confirms a successful proposal defense);
• signed reader agreement form(s).

Thesis Proposal Forms

• SAMPLE Title Page (doc)
• Research Advisor Agreement Form (pdf)
• Chair Agreement Form (pdf)
• Reader Agreement Form (pdf)

Thesis Defense and Final Thesis Document

When the thesis is substantially complete and fully acceptable to the thesis committee, a public thesis defense is scheduled for the student to present his/her work to the thesis committee and other members of the community. The thesis defense is the last formal examination required for receipt of a doctoral degree. To be considered "public", a defense must be announced to the community at least five working days in advance. At the defense, the thesis committee determines if the research presented is sufficient for granting a doctoral degree. Following a satisfactory thesis defense, the student submits the final thesis document, approved by the research advisor, to Traci Anderson via email (see instructions below).

[Friendly advice: Contact jrstein [at] mit.edu (Joseph Stein) at least two weeks before your scheduled date to arrange for advertising via email and posters. A defense can be canceled for insufficient public notice.]

Before the Thesis Defense 

Committee Approves Student to Defend: The thesis committee, working with the student and reviewing thesis drafts, concludes that the doctoral work is complete. The student should discuss the structure of the defense (general guidelines below) with the thesis committee chair and the research advisor. 

Schedule the Defense: The student schedules a defense at a time when all members of the thesis committee will be physical present. Any exceptions must be approved in advance by the IMES/HST Academic Office.

Reserve Room: It is the student's responsibility to reserve a room and any necessary equipment. Please contact imes-reservation [at] mit.edu (subject: E25%20Room%20Reservation) (IMES Reservation) to  reserve rooms E25-140, E25-141, E25-119/121, E25-521. 

Final Draft: A complete draft of the thesis document is due to the thesis committee two weeks prior to the thesis defense to allow time for review.  The thesis should be written as a single cohesive document; it may include content from published papers (see libraries website on " Use of Previously Published Material in a Thesis ") but it may not be a simple compilation of previously published materials.

Publicize the Defense:   The IMES/HST Academic Office invites the community to attend the defense via email and a notice on the HST website. This requires that the student email a thesis abstract and supplemental information to  jrstein [at] mit.edu (Joseph Stein)  two weeks prior to the thesis defense. The following information should be included: Date and time, Location, (Zoom invitation with password, if offering a hybrid option), Thesis Title, Names of committee members, with academic and professional titles and institutional affiliations. The abstract is limited to 250 words for the poster, but students may optionally submit a second, longer abstract for the email announcement.

Thesis Defense Guidelines

Public Defense: The student should prepare a presentation of 45-60 minutes in length, to be followed by a public question and answer period of 15–30 minutes at discretion of the chair.

Committee Discussion:  Immediately following the public thesis presentation, the student meets privately with the thesis committee and any other faculty members present to explore additional questions at the discretion of the faculty. Then the thesis committee meets in executive session and determines whether the thesis defense was satisfactory. The committee may suggest additions or editorial changes to the thesis document at this point.

Chair Confirms Pass: After the defense, the thesis committee chair should inform Traci Anderson of the outcome via email to tanderso [at] mit.edu (tanderso[at]mit[dot]edu) .

Submitting the Final Thesis Document

Please refer to the MIT libraries  thesis formatting guidelines .

Title page notes. Sample title page  from the MIT Libraries.

Program line : should read, "Submitted to the Harvard-MIT Program in Health Sciences and Technology, in partial fulfillment of the the requirements for the degree of ... "

Copyright : Starting with the June 2023 degree period and as reflected in the  MIT Thesis Specifications , all students retain the copyright of their thesis.  Please review this section for how to list on your title page Signature Page: On the "signed" version, only the student and research advisor should sign. Thesis committee members are not required to sign. On the " Accepted by " line, please list: Collin M. Stultz, MD, PhD/Director, Harvard-MIT Program in Health Sciences and Technology/ Nina T. and Robert H. Rubin Professor in Medical Engineering and Science/Professor of Electrical Engineering and Computer Science.

The Academic Office will obtain Professor Stultz's signature.

Thesis Submission Components.  As of 4/2021, the MIT libraries have changed their thesis submissions guidelines and are no longer accepting hard copy theses submissions. For most recent guidance from the libraries:  https://libguides.mit.edu/mit-thesis-faq/instructions  

Submit to the Academic Office, via email ( tanderso [at] mit.edu (tanderso[at]mit[dot]edu) )

pdf/A-1 of the final thesis should include an UNSIGNED title page

A separate file with a SIGNED title page by the student and advisor, the Academic Office will get Dr. Collin Stultz's signature.

For the MIT Library thesis processing, fill out the "Thesis Information" here:  https://thesis-submit.mit.edu/

File Naming Information:  https://libguides.mit.edu/

Survey of Earned Doctorates.  The University Provost’s Office will contact all doctoral candidates via email with instructions for completing this survey.

Links to All Forms in This Guide

• MEMP Rotation Form (optional)
• Semi-Annual Progress Review Form
• Letter of Intent One
• Letter of Intent Two

Final Thesis

• HST Sample thesis title page  (signed and unsigned)
• Sample thesis title page  (MIT Libraries)

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Dissertation Formatting Guidance

The following resource shares some best practice guidance for dissertation formatting. 

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The following resource shares some best practice guidance for dissertation formatting. Please note that some of the elements outlined below are required and will be reviewed by the FAS Registrar's Office as part of Harvard Griffin GSAS policies on formatting . 

Language of the Dissertation

The language of the dissertation is ordinarily English, although some departments whose subject matter involves foreign languages may accept a dissertation written in a language other than English.

Most dissertations are 100 to 300 pages in length. All dissertations should be divided into appropriate sections, and long dissertations may need chapters, main divisions, and subdivisions.

Page and Text Requirements

• 8½ x 11 inches, unless a musical score is included
• At least 1 inch for all margins
• Body of text: double spacing
• Block quotations, footnotes, and bibliographies: single spacing within each entry but double spacing between each entry
• Table of contents, list of tables, list of figures or illustrations, and lengthy tables: single spacing may be used

Fonts and Point Size

Use 10-12 point size. Fonts must be embedded in the PDF file to ensure all characters display correctly. 

Recommended Fonts

If you are unsure whether your chosen font will display correctly, use one of the following fonts: 

If fonts are not embedded, non-English characters may not appear as intended. Fonts embedded improperly will be published to DASH as is. It is the student’s responsibility to make sure that fonts are embedded properly prior to submission. 

Instructions for Embedding Fonts

To embed your fonts in recent versions of Word, follow these instructions from Microsoft:

• Click the File tab and then click Options .
• In the left column, select the Save tab.
• Clear the Do not embed common system fonts check box.

For reference, below are some instructions from ProQuest UMI for embedding fonts in older file formats:

To embed your fonts in Microsoft Word 2010:

• In the File pull-down menu, click on Options .
• Choose Save on the left sidebar.
• Check the box next to Embed fonts in the file.
• Click the OK button.
• Save the document.

Note that when saving as a PDF, make sure to go to “more options” and save as “PDF/A compliant”

To embed your fonts in Microsoft Word 2007:

• Click the circular Office button in the upper left corner of Microsoft Word.
• A new window will display. In the bottom right corner select Word Options . 
• Choose Save from the left sidebar.

Using Microsoft Word on a Mac:

Microsoft Word 2008 on a Mac OS X computer will automatically embed your fonts while converting your document to a PDF file.

If you are converting to PDF using Acrobat Professional (instructions courtesy of the Graduate Thesis Office at Iowa State University):  

• Open your document in Microsoft Word. 
• Click on the Adobe PDF tab at the top. Select "Change Conversion Settings." 
• Click on Advanced Settings. 
• Click on the Fonts folder on the left side of the new window. In the lower box on the right, delete any fonts that appear in the "Never Embed" box. Then click "OK." 
• If prompted to save these new settings, save them as "Embed all fonts." 
• Now the Change Conversion Settings window should show "embed all fonts" in the Conversion Settings drop-down list and it should be selected. Click "OK" again. 
• Click on the Adobe PDF link at the top again. This time select Convert to Adobe PDF. Depending on the size of your document and the speed of your computer, this process can take 1-15 minutes. 
• After your document is converted, select the "File" tab at the top of the page. Then select "Document Properties." 
• Click on the "Fonts" tab. Carefully check all of your fonts. They should all show "(Embedded Subset)" after the font name. 
•  If you see "(Embedded Subset)" after all fonts, you have succeeded.

Body of Text, Tables, Figures, and Captions

The font used in the body of the text must also be used in headers, page numbers, and footnotes. Exceptions are made only for tables and figures created with different software and inserted into the document.

Tables and figures must be placed as close as possible to their first mention in the text. They may be placed on a page with no text above or below, or they may be placed directly into the text. If a table or a figure is alone on a page (with no narrative), it should be centered within the margins on the page. Tables may take up more than one page as long as they obey all rules about margins. Tables and figures referred to in the text may not be placed at the end of the chapter or at the end of the dissertation.

• Given the standards of the discipline, dissertations in the Department of History of Art and Architecture and the Department of Architecture, Landscape Architecture, and Urban Planning often place illustrations at the end of the dissertation.

Figure and table numbering must be continuous throughout the dissertation or by chapter (e.g., 1.1, 1.2, 2.1, 2.2, etc.). Two figures or tables cannot be designated with the same number. If you have repeating images that you need to cite more than once, label them with their number and A, B, etc. 

Headings should be placed at the top of tables. While no specific rules for the format of table headings and figure captions are required, a consistent format must be used throughout the dissertation (contact your department for style manuals appropriate to the field).

Captions should appear at the bottom of any figures. If the figure takes up the entire page, the caption should be placed alone on the preceding page, centered vertically and horizontally within the margins.

Each page receives a separate page number. When a figure or table title is on a preceding page, the second and subsequent pages of the figure or table should say, for example, “Figure 5 (Continued).” In such an instance, the list of figures or tables will list the page number containing the title. The word “figure” should be written in full (not abbreviated), and the “F” should be capitalized (e.g., Figure 5). In instances where the caption continues on a second page, the “(Continued)” notation should appear on the second and any subsequent page. The figure/table and the caption are viewed as one entity and the numbering should show correlation between all pages. Each page must include a header.

Landscape orientation figures and tables must be positioned correctly and bound at the top so that the top of the figure or table will be at the left margin. Figure and table headings/captions are placed with the same orientation as the figure or table when on the same page. When on a separate page, headings/captions are always placed in portrait orientation, regardless of the orientation of the figure or table. Page numbers are always placed as if the figure were vertical on the page.

If a graphic artist does the figures, Harvard Griffin GSAS will accept lettering done by the artist only within the figure. Figures done with software are acceptable if the figures are clear and legible. Legends and titles done by the same process as the figures will be accepted if they too are clear, legible, and run at least 10 or 12 characters per inch. Otherwise, legends and captions should be printed with the same font used in the text.

Original illustrations, photographs, and fine arts prints may be scanned and included, centered between the margins on a page with no text above or below.

Pages should be assigned a number except for the Thesis Acceptance Certificate. Preliminary pages (abstract, table of contents, list of tables, graphs, illustrations, and preface) should use small Roman numerals (i, ii, iii, iv, v, etc.). All pages must contain text or images.  

Count the title page as page i and the copyright page as page ii, but do not print page numbers on either page .

For the body of text, use Arabic numbers (1, 2, 3, 4, 5, etc.) starting with page 1 on the first page of text. Page numbers must be centered throughout the manuscript at the top or bottom. Every numbered page must be consecutively ordered, including tables, graphs, illustrations, and bibliography/index (if included); letter suffixes (such as 10a, 10b, etc.) are not allowed. It is customary not to have a page number on the page containing a chapter heading.

Check pagination carefully. Account for all pages.

Thesis Acceptance Certificate

A copy of the Thesis Acceptance Certificate should appear as the first page. This page should not be counted or numbered. The DAC will appear in the online version of the published dissertation. The author name and date on the DAC and title page should be the same. 

The dissertation begins with the title page; the title should be as concise as possible and should provide an accurate description of the dissertation. The author name and date on the DAC and title page should be the same. 

Do not print a page number on the title page. It is understood to be page  i  for counting purposes only.

Copyright Statement

A copyright notice should appear on a separate page immediately following the title page and include the copyright symbol ©, the year of first publication of the work, and the name of the author:

© [ year ] [ Author’s Name ] All rights reserved.

Alternatively, students may choose to license their work openly under a  Creative Commons  license. The author remains the copyright holder while at the same time granting up-front permission to others to read, share, and (depending on the license) adapt the work, so long as proper attribution is given. (By default, under copyright law, the author reserves all rights; under a Creative Commons license, the author reserves some rights.)

Do  not  print a page number on the copyright page. It is understood to be page  ii  for counting purposes only.

An abstract, numbered as page  iii , should immediately follow the copyright page and should state the problem, describe the methods and procedures used, and give the main results or conclusions of the research. The abstract will appear in the online and bound versions of the dissertation and will be published by ProQuest. There is no maximum word count for the abstract. 

• double-spaced
• left-justified
• indented on the first line of each paragraph
• The author’s name, right justified
• The words “Dissertation Advisor:” followed by the advisor’s name, left-justified (a maximum of two advisors is allowed)
• Title of the dissertation, centered, several lines below author and advisor
• Table of Contents

Dissertations divided into sections must contain a table of contents that lists, at minimum, the major headings in the following order:

• Front Matter
• Body of Text
• Back Matter

Front and Back Matter

Front matter includes (if applicable):

• acknowledgements of help or encouragement from individuals or institutions
• a dedication
• a list of illustrations or tables
• a glossary of terms
• one or more epigraphs.

Back matter includes (if applicable):

• bibliography
• supplemental materials, including figures and tables
• an index (in rare instances).

Supplemental Material

Supplemental figures and tables must be placed at the end of the dissertation in an appendix, not within or at the end of a chapter. If additional digital information (including audio, video, image, or datasets) will accompany the main body of the dissertation, it should be uploaded as a supplemental file through ProQuest ETD . Supplemental material will be available in DASH and ProQuest and preserved digitally in the Harvard University Archives.

Harvard Library Office for Scholarly Communication

Preparation of MUP Design Thesis

What does it take to complete a graduate thesis in the Department of Urban Planning and Design? The seminar introduces different types of theses that might be produced by students, whether textual, design-focused, or based in some other medium, such as film. It addresses topic and question identification, research methods, case selection, the craft of thesis production, managing the student-advisor relationship, and techniques for verbally defending a thesis.

Over the semester, students identify and refine their thesis topic, solidify their relationship with a thesis advisor, and produce a thesis proposal. By the end of the semester, students will have produced a solid thesis proposal and have the necessary intellectual foundation to complete their thesis by the end of the academic year.

Course meetings combine input from faculty, group discussions, progress reports by students, and reflections on next steps. The course will include a midterm and final review of students' proposals, to be attended by faculty and critics.

How Alan Garber ended the Harvard protest encampment peacefully

I t would not be quite right to say that anyone won the battle of Harvard Yard. But Alan M. Garber, the interim president of the university, has survived it — for now.

Protesters were exiting the yard Tuesday after about three weeks of camping out , and they’ll likely be reinstated soon as students. School leaders have agreed to meet to discuss the university’s investment practices, but Garber has told them Harvard will not divest from Israel. Preparations for commencement can move forward, to the relief of thousands with plane tickets and hotel reservations.

Garber outlasted the protesters, and did so without calling in police or using over-the-top rhetoric to shame student demonstrators. It’s a best-case scenario in one of the grimmest academic years in Harvard’s recent history — and, surely, in Garber’s career. Some think this test of his leadership has proven his mettle to stay on permanently as president.

“I suspect it reinforces Alan’s approach to conflict,” said Barbara McNeil, a Harvard Medical School professor, radiologist, and longtime friend of Garber. She described him as even-handed, calm, logical, with the “ability to think about downstream consequences.”

The secretive Harvard Corporation, the school’s top governing board, has yet to assemble a search committee to find a successor to Claudine Gay, who resigned on Jan. 2 amid plagiarism accusations and criticism of her handling of campus antisemitism. Some faculty view this as a nod to Garber’s performance thus far.

Garber, who declined an interview, has not indicated whether he is interested in the permanent role.

In the last several weeks, Garber faced enormous pressure from students, professors, alumni, parents, and conservative politicians with strong and conflicting views on what should be done about the protesters and their divestment demands.

The protesters’ fight has sometimes turned harshly confrontational, personal, and vicious. Protesters have chanted outside Garber’s Hawthorn Street home. Last week a poster hung from a tree in Harvard Yard portrayed Garber, who is Jewish, as a devil, with horns and a tail, sitting on a toilet, with the words: “Alan Garbage funds genocide.” The depiction of Jews as demons is a longstanding antisemitic trope.

“It’s unbelievably stressful to have hundreds of people march to your house and stand on your front lawn screaming at you, calling you names,” said Jeffrey Flier, a former dean of Harvard Medical School who co-leads a Harvard faculty group, the Council on Academic Freedom. “Pictures of you looking like the devil — these are things that I wouldn’t wish on my worst enemy.”

And it isn’t really over, protesters say. The demonstrators said they are entering “the beginning of a new phase . . . a shift in strategy” in their fight to get Harvard to divest from Israel. “Harvard beware,” the Harvard Out of Occupied Palestine group posted on its Instagram account just before dismantling the camp, “the Liberated Zone is everywhere.”

A runner who has raced in marathons, Garber is known as thoughtful, cerebral. A physician with a PhD in economics, he has spent a lifetime thinking about the value of medical interventions, weighing the effectiveness of a cure against its costs.

He previously served as Harvard’s provost for about a dozen years. Several faculty members described him as principled and fair. Even those who at times have disagreed with his decisions respect him, said Alison Frank Johnson, a history professor.

“He didn’t mind that you disagreed with him,” Frank Johnson said about Garber’s time as provost. “He was boundlessly intellectually curious. If you have an argument about why he is making the wrong choice, he wants to hear it.”

Garber holds three Harvard degrees, completing his undergraduate degree in economics in 1976, before earning a master’s and PhD in economics, publishing a dissertation on the costs of antibiotic resistance. While pursuing his doctorate at Harvard, Garber was also working toward a medical degree at the Stanford University School of Medicine.

He completed a residency program in Boston at Brigham and Women’s Hospital before joining the faculty at Stanford, where he taught medicine, health research and policy, and economics for 25 years. He returned to Cambridge in 2011 under former Harvard president Drew Faust.

He was appointed interim president when Gay departed in early January. Since stepping into the role, he has helped defuse tension on a campus that was roiled by protests and controversies after the Oct. 7 Hamas-led attack on Israel.

“He stepped in to the leadership position this past January at, to say the least, one of the most challenging times in Harvard’s history,” said Richard Lazarus, a Harvard Law professor. “He created some much-needed immediate calm.”

Garber created two task forces to study and combat antisemitism and anti-Muslim and anti-Arab bias. When former Harvard president Larry Summers and Jonathan Greenblatt, chief executive of the Anti-Defamation League, criticized Garber’s appointment of Derek Penslar, a leading scholar of Zionism, to co-lead the committee on antisemitism, Garber did not waver . Garber thinks through decisions carefully, likely a result of his economics training, McNeil said.

“Alan has kept the temperature down more than at many other schools,” McNeil said. “It’s just a reflection of who he is as a person.”

Garber spent much of the spring semester rebuilding trust among donors, families, and prospective students who were concerned about the controversies from the fall, some of whom had lost faith in the institution and were deeply worried about reports of antisemitism on the campus. He traveled around the country and internationally to meet with alumni and donors in person, a spokesperson said, and held meetings with concerned affiliates in Cambridge. He also formed a working group to explore adoption of a policy of neutrality, in which the university would not take any position on current affairs to protect academic freedom of students and faculty.

“I am the interim president,” Garber said to Harvard Magazine in February. “But the problems we need to deal with are not interim problems.”

Over the winter he updated campus guidelines on protests to essentially forbid demonstrations in school buildings and limit disruption to university operations. Some criticized him, noting past generations of students used building takeovers and other disruptive tactics to push for changes. In 2001, students occupied Massachusetts Hall, home to the president’s office, and set up an encampment to push for living wages for Harvard workers. The efforts were largely successful and protesters received little or no discipline, according to an op/ed in the Harvard Crimson, the student newspaper.

Two Harvard Kennedy School graduates who participated in the 2001 protest recently wrote in the Crimson that Garber’s response to the Gaza protesters, in contrast, “feels contemptuous.”

Yet, the spring semester was going relatively smoothly compared to the fall, until late April when students camped out in Harvard Yard after demonstrators at Columbia University were arrested.

Student organizers sought to bring attention to the growing death toll in Gaza, where more than 34,000 have died since Israel invaded after the Hamas-led terror attack. They wanted Harvard to disclose and divest Israeli investments, and to drop disciplinary charges against students related to pro-Palestinian advocacy.

Harvard leaders let the encampment stand for weeks despite calls from some alumni and donors to call on law enforcement to remove it with force. Garber also didn’t negotiate with protesters; some schools that did, including Brown University and Rutgers University, faced swift backlash from conservative politicians and donors for engaging with pro-Palestinian demands.

Instead, Garber threatened to discipline the students, eventually suspending them so they could no longer move freely in and out of Harvard Yard and the surrounding buildings. He ultimately gave the pro-Palestinian student protesters a couple of face-saving concessions but made no commitments about divestment; more substantially, he agreed to all but drop the suspensions. Some still face separate disciplinary proceedings.

Ultimately, though, he simply outlasted them by making it uncomfortable and unproductive for the students to stay in a locked, largely abandoned Harvard Yard, without access to bathrooms, food, or the world outside. The protesters voted Monday night to dismantle the camp.

Leandro Urbano, who will graduate from the Harvard Kennedy School later this month, said the conflict seemed to come to a resolution without the constant media firestorm the school endured in the fall.

“President Garber has been much more balanced in his dealing with both sides,” Urbano said. He added that students participating in the encampment also remained “civilized.”

Garber has likely relied on his marathon trainings in recent days, said Daniel Lieberman, a biological anthropologist at Harvard who used to run with Garber.

Long-distance runners “don’t give up,” Lieberman said. “It’s about endurance.”

Globe correspondent Maddie Khaw contributed to this report.

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Indiana University Graduate School Indianapolis

• Purdue Graduate Students
• Theses & Dissertations
• Submission Methods

Once you’ve finalized your dissertation, your instructions for submission vary depending on whether your degree is conferred through IU or Purdue.

Purdue Dissertation Submission

The details for submitting a dissertation for a Purdue graduate program at IUPUI can be found here, in the Purdue Graduate Student pages of our website.

IU Dissertation Submission

Pay careful attention to the deadlines for each of these steps.

Complete the steps below, in order, to submit your dissertation.

Step 1: Defend

Defend your dissertation.

Step 2: Schedule a Format Check

Once you are ready to begin the submission process, email the IU Graduate School Indianapolis recorder to schedule a format check. The scheduling of this appointment is mostly determined by the post-defense revisions required by your committee, but should take place well in advance of your expected graduation date to avoid delay. Submit the following for the format check:

• Committee approved dissertation
• Copy of the signed acceptance page
• Copy of the signed abstract

Step 3: Submit to ProQuest and IUPUI ScholarWorks.

IUPUI students must submit the fully approved and formatted dissertation to ProQuest, which will automatically upload it to ScholarWorks upon ProQuest approval. Make sure you read all submission instructions before attempting to submit through ProQuest.

You’ll need to decide if you want to register your copyright . Copyright registration is optional, and there is a fee associated with ProQuest.

Once at the site, select “Submit my dissertation/thesis,” and follow the instructions. Email the following to the University Graduate School Recorder:

• Confirmation of electronic submission and fee receipt

Step 4. Have Your Dissertation Bound

If you choose to order a bound copy that will accept dissertation and thesis orders, a list of binderies can be found in the attached document "Dissertation and Thesis Bound Copies: Bindery Information." This is in no way an endorsement of services by Indiana University, it is simply a courtesy to our graduate students.

Students must work with the individual binderies to obtain pricing and the document transfer logistics required for each.

If the bindery does not have its own print press, ask for print shop recommendations.

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UT Electronic Theses and Dissertations

Permanent URI for this community https://hdl.handle.net/2152/4

This collection contains University of Texas at Austin electronic theses and dissertations (ETDs). The collection includes ETDs primarily from 2001 to the present. Some pre-2001 theses and dissertations have been digitized and added to this collection, but those are uncommon. The library catalog is the most comprehensive list of UT Austin theses and dissertations.

Since 2010, the Office of Graduate Studies at UT Austin has required all theses and dissertations to be made publicly available in Texas ScholarWorks; however, authors are able to request an embargo of up to seven years. Embargoed ETDs will not show up in this collection. Most of the ETDs in this collection are freely accessible to all users, but some pre-2010 works require a current UT EID at point of use. Please see the FAQs for more information. If you have a question about the availability of a specific ETD, please contact [email protected].

Some items in this collection may contain offensive images or text. The University of Texas Libraries is committed to maintaining an accurate and authentic scholarly and historic record. An authentic record is essential for understanding our past and informing the present. In order to preserve the authenticity of the historical record we will not honor requests to redact content, correct errors, or otherwise remove content, except in cases where there are legal concerns (e.g. potential copyright infringement, inclusion of HIPAA/FERPA protected information or Social Security Numbers) or evidence of a clear and imminent threat to personal safety or well-being.

This policy is in keeping with the  American Library Association code of ethics  to resist efforts to censor library resources, and the  Society of American Archivists code of ethics  that states "archivists may not willfully alter, manipulate, or destroy data or records to conceal facts or distort evidence." Please see UT Libraries'  Statement on Harmful Language and Content  for more information.

Authors of these ETDs have retained their copyright while granting the University of Texas Libraries the non-exclusive right to reproduce and distribute their works.

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• UT Electronic Theses and Dissertations   30995