best research topics in inorganic chemistry

100+ Great Chemistry Research Topics

Table of contents

1 What are the best chemistry research topics?
2 5 Tips for Writing Chemistry Research Papers
3 Chemical Engineering Research Topics
4 Organic Сhemistry Research Topics
5 Іnorganic Сhemistry Research Topics
6 Biomolecular Сhemistry Research Topics
7 Analytical Chemistry Research Topics
8 Computational Chemistry Research Topics
9 Physical Chemistry Research Topics
10 Innovative Chemistry Research Topics
11 Environmental Chemistry Research Topics
12 Green Chemistry Research Topics
13.1 Conclusion

Do you need a topic for your chemistry research paper? Are you unsure of where to start? Don’t worry – we’re here to help. In this post, we’ll go over a series of the best chemistry research paper topics as well as Tips for Writing Chemistry Research Papers on different topics. By the time you finish reading this post, you’ll have plenty of ideas to get started on your next research project!

There are many different subfields of chemistry, so it can be tough to find interesting chemistry topics to write about. If you’re struggling to narrow down your topic, we’ll go over lists of topics in multiple fields of study.

What are the best chemistry research topics?

Doing research is important to help scientists learn more about the world around us. By researching different compounds and elements, we can learn more about how they interact with one another and how they can be used to create new products or improve existing ones.

There are many different topics that you can choose to research in chemistry. Here are just a few examples:

The history of chemistry and how it has evolved over time
How different chemicals react with one another
How to create new compounds or improve existing ones
The role of chemistry in the environment
The health effects of different chemicals

5 Tips for Writing Chemistry Research Papers

Once you have chosen a topic for your research paper , it is important to follow some tips to ensure that your paper is well-written and accurate. Here are a few tips to get you started:

Start by doing some background research on your topic. This will help you understand the basics of the topic and give you a good foundation to build your paper on.
Make sure to cite all of the sources that you use in your paper. This will help to show where you got your information and will also help to add credibility to your work.
Be sure to proofread your paper before you submit it. This will ensure that there are no errors and that your paper is clear and concise.
Get help from a tutor or friend if you are struggling with your paper. They may be able to offer helpful advice or feedback.
Take your time when writing your research paper . This is not a race, and it is important to make sure that you do a good job on your research.

By following these tips, you can be sure that your chemistry research paper will be a success! So what are you waiting for? Let’s go over some of the best research paper topics out there.

Chemical Engineering Research Topics

Chemical Engineering is a branch of engineering that deals with the design and application of chemical processes. If you’re wondering how to choose a paper topic, here are some ideas to inspire you:

How to create new alloy compounds or improve existing ones
The health effects of the food industry chemicals
Chemical engineering and sustainable development
The future of chemical engineering
Chemical engineering and the food industry
Chemical engineering and the pharmaceutical industry
Chemical engineering and the cosmetics industry
Chemical engineering and the petrochemical industry

These are just a few examples – there are many more possibilities out there! So get started on your research today. Who knows what you might discover!

Organic Сhemistry Research Topics

Organic chemistry is the study of carbon-containing molecules. There are many different organic chemistry research topics that a student could choose to focus on and here are just a few examples of possible research projects in organic chemistry:

Investigating new methods for synthesizing chiral molecules
Studying the structure and reactivity of carbon nanotubes
Investigating metal complexes with organometallic ligands
Designing benzene derivatives with improved thermal stability
Exploring new ways to control the stereochemistry of chemical reactions
Studying the role of enzymes in organic synthesis
Investigating new strategies for combating drug resistance
Developing new methods for detecting explosives residues
Studying the photochemistry of organic molecules
Studying the behavior of organometallic compounds in biological systems

Іnorganic Сhemistry Research Topics

Inorganic Chemistry is the study of the chemistry of materials that do not contain carbon. Unlike other chemistry research topics, these include elements such as metals, minerals, and inorganic compounds. If you are looking for inorganic chemistry research topics on inorganic chemistry, here are some ideas to get you started:

How different metals react with one another
How to create new alloys or improve existing ones
The role of inorganic chemistry in the environment
Inorganic chemistry and sustainable development
The future of inorganic chemistry
Inorganic chemistry and the food industry
Inorganic chemistry and the pharmaceutical industry
Atomic structure progressive scale grading
Inorganiс Сhemistry and the cosmetics industry

Biomolecular Сhemistry Research Topics

Biomolecular chemistry is the study of molecules that are important for life. These molecules can be found in all living things, from tiny bacteria to the largest animals. Researchers who work in this field use a variety of techniques to learn more about how these molecules function and how they interact with each other.

If you are looking for essential biomolecular chemistry research topics, here are some ideas to get you started:

The structure and function of DNA
The structure and function of proteins
The role of carbohydrates in the body
The role of lipids in the body
How enzymes work
The role of biochemistry in heart disease
Cyanides and their effect on the body
The role of biochemistry in cancer treatment
The role of biochemistry in Parkison’s disease treatment
The role of biochemistry in the immune system

The possibilities are endless for someone willing to dedicate some time to research.

Analytical Chemistry Research Topics

Analytical Chemistry is a type of chemistry that helps scientists figure out what something is made of. This can be done through a variety of methods, such as spectroscopy or chromatography. If you are looking for research topics, here are some ideas to get you started:

How food chemicals react with one another
Mass spectrometry
Analytical aspects of gas and liquid chromatography
Analytical chemistry and sustainable development
Atomic absorption spectroscopy methods and best practices
Analytical chemistry and the pharmaceutical industry in Ibuprofen consumption
Analytical chemistry and the cosmetics industry in UV protectors
Dispersive x-ray analysis of damaged tissues

Analytical chemistry is considered by many a complex science and there is a lot yet to be discovered in the field.

Computational Chemistry Research Topics

Computational chemistry is a way to use computers to help chemists understand chemical reactions. This can be done by simulating reactions or by designing new molecules. If you are looking for essential chemistry research topics in computational chemistry, here are some ideas to get you started:

Molecular mechanics simulation
Reaction rates of complex chemical reactions
Designing new molecules: how can simulation help
The role of computers in the study of quantum mechanics
How to use computers to predict chemical reactions
Using computers to understand organic chemistry
The future of computational chemistry in organic reactions
The impacts of simulation on the development of new medications
Combustion reaction simulation impact on engine development
Quantum-chemistry simulation review

Computers are cutting-edge technology in chemical research and this relatively new field of study has a ton yet to be explored.

Physical Chemistry Research Topics

Physical chemistry is the study of how matter behaves. It looks at the physical and chemical properties of atoms and molecules and how they interact with each other. If you are looking for physical chemistry research topics, here are some ideas to get you started:

Standardization of pH scales
Structure of atom on a quantum scale
Bonding across atoms and molecules
The effect of temperature on chemical reactions
The role of light in in-body chemical reactions
Chemical kinetics
Surface tension and its effects on mixtures
The role of pressure in chemical reactions
Rates of diffusion in gases and liquids
The role of entropy in chemical reactions

Here are just a few samples, but there are plenty more options! Start your research right now!

Innovative Chemistry Research Topics

Innovative chemistry is all about coming up with new ideas and ways to do things. This can be anything from creating new materials to finding new ways to make existing products. If you are looking for ground-breaking chemistry research topics, here are some ideas to get you started:

Amino acids side chain effects in protein folding
Chemistry in the production of nanomaterials
The role of enzymes in chemical reactions
Photocatalysis in 3D printing
Avoiding pesticides in agriculture
Combining chemical and biological processes
Gene modification in medicinal chemistry
The role of quantum mechanics in chemical reactions
Astrochemical research on extraterrestrial molecules
Spectroscopy signatures of pressurized organic components

If you need a hand, there are several sites that also offer research papers for sale and can be a great asset as you work to create your own research papers.

Whatever route you decide to take, good luck! And remember – the sky’s the limit when it comes to research! So get started today and see where your studies may take you. Who knows, you might just make a breakthrough discovery!

Environmental Chemistry Research Topics

Environmental Chemistry is the study of how chemicals interact with the environment. This can include anything from the air we breathe to the water we drink. If you are looking for environmental chemistry research topics, here are some ideas to get you started:

Plastic effects on ocean life
Urban ecology
The role of carbon in climate change
Air pollution and its effects
Water pollution and its effects
Chemicals in food and their effect on the body
The effect of chemicals on plant life
Earth temperature prediction models

A lot of research on the environment is being conducted at the moment because the environment is in danger. There are a lot of environmental problems that need to be solved, and research is the key to solving them.

Green Chemistry Research Topics

Green chemistry is the study of how to make products and processes that are environmentally friendly. This can include anything from finding new ways to recycle materials to developing new products that are biodegradable. If you are looking for green chemistry research topics, here are some ideas to get you started:

Recycling and reuse of materials
Developing biodegradable materials
Improving existing recycling processes
Green chemistry and sustainable development
The future of green chemistry
Green chemistry and the food industry
Green chemistry and the pharmaceutical industry
Green chemistry and the cosmetics industry

A more environmentally friendly world is something we all aspire for and a lot of research has been conducted on how we can achieve this, making this one of the most promising areas of study. The results have been varied, but there are a few key things we can do to make a difference.

Controversial Chemistry Research Topics

Controversial chemistry is all about hot-button topics that people are passionate about. This can include anything from the use of chemicals in warfare to the health effects of different chemicals. If you are looking for controversial topics to write about , here are some ideas to get you started:

The use of chemicals in warfare
Gene modification in human babies
Bioengineering
How fast food chemicals affect the human brain
The role of the government in regulating chemicals
Evolution of cigarette chemicals over time
Chemical effects of CBD oils
Antidepressant chemical reactions
Synthetic molecules replication methods
Gene analysis

Controversial research papers often appear in the media before it has been peer-reviewed and published in a scientific journal. The reason for this is that the media is interested in stories that are new, exciting, and generate a lot of debate.

Chemistry is an incredibly diverse and interesting field, with many controversial topics to write about. If you are looking for a research topic, consider the examples listed in this article. With a little bit of effort, you are sure to find a topic that is both interesting and within your skillset.

In order to be a good researcher, it is important to be able to think critically and solve problems. However, innovation in chemistry research can be challenging. When thinking about how to innovate, it is important to consider both the practical and theoretical aspects of your research. Additionally, try to build on the work of others in order to create something new and unique. With a little bit of effort, you are sure to be able to find a topic that is both interesting and within your skillset.

Happy writing!

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ACS Publications

10 Hot Topics in Chemistry So Far in 2023

Apr 25, 2023

Here, we bring you a selection of hot topics published in ACS journals so far this year, spanning a wide range of subject areas from authors around the world. From algae to wearable devices, this collection features fascinating innovations for everyone to enjoy.

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Tobacco: Chemistry, Mechanisms, and Disease Prevention

50 years ago, scientists first identified N ′-nitrosonornicotine, the tobacco-specific carcinogen found in both cigarette smoke and smokeless tobacco products. The tobacco industry has evolved tremendously since then, but there is still much to be understood about the root causes of certain cancers associated with prolonged tobacco use. Additionally, the rise of e-cigarettes and other tobacco-free products presents a need for further investigations into the potential toxicity of and damage from various vaping mechanisms. This collection of papers from Chemical Research in Toxicology highlights key advances across a broad array of topics on tobacco products, e-cigarettes, disease prevention, and more.

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Special Issue: Tobacco - Chemistry, Mechanisms, Biomarkers and Disease Prevention

All about algae.

Chemists Celebrate Earth Week (CCEW) is a community-based program of ACS. This year, CCEW’s theme was “The Curious Chemistry of Amazing Algae.” These amazing organisms are emerging as a potential sustainable source of food and biofuels, as well as bioplastics and other co-products. Part of the attraction is that they exist in large numbers, and they have a variety of characteristics depending on where and how they grow. Critically, algae have evolved to produce and store energy—a skill which they perform more efficiently than any other known natural or engineered process. This Virtual Issue brings together articles from 20 different journals, covering a variety of topics such as algal uses in hydrogels, wastewater treatment, bioplastics, fuel production, and batteries—as well as ways to control harmful algal blooms in the wild.

Digital illustration of blue and green algae underwater

Chemists Celebrate Earth Week: The Curious Chemistry of Amazing Algae

Gaining insight into parkinson’s disease.

World Parkinson’s Day is held each year on April 11 to raise awareness of this progressive neurological disease, which affects approximately 1% of people aged 65 and older and 4–5% of those over the age of 85. But due to its complex etiology, the underlying pathogenesis of Parkinson’s is not fully understood. As such, there remains a desperate need for research into both causes and possible cures. A recent collection of articles highlights significant contributions reported in ACS journals. In addition to various pharmaceutical options being explored, research is also underway to improve the performance of sensors and develop new protocols for detecting neurotransmitters, which could help speed diagnosis and support monitoring.

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World Parkinson’s Day

A second skin: the world of wearables.

The idea of sensors for health detecting naturally takes us to wearables. Wearables go far beyond fitness trackers, with devices now including patches, tattoos, fabrics, and contact lenses. The embedded technology spans multiple disciplines, which together are redefining what can be done with wearable sensors. ACS Sensors brings together 29 publications that showcase the interdisciplinary nature of this exciting field, bringing together engineering, materials, spectroscopy, data science, physics, medicine, and more—which could pave the way for dramatic advances in both health diagnosis and monitoring.

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Lessons Learned: Post-Pandemic Teaching Strategies

In 2020, the Journal of Chemical Education published a Special Issue around educational insights gained during the COVID-19 pandemic. Now, in 2023, this new Virtual Special Issue on the same topic in the time after COVID offers more data-driven assessments of changes made in the chemistry education community as a result of the pandemic. Widespread lockdowns forced people to find novel solutions in many spheres of life, including redefining “the classroom.” Educators used a variety of platforms to share remote learning, and hybrid teaching environments evolved into the new normal. This collection looks at teaching innovations and student learning in the field of chemistry, showcasing how the pandemic has shaped new ways of working—from remote laboratory methods to student engagement and technical tools.

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Teaching Changes and Insights Gained in the Time after COVID-19

Hot articles in inorganic/organic chemistry.

Look, it’s a hot topics collection within a hot topics collection! This next list includes 58 Editors' Choice articles spanning ACS Publications’ core organic and inorganic journals. These editor-curated articles showcase innovative thinking in a variety of areas, including synthetic methodology, coordination, main-group chemistry, catalysis, energy research, medical science, and theoretical and computational chemistry. The ACS Editors' Choice designation is designed to highlight important new findings, which are free to read for a limited time.

Blue and purple word cloud with various organic and inorganic chemistry terms

Hot Articles from the ACS Organic/Inorganic Journal Portfolio: 2022 Editors' Choice

Research excellence from latin america.

Join us now as we take you on a brief world tour of cutting-edge work from three key geographic regions. First, let’s take a closer look at research from Latin America . Over the past 100 years, ACS has published more than 26,000 articles from Latin American scientists spanning almost all fields of chemistry—and discovery and innovation in Latin America continues to thrive today. This Virtual Issue from ACS Omega is fully open access and features 35 papers on key frontier topics.

Excellence in Agricultural Research from India

Next, we travel to India, where another Virtual Issue from ACS Agricultural Science & Technology and Journal of Agricultural and Food Chemistry highlights regional contributions to the boundaries of agricultural research. Topics covered include plant science and biotechnology, crop protection, sustainable agriculture, and precision farming—as well as less obvious disciplines such as nanomaterials, which could play a role in making agriculture more sustainable.

Highlighting Excellence in Agricultural Research from India

Emerging trends in molecular pharmaceutics across australasia.

The third and final stop on our world tour is Australasia , with a collection of exciting research on emerging trends in the pharmaceutical sciences. The papers, all published in Molecular Pharmaceutics , highlight the high-quality work led by researchers in both academia and industry across Australia and New Zealand. This includes a wide range of advanced drug delivery research areas, including nanotechnology, biomaterials, biodegradable polymers, and drug targeting. This collection presents novel innovations with the potential to translate into new treatment paradigms and options for people around the globe.

Mastering the Art of Scientific Publication (Part 2)

And finally, for anyone wanting to get their own work published (and perhaps find it included in a future Virtual Issue), we draw your attention to a collection of recent editorials that offer tips and best practices for composing a well-balanced scientific article, preparing an effective manuscript, and increasing your likelihood of getting your work accepted for publication. Just getting started? Be sure to check out Part 1 as well.

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Mastering the Art of Scientific Publication − Part II

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Inorganic Chemistry Frontiers

The international, high quality journal for interdisciplinary research between inorganic chemistry and related subjects

best research topics in inorganic chemistry

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Inorganic Chemistry Frontiers publishes research articles, reviews, notes, comments and methods covering all areas of inorganic chemistry.

Emphases are placed on interdisciplinary studies where inorganic chemistry and organometallic chemistry meet related areas, such as catalysis, biochemistry, nanoscience, energy and materials science.

For publication in Inorganic Chemistry Frontiers , papers should report high-quality work of exceptional novelty, which will be of significant interest to the wide readership of the journal.

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Editor-in-chief

Song Gao , Peking University and Sun Yat-sen University, China

Associate editors

Jun Chen , Nankai University, China

Paula Diaconescu , University of California, Los Angeles, USA

Svetlana Mintova , CNRS, France

Justin J. Wilson , Cornell University, USA

Teppei Yamada , University of Tokyo, Japan

Zhiping Zheng , Southern University of Science and Technology, China

Editorial board members

Hiroshi Kitagawa , Kyoto University, Japan

Yu Tang , Lanzhou University, China

Xianran Xing , University of Science and Technology Beijing, China

Nanfeng Zheng , Xiamen University, China

Christopher J Chang , University of California, Berkeley, USA

Chi-Ming Che , University of Hong Kong, China

Ling Chen, Beijing Normal University, China

Xiaoming Chen , Sun Yat-Sen University, China

Eugenio Coronado , University of Valencia, Spain

Yi Cui , Stanford University, USA

Patrick Gámez , University of Barcelona, Spain

Hairong Guan , University of Cincinnati, USA

Andy Hor , University of Hong Kong, China

Zhaomin Hou , RIKEN, Japan

Xile H u , École Polytechnique Fédérale de Lausanne, Switzerland

Mercouri Kanatzidis , Northwestern University, USA

Jaqueline L. Kiplinger , Los Alamos National Laboratory, USA

Yadong Li , Tsinghua University, China

Wenbin Lin , University of Chicago, USA

Yi Lu , University of Texas at Austin, USA

P S Mukherjee , Indian Institute of Science, India

Wonwoo Nam , Ewha Womans University, South Korea

Hiroshi Nishihara , University of Tokyo, Japan

Hiroki Oshio , University of Tsukuba, Japan

Oleg Ozerov , Texas A&M University, USA

Manfred Scheer , University of Regensburg, Germany

Baolian Su , University of Namur, Belgium

Jean Pascal Sutter , Laboratory of Coordination Chemistry, CNRS, France

Richard Winpenny , University of Manchester, UK

Yi Xie , University of Science and Technology of China, China

Zuowei Xie , The Chinese University of Hong Kong, China

Chunhua Yan , Peking University, China

Hong-Cai Joe Zhou , Texas A&M University, USA

Xiaodong Zou , Stockholm University, Sweden

Qichun Zhang , City University of Hong Kong, China

Wenjun Liu , Executive Editor

Kailin Deng , Deputy Editor

Yongxu Hu , Development Editor

Helen Saxton , Editorial Production Manager, ORCID 0000-0002-1560-7396

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Laura Smith , Publishing Editor, ORCID 0000-0002-2976-8529

Jie Gao , Assistant Editor

Yu Zhang , Assistant Editor

Article types

Inorganic Chemistry Frontiers publishes:

Research articles

Chemistry frontiers.

All original research work published in Inorganic Chemistry Frontiers will be in one 'Research article' format. Both Communications and Full papers can be published in the same format. Innovative syntheses of important inorganic/organometallic compounds with potential value to the multi-interdisciplinary research, assays, devices and concepts are also encouraged.

Lengthy introductions, excessive data or experimental details and pure conjecture should not be included in the main text. Authors are encouraged to include a brief experimental section containing key and representative experimental procedures in the main text. Additional repeated information and characterisation data should be included in the electronic supplementary information by citing the typical or general procedure in the main text.

Authors are encouraged to use the article templates from our Author templates & services page to prepare Research articles. However, the use of the template for submission is not essential.

A Review article should provide a critical and in-depth discussion of a particularly relevant or interesting topic in inorganic chemistry. It should aim to provide the reader with an authoritative, balanced and up-to-date overview, and not a comprehensive list of all possible references. Authors should also aim to identify areas in the field where further developments are needed. Reviews should not describe any unpublished results.

Chemistry frontiers publish comments, notes, or conjecture looking forward at the future of inorganic chemistry sciences. The articles should provide insight into the significance of hot emerging areas, as well as personal perspectives on these new developments. Chemistry frontiers could be speculative and controversial in nature. Some new unpublished results may be included but the amount should be minimized.

Chemistry frontiers are generally four journal pages in length. All contributions are subject to a rigorous and full peer review procedure.

Highlights feature the latest breakthroughs in inorganic chemistry and related fields. Authors should discuss on the importance of the recent advances, as well as the potential influence they may bring to the field. Highlights are short, easy-to-read articles within four journal pages.

Comments and Replies are a medium for the discussion and exchange of scientific opinions between authors and readers concerning material published in Inorganic Chemistry Frontiers .

For publication, a Comment should present an alternative analysis of and/or new insight into the previously published material. Any Reply should further the discussion presented in the original article and the Comment. Comments and Replies that contain any form of personal attack are not suitable for publication.

Comments that are acceptable for publication will be forwarded to the authors of the work being discussed, and these authors will be given the opportunity to submit a Reply. The Comment and Reply will both be subject to rigorous peer review in consultation with the journal’s Editorial Board where appropriate. The Comment and Reply will be published together.

Journal specific guidelines

Experimental information must be provided to enable other researchers to reproduce the work accurately. Figures should include error bars where appropriate and results should be accompanied by analyses of experimental uncertainty.

The experimental details and the characterisation data should be provided preferably as electronic supplementary information (ESI) although on occasion it may be appropriate to include some or all of this within the body of the article. This will depend on the nature of the research being reported.

Characterisation of new compounds

It is the responsibility of authors to provide fully convincing evidence for the homogeneity, purity and identity of all compounds they claim as new. This evidence is required to establish that the properties and constants reported are those of the compound with the new structure claimed. Referees will assess, as a whole, the evidence presented in support of the claims made by the authors. The requirements for characterisation criteria are detailed below.

Inorganic and organometallic compounds

A new chemical substance (molecule or extended solid) should have a homogeneous composition and structure. New chemical syntheses must unequivocally establish the purity and identity of these materials. Where the compound is molecular, minimum standards have been established.

For manuscripts that report new compounds or materials, data must be provided to establish unequivocally the homogeneity, purity and identification of these substances. In general, this should include elemental analyses that agree to within ±0.4% of the calculated values. In cases where elemental analyses cannot be obtained (for example, for thermally unstable compounds), justification for the omission of this data should be provided.

Note that an X-ray crystal structure is not sufficient for the characterisation of a new material, since the crystal used in this analysis does not necessarily represent the bulk sample. In rare cases, it may be possible to substitute elemental analyses with high-resolution mass spectrometric molecular weights. This is appropriate, for example, with trivial derivatives of thoroughly characterised substances or routine synthetic intermediates.

In all cases, relevant spectroscopic data (NMR, IR, UV-vis, etc) should be provided in tabulated form and as reproduced spectra; reproduced spectra should be included in the electronic supplementary information (ESI).

Mass spectrometric and spectroscopic data do not constitute proof of purity, and in the absence of elemental analyses additional evidence of purity should be provided (melting points, PXRD data, etc).

Experimental data for new substances should also include synthetic yields, reported in terms of grams or moles, and as a percentage. Where the compound is an extended solid, it is important to establish unequivocally the chemical structure and bulk composition.

Single crystal diffraction does not determine the bulk structure. Referees will normally look to see evidence of bulk homogeneity.

A fully indexed powder diffraction pattern, which agrees with single crystal data, may be used as evidence of a bulk homogeneous structure and chemical analysis may be used to establish purity and homogeneous composition.

It should be unambiguous whether yields pertain to a crude product (specify purity if possible) or a purified product. They must also include all the characterisation data for the prepared compound or material. For a series of related compounds, at least one representative procedure that outlines a specific example that is described in the text or in a table and which is representative for the other cases, must be provided.

If a known compound is prepared by a new or modified synthetic procedure, the types of physical and spectroscopic data that were found to match cited literature data should be identified, and purity documentation should be provided as indicated in the previous paragraph for new compounds.

For all compounds, even when the isolation of a pure compound is not being claimed, the degree of purity must still be estimated and, at least for diamagnetic compounds, NMR spectroscopic data included in the electronic supplementary information as described above.

Peaks appearing in the provided spectra that do not belong to a compound of interest should be designated and assigned as much as possible.

Nano-sized materials (such as quantum dots, nanoparticles, nanotubes, nanowires)

For nano-sized materials it is essential that the authors not only provide detailed characterisation on individual objects (see above) but also a comprehensive characterisation of the bulk composition.

Characterisation of the bulk of the sample require determination of the chemical composition and size distribution over large portions of the sample.

The syntheses of all new compounds must be described in detail.

Synthetic procedures must include the specific reagents, products and solvents and must give the amounts (g, mmol, for products: %) for all of them, as well as clearly stating how the percentage yields are calculated. It should be unambiguous whether yields pertain to a crude product (specify purity if possible) or a purified product. They must also include all the characterisation data for the prepared compound or material.

For a series of related compounds, at least one representative procedure, which outlines a specific example that is described in the text or in a table and which is representative for the other cases, must be provided.

Organic compounds

Authors are required to provide unequivocal support for the purity and assigned structure of all compounds using a combination of the following characterisation techniques: analytical, physical, spectroscopic.

Analytical Elemental analysis (within ±0.4% of the calculated value) is required to confirm 95% sample purity and corroborate isomeric purity. Authors are required to provide copies of 1 H, 13 C NMR spectra and/or GC/HPLC traces in the electronic supplementary information (ESI) especially if satisfactory elemental analysis results cannot be obtained. For libraries of compounds, HPLC traces should be submitted as proof of purity.

The determination of enantiomeric excess of nonracemic, chiral substances should be supported with either SFC/GC/HPLC traces with retention times for both enantiomers and separation conditions (that is, chiral support, solvent and flow rate) or for Mosher Ester/Chiral Shift Reagent analysis, copies of the spectra.

Physical Important physical properties - for example, boiling or melting point, specific rotation, refractive index, etc - including conditions and a comparison to the literature for known compounds should be provided. For crystalline compounds, the method used for recrystallisation should also be documented (that is, solvent, etc).

Spectroscopic Mass spectra and a complete numerical listing of 1 H, 13 C NMR peaks in support of the assigned structure, including relevant 2D NMR spectra and related experiments (that is, NOE, etc) is required. Authors are required to provide copies of these spectra. Infrared spectra that support functional group modifications, including other diagnostic assignments should be included.

High-resolution mass spectra are acceptable as proof of the molecular weight provided the purity of the sample has been accurately determined as outlined above.

The syntheses of all new compounds must be described in detail. Synthetic procedures must include the specific reagents, products and solvents and must give the amounts (g, mmol, for products: %) for all of them, as well as clearly stating how the percentage yields are calculated. It should be unambiguous whether yields pertain to a crude product (specify purity if possible) or a purified product. They must include the 1 H, 13 C NMR spectra and MS data of this specific compound.

For multistep synthesis papers: spectra of key compounds and of the final product should be included. For a series of related compounds, at least one representative procedure, which outlines a specific example that is described in the text or in a table and which is representative for the other cases, must be provided.

For all soluble polymers an estimation of molecular weight must be provided by a suitable method - for example, size exclusion chromatography, including details of columns, eluents and calibration standards, intrinsic viscosity, MALDI TOF, etc in addition to full NMR characterisation ( 1 H, 13 C) as for organic compound characterisation (see above).

The synthesis of all new compounds must be described in detail. Synthetic procedures must include the specific reagents, products and solvents and must give the amounts (g, mmol, for products: %) for all of them, as well as clearly stating how the percentage yields are calculated. It should be unambiguous whether yields pertain to a crude product (specify purity if possible) or a purified product. They must also include all the characterisation data for the prepared compound or material.

Biomolecules (for example, enzymes, proteins, DNA/RNA, oligosaccharides, oligonucleotides)

Authors should provide rigorous evidence for the identity and purity of the biomolecules described.

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Home » 300+ Chemistry Research Topics

300+ Chemistry Research Topics

Table of Contents

Chemistry is a fascinating and complex field that explores the composition, properties, and behavior of matter at the molecular and atomic level. As a result, there are numerous chemistry research topics that can be explored, ranging from the development of new materials and drugs to the study of natural compounds and the environment. In this rapidly evolving field, researchers are constantly uncovering new insights and pushing the boundaries of our understanding of chemistry. Whether you are a student, a professional researcher, or simply curious about the world around you, there is always something new to discover in the field of chemistry. In this post, we will explore some of the exciting and important research topics in chemistry today.

Chemistry Research Topics

Chemistry Research Topics are as follows:

Organic Chemistry Research Topics

Organic Chemistry Research Topics are as follows:

Development of novel synthetic routes for the production of biologically active natural products
Investigation of reaction mechanisms and kinetics for organic transformations
Design and synthesis of new catalysts for asymmetric organic reactions
Synthesis and characterization of chiral compounds for pharmaceutical applications
Development of sustainable methods for the synthesis of organic molecules using renewable resources
Discovery of new reaction pathways for the conversion of biomass into high-value chemicals
Study of molecular recognition and host-guest interactions for drug design
Design and synthesis of new materials for energy storage and conversion
Development of efficient and selective methods for C-H functionalization reactions
Exploration of the reactivity of reactive intermediates such as radicals and carbenes
Study of supramolecular chemistry and self-assembly of organic molecules
Development of new methods for the synthesis of heterocyclic compounds
Investigation of the biological activities and mechanisms of action of natural products
Synthesis of polymeric materials with controlled architecture and functionality
Development of new synthetic methodologies for the preparation of bioconjugates
Investigation of the mechanisms of enzyme catalysis and the design of enzyme inhibitors
Synthesis and characterization of novel fluorescent probes for biological imaging
Development of new synthetic strategies for the preparation of carbohydrates and glycoconjugates
Study of the properties and reactivity of carbon nanomaterials
Design and synthesis of novel drugs for the treatment of diseases such as cancer, diabetes, and Alzheimer’s disease.

Inorganic Chemistry Research Topics

Inorganic Chemistry Research Topics are as follows:

Synthesis and characterization of new metal-organic frameworks (MOFs) for gas storage and separation applications
Development of new catalysts for sustainable chemical synthesis reactions
Investigation of the electronic and magnetic properties of transition metal complexes for spintronics applications
Synthesis and characterization of novel nanomaterials for energy storage applications
Development of new ligands for metal coordination complexes with potential medical applications
Investigation of the mechanism of metal-catalyzed reactions using advanced spectroscopic techniques
Synthesis and characterization of new inorganic materials for photocatalytic water splitting
Development of new materials for electrochemical carbon dioxide reduction reactions
Investigation of the properties of transition metal oxides for energy storage and conversion applications
Synthesis and characterization of new metal chalcogenides for optoelectronic applications
Development of new methods for the preparation of inorganic nanoparticles with controlled size and shape
Investigation of the reactivity and catalytic properties of metal clusters
Synthesis and characterization of new metal-organic polyhedra (MOPs) for gas storage and separation applications
Development of new methods for the synthesis of metal nanoparticles using environmentally friendly reducing agents
Investigation of the properties of metal-organic frameworks for gas sensing applications
Synthesis and characterization of new coordination polymers with potential magnetic and electronic properties
Development of new materials for electrocatalytic water oxidation reactions
Investigation of the properties of metal-organic frameworks for carbon capture and storage applications
Synthesis and characterization of new metal-containing polymers with potential applications in electronics and energy storage
Development of new methods for the synthesis of metal-organic frameworks using green solvents and renewable resources.

Physical Chemistry Research Topics

Physical Chemistry Research Topics are as follows:

Investigation of the properties and interactions of ionic liquids in aqueous and non-aqueous solutions.
Development of advanced analytical techniques for the study of protein structure and dynamics.
Investigation of the thermodynamic properties of supercritical fluids for use in industrial applications.
Development of novel nanomaterials for energy storage applications.
Studies of the surface chemistry of catalysts for the optimization of their performance in chemical reactions.
Development of new methods for the synthesis of complex organic molecules with improved yields and selectivity.
Investigation of the molecular mechanisms involved in the catalysis of biochemical reactions.
Development of new strategies for the controlled release of drugs and other bioactive molecules.
Studies of the interaction of nanoparticles with biological systems for biomedical applications.
Investigation of the thermodynamic properties of materials under extreme conditions of temperature and pressure.
Development of new methods for the characterization of materials at the nanoscale.
Investigation of the electronic and magnetic properties of materials for use in spintronics.
Development of new materials for energy conversion and storage.
Studies of the kinetics and thermodynamics of adsorption processes on surfaces.
Investigation of the transport properties of ionic liquids for use in energy storage and conversion devices.
Development of new materials for the capture and sequestration of greenhouse gases.
Studies of the structure and properties of biomolecules for use in drug design and development.
Investigation of the dynamics of chemical reactions in solution using time-resolved spectroscopic techniques.
Development of new approaches for the synthesis of metallic and semiconductor nanoparticles with controlled size and shape.
Studies of the structure and properties of materials for use in electrochemical energy storage devices.

Analytical Chemistry Research Topics

Analytical Chemistry Research Topics are as follows:

Development and optimization of analytical techniques for the quantification of trace elements in food and environmental samples.
Design and synthesis of novel analytical probes for the detection of biomolecules in complex matrices.
Investigation of the fundamental mechanisms involved in the separation and detection of complex mixtures using chromatographic techniques.
Development of sensors and biosensors for the detection of chemical and biological species in real-time.
Investigation of the chemical and structural properties of nanomaterials and their applications in analytical chemistry.
Development and validation of analytical methods for the quantification of contaminants and pollutants in water, air, and soil.
Investigation of the molecular mechanisms underlying drug metabolism and toxicity using mass spectrometry.
Development of analytical tools for the identification and quantification of drugs of abuse in biological matrices.
Investigation of the chemical composition and properties of natural products and their applications in medicine and food science.
Development of advanced analytical techniques for the characterization of proteins and peptides.
Investigation of the chemistry and mechanism of action of antioxidants in foods and their impact on human health.
Development of analytical methods for the detection and quantification of microorganisms in food and environmental samples.
Investigation of the molecular mechanisms involved in the biosynthesis and degradation of important biomolecules such as proteins, carbohydrates, and lipids.
Development of analytical methods for the detection and quantification of environmental toxins and their impact on human health.
Investigation of the structure and properties of biological membranes and their role in drug delivery and disease.
Development of analytical techniques for the characterization of complex mixtures such as petroleum and crude oil.
Investigation of the chemistry and mechanism of action of natural and synthetic dyes.
Development of analytical techniques for the detection and quantification of pharmaceuticals and personal care products in water and wastewater.
Investigation of the chemical composition and properties of biopolymers and their applications in biomedicine and biomaterials.
Development of analytical methods for the identification and quantification of essential nutrients and vitamins in food and dietary supplements.

Biochemistry Research Topics

Biochemistry Research Topics are as follows:

The role of enzymes in metabolic pathways
The biochemistry of DNA replication and repair
Protein folding and misfolding diseases
Lipid metabolism and the pathogenesis of atherosclerosis
The role of vitamins and minerals in human metabolism
Biochemistry of cancer and the development of targeted therapies
The biochemistry of signal transduction pathways and their regulation
The mechanisms of antibiotic resistance in bacteria
The biochemistry of neurotransmitters and their roles in behavior and disease
The role of oxidative stress in aging and age-related diseases
The biochemistry of microbial fermentation and its applications in industry
The biochemistry of the immune system and its response to pathogens
The biochemistry of plant metabolism and its regulation
The molecular basis of genetic diseases and gene therapy
The biochemistry of membrane transport and its role in cell function
The biochemistry of muscle contraction and its regulation
The role of lipids in membrane structure and function
The biochemistry of photosynthesis and its regulation
The biochemistry of RNA splicing and alternative splicing events
The biochemistry of epigenetics and its regulation in gene expression.

Environmental Chemistry Research Topics

Environmental Chemistry Research Topics are as follows:

Investigating the effects of microplastics on aquatic ecosystems and their potential impact on human health.
Examining the impact of climate change on soil quality and nutrient availability in agricultural systems.
Developing methods to improve the removal of heavy metals from contaminated soils and waterways.
Assessing the effectiveness of natural and synthetic antioxidants in mitigating the effects of air pollution on human health.
Investigating the potential for using algae and other microorganisms to sequester carbon dioxide from the atmosphere.
Studying the role of biodegradable plastics in reducing plastic waste and their impact on the environment.
Examining the impact of pesticides and other agricultural chemicals on water quality and the health of aquatic organisms.
Investigating the effects of ocean acidification on marine organisms and ecosystems.
Developing new materials and technologies to reduce carbon emissions from industrial processes.
Evaluating the effectiveness of phytoremediation in cleaning up contaminated soils and waterways.
Studying the impact of microplastics on terrestrial ecosystems and their potential to enter the food chain.
Developing sustainable methods for managing and recycling electronic waste.
Investigating the role of natural processes, such as weathering and erosion, in regulating atmospheric carbon dioxide levels.
Assessing the impact of urbanization on air quality and developing strategies to mitigate pollution in cities.
Examining the effects of climate change on the distribution and abundance of species in different ecosystems.
Investigating the impact of ocean currents on the distribution of pollutants and other environmental contaminants.
Developing new materials and technologies for renewable energy generation and storage.
Studying the effects of deforestation on soil quality, water availability, and biodiversity.
Assessing the potential for using waste materials, such as agricultural residues and municipal solid waste, as sources of renewable energy.
Investigating the role of natural and synthetic chemicals in regulating ecosystem functions, such as nutrient cycling and carbon sequestration.

Polymer Chemistry Research Topics

Polymer Chemistry Research Topics are as follows:

Development of new monomers for high-performance polymers
Synthesis and characterization of biodegradable polymers for sustainable packaging
Design of stimuli-responsive polymers for drug delivery applications
Investigation of the properties and applications of conductive polymers
Development of new catalysts for controlled/living polymerization
Synthesis of polymers with tailored mechanical properties
Characterization of the structure-property relationship in polymer nanocomposites
Study of the impact of polymer architecture on material properties
Design and synthesis of new polymeric materials for energy storage
Development of high-throughput methods for polymer synthesis and characterization
Exploration of new strategies for polymer recycling and upcycling
Synthesis and characterization of responsive polymer networks for smart textiles
Design of advanced polymer coatings with self-healing properties
Investigation of the impact of processing conditions on the morphology and properties of polymer materials
Study of the interactions between polymers and biological systems
Development of biocompatible polymers for tissue engineering applications
Synthesis and characterization of block copolymers for advanced membrane applications
Exploration of the potential of polymer-based sensors and actuators
Design of novel polymer electrolytes for advanced batteries and fuel cells
Study of the behavior of polymers under extreme conditions, such as high pressure or temperature.

Materials Chemistry Research Topics

Materials Chemistry Research Topics are as follows:

Development of new advanced materials for energy storage and conversion
Synthesis and characterization of nanomaterials for environmental remediation
Design and fabrication of stimuli-responsive materials for drug delivery
Investigation of electrocatalytic materials for fuel cells and electrolysis
Fabrication of flexible and stretchable electronic materials for wearable devices
Development of novel materials for high-performance electronic devices
Exploration of organic-inorganic hybrid materials for optoelectronic applications
Study of corrosion-resistant coatings for metallic materials
Investigation of biomaterials for tissue engineering and regenerative medicine
Synthesis and characterization of metal-organic frameworks for gas storage and separation
Design and fabrication of new materials for water purification
Investigation of carbon-based materials for supercapacitors and batteries
Synthesis and characterization of self-healing materials for structural applications
Development of new materials for catalysis and chemical reactions
Exploration of magnetic materials for spintronic devices
Investigation of thermoelectric materials for energy conversion
Study of 2D materials for electronic and optoelectronic applications
Development of sustainable and eco-friendly materials for packaging
Fabrication of advanced materials for sensors and actuators
Investigation of materials for high-temperature applications such as aerospace and nuclear industries.

Nuclear Chemistry Research Topics

Nuclear Chemistry Research Topics are as follows:

Nuclear fission and fusion reactions
Nuclear power plant safety and radiation protection
Radioactive waste management and disposal
Nuclear fuel cycle and waste reprocessing
Nuclear energy and its impact on climate change
Radiation therapy for cancer treatment
Radiopharmaceuticals for medical imaging
Nuclear medicine and its role in diagnostics
Nuclear forensics and nuclear security
Isotopic analysis in environmental monitoring and pollution control
Nuclear magnetic resonance (NMR) spectroscopy
Nuclear magnetic resonance imaging (MRI)
Radiation damage in materials and radiation effects on electronic devices
Nuclear data evaluation and validation
Nuclear reactors design and optimization
Nuclear fuel performance and irradiation behavior
Nuclear energy systems integration and optimization
Neutron and gamma-ray detection and measurement techniques
Nuclear astrophysics and cosmology
Nuclear weapons proliferation and disarmament.

Medicinal Chemistry Research Topics

Medicinal Chemistry Research Topics are as follows:

Drug discovery and development
Design and synthesis of novel drugs
Medicinal chemistry of natural products
Structure-activity relationships (SAR) of drugs
Rational drug design using computational methods
Target identification and validation
Drug metabolism and pharmacokinetics (DMPK)
Drug delivery systems
Development of new antibiotics
Design of drugs for the treatment of cancer
Development of drugs for the treatment of neurological disorders
Medicinal chemistry of peptides and proteins
Development of drugs for the treatment of infectious diseases
Discovery of new antiviral agents
Design of drugs for the treatment of cardiovascular diseases
Medicinal chemistry of enzyme inhibitors
Development of drugs for the treatment of inflammatory diseases
Design of drugs for the treatment of metabolic disorders
Medicinal chemistry of anti-cancer agents
Development of drugs for the treatment of rare diseases.

Food Chemistry Research Topics

Food Chemistry Research Topics are as follows:

Investigating the effect of cooking methods on the nutritional value of food.
Analyzing the role of antioxidants in preventing food spoilage and degradation.
Examining the effect of food processing techniques on the nutritional value of fruits and vegetables.
Studying the chemistry of food additives and their impact on human health.
Evaluating the role of enzymes in food digestion and processing.
Investigating the chemical properties and functional uses of food proteins.
Analyzing the effect of food packaging materials on the quality and safety of food products.
Examining the chemistry of food flavorings and the impact of flavor on consumer acceptance.
Studying the role of carbohydrates in food texture and structure.
Investigating the chemistry of food lipids and their impact on human health.
Analyzing the chemical properties and functional uses of food gums and emulsifiers.
Examining the effect of processing on the flavor and aroma of food products.
Studying the chemistry of food preservatives and their impact on food safety.
Investigating the chemical properties and functional uses of food fibers.
Analyzing the effect of food processing on the bioavailability of nutrients.
Examining the chemistry of food colorants and their impact on consumer acceptance.
Studying the role of vitamins and minerals in food and their impact on human health.
Investigating the chemical properties and functional uses of food hydrocolloids.
Analyzing the effect of food processing on the allergenicity of food products.
Examining the chemistry of food sweeteners and their impact on human health.

Industrial Chemistry Research Topics

Industrial Chemistry Research Topics are as follows:

Development of catalysts for selective hydrogenation reactions in the petrochemical industry.
Green chemistry approaches for the synthesis of biodegradable polymers from renewable sources.
Optimization of solvent extraction processes for the separation of rare earth elements from ores.
Development of novel materials for energy storage applications, such as lithium-ion batteries.
Production of biofuels from non-food sources, such as algae or waste biomass.
Application of computational chemistry to optimize the design of new catalysts and materials.
Design and optimization of continuous flow processes for large-scale chemical production.
Development of new synthetic routes for the production of pharmaceutical intermediates.
Investigation of the environmental impact of industrial processes and development of sustainable alternatives.
Development of innovative water treatment technologies for industrial wastewater.
Synthesis of functionalized nanoparticles for use in drug delivery and other biomedical applications.
Optimization of processes for the production of high-performance polymers, such as polyamides or polyesters.
Design and optimization of process control strategies for efficient and safe chemical production.
Development of new methods for the detection and removal of heavy metal ions from industrial effluents.
Investigation of the behavior of surfactants in complex mixtures, such as crude oil or food products.
Development of new materials for catalytic oxidation reactions, such as the removal of volatile organic compounds from air.
Investigation of the properties and behavior of materials under extreme conditions, such as high pressure or high temperature.
Development of new processes for the production of chemicals from renewable resources, such as bio-based building blocks.
Study of the kinetics and mechanism of chemical reactions in complex systems, such as multi-phase reactors.
Optimization of the production of fine chemicals, such as flavors and fragrances, using biocatalytic processes.

Computational Chemistry Research Topics

Computational Chemistry Research Topics are as follows:

Development and application of machine learning algorithms for predicting chemical reactions and properties.
Investigation of the role of solvents in chemical reactions using molecular dynamics simulations.
Modeling and simulation of protein-ligand interactions to aid drug design.
Study of the electronic structure and reactivity of catalysts for sustainable energy production.
Analysis of the thermodynamics and kinetics of complex chemical reactions using quantum chemistry methods.
Exploration of the mechanism and kinetics of enzyme-catalyzed reactions using molecular dynamics simulations.
Investigation of the properties and behavior of nanoparticles using computational modeling.
Development of computational tools for the prediction of chemical toxicity and environmental impact.
Study of the electronic properties of graphene and other 2D materials for applications in electronics and energy storage.
Investigation of the mechanisms of protein folding and aggregation using molecular dynamics simulations.
Development and optimization of computational methods for calculating thermodynamic properties of liquids and solids.
Study of the properties of supercritical fluids for applications in separation and extraction processes.
Development of new methods for the calculation of electron transfer rates in complex systems.
Investigation of the electronic and mechanical properties of carbon nanotubes for applications in nanoelectronics and nanocomposites.
Development of new approaches for modeling the interaction of biomolecules with biological membranes.
Study of the mechanisms of charge transfer in molecular and hybrid solar cells.
Analysis of the structural and mechanical properties of materials under extreme conditions using molecular dynamics simulations.
Development of new approaches for the calculation of free energy differences in complex systems.
Investigation of the reaction mechanisms of metalloenzymes using quantum mechanics/molecular mechanics (QM/MM) methods.
Study of the properties of ionic liquids for applications in catalysis and energy storage.

Theoretical Chemistry Research Topics

Theoretical Chemistry Research Topics are as follows:

Quantum Chemical Studies of Excited State Processes in Organic Molecules
Theoretical Investigation of Structure and Reactivity of Metal-Organic Frameworks
Computational Modeling of Reaction Mechanisms and Kinetics in Enzyme Catalysis
Theoretical Investigation of Non-Covalent Interactions in Supramolecular Chemistry
Quantum Chemical Studies of Photochemical Processes in Organic Molecules
Theoretical Analysis of Charge Transport in Organic and Inorganic Materials
Computational Modeling of Protein Folding and Dynamics
Quantum Chemical Investigations of Electron Transfer Processes in Complex Systems
Theoretical Studies of Surface Chemistry and Catalysis
Computational Design of Novel Materials for Energy Storage Applications
Theoretical Analysis of Chemical Bonding and Molecular Orbital Theory
Quantum Chemical Investigations of Magnetic Properties of Complex Systems
Computational Modeling of Biological Membranes and Transport Processes
Theoretical Studies of Nonlinear Optical Properties of Molecules and Materials
Quantum Chemical Studies of Spectroscopic Properties of Molecules
Theoretical Investigations of Reaction Mechanisms in Organometallic Chemistry
Computational Modeling of Heterogeneous Catalysis
Quantum Chemical Studies of Excited State Dynamics in Photosynthesis
Theoretical Analysis of Chemical Reaction Networks
Computational Design of Nanomaterials for Biomedical Applications

Astrochemistry Research Topics

Astrochemistry Research Topics are as follows:

Investigating the chemical composition of protoplanetary disks and its implications for planet formation
Examining the role of magnetic fields in the formation of complex organic molecules in space
Studying the effects of interstellar radiation on the chemical evolution of molecular clouds
Exploring the chemistry of comets and asteroids to better understand the early solar system
Investigating the origin and evolution of interstellar dust and its relationship to organic molecules
Examining the formation and destruction of interstellar molecules in shocked gas
Studying the chemical processes that occur in the atmospheres of planets and moons in our solar system
Exploring the possibility of life on other planets through astrobiology and astrochemistry
Investigating the chemistry of planetary nebulae and their role in the evolution of stars
Studying the chemical properties of exoplanets and their potential habitability
Examining the chemical reactions that occur in the interstellar medium
Investigating the chemical composition of supernova remnants and their impact on the evolution of galaxies
Studying the chemical composition of interstellar grains and their role in the formation of stars and planets
Exploring the chemistry of astrocytes and their role in the evolution of galaxies
Investigating the formation of interstellar ice and its implications for the origin of life
Examining the chemistry of molecular clouds and its relationship to star formation
Studying the chemical composition of the interstellar medium in different galaxies and how it varies
Investigating the role of cosmic rays in the formation of complex organic molecules in space
Exploring the chemical properties of interstellar filaments and their relationship to star formation
Studying the chemistry of protostars and the role of turbulence in the formation of stars.

Geochemistry Research Topics

Geochemistry Research Topics are as follows:

Understanding the role of mineralogical and geochemical factors on metal mobility in contaminated soils
Investigating the sources and fate of dissolved organic matter in aquatic systems
Exploring the geochemical signatures of ancient sedimentary rocks to reconstruct Earth’s past atmospheric conditions
Studying the impacts of land-use change on soil organic matter content and quality
Investigating the impact of acid mine drainage on water quality and ecosystem health
Examining the processes controlling the behavior and fate of emerging contaminants in the environment
Characterizing the organic matter composition of shale gas formations to better understand hydrocarbon storage and migration
Evaluating the potential for carbon capture and storage in geologic formations
Investigating the geochemical processes controlling the formation and evolution of ore deposits
Studying the geochemistry of geothermal systems to better understand energy production potential and environmental impacts
Exploring the impacts of climate change on the biogeochemistry of terrestrial ecosystems
Investigating the geochemical cycling of nutrients in coastal marine environments
Characterizing the isotopic composition of minerals and fluids to understand Earth’s evolution
Developing new analytical techniques to better understand the chemistry of natural waters
Studying the impact of anthropogenic activities on the geochemistry of urban soils
Investigating the role of microbial processes in geochemical cycling of elements in soils and sediments
Examining the impact of wildfires on soil and water chemistry
Characterizing the geochemistry of mineral dust and its impact on climate and biogeochemical cycles
Investigating the geochemical factors controlling the release and transport of contaminants from mine tailings
Exploring the biogeochemistry of wetlands and their role in carbon sequestration and nutrient cycling.

Electrochemistry Research Topics

Electrochemistry Research Topics are as follows:

Development of high-performance electrocatalysts for efficient electrochemical conversion of CO2 to fuels and chemicals
Investigation of electrode-electrolyte interfaces in lithium-ion batteries for enhanced battery performance and durability
Design and synthesis of novel electrolytes for high-energy-density and stable lithium-sulfur batteries
Development of advanced electrochemical sensors for the detection of trace-levels of analytes in biological and environmental samples
Analysis of the electrochemical behavior of new materials and their electrocatalytic properties in fuel cells
Study of the kinetics of electrochemical reactions and their effect on the efficiency and selectivity of electrochemical processes
Development of novel strategies for the electrochemical synthesis of value-added chemicals from biomass and waste materials
Analysis of the electrochemical properties of metal-organic frameworks (MOFs) for energy storage and conversion applications
Investigation of the electrochemical degradation mechanisms of polymer electrolyte membranes in fuel cells
Study of the electrochemical properties of 2D materials and their applications in energy storage and conversion devices
Development of efficient electrochemical systems for desalination and water treatment applications
Investigation of the electrochemical properties of metal-oxide nanoparticles for energy storage and conversion applications
Analysis of the electrochemical behavior of redox-active organic molecules and their application in energy storage and conversion devices
Study of the electrochemical behavior of metal-organic frameworks (MOFs) for the catalytic conversion of CO2 to value-added chemicals
Development of novel electrode materials for electrochemical capacitors with high energy density and fast charge/discharge rates
Investigation of the electrochemical properties of perovskite materials for energy storage and conversion applications
Study of the electrochemical behavior of enzymes and their application in bioelectrochemical systems
Development of advanced electrochemical techniques for the characterization of interfacial processes in electrochemical systems
Analysis of the electrochemical behavior of nanocarbons and their application in electrochemical energy storage devices
Investigation of the electrochemical properties of ionic liquids for energy storage and conversion applications.

Surface Chemistry Research Topics

Surface Chemistry Research Topics are as follows:

Surface modification of nanoparticles for enhanced catalytic activity
Investigating the effect of surface roughness on the wetting behavior of materials
Development of new materials for solar cell applications through surface chemistry techniques
Surface chemistry of graphene and its applications in electronic devices
Surface functionalization of biomaterials for biomedical applications
Characterization of surface defects and their effect on material properties
Surface modification of carbon nanotubes for energy storage applications
Developing surface coatings for corrosion protection of metals
Synthesis of self-assembled monolayers on surfaces for sensor applications
Surface chemistry of metal-organic frameworks for gas storage and separation
Investigating the role of surface charge in protein adsorption
Developing surfaces with superhydrophobic or superoleophobic properties for self-cleaning applications
Surface functionalization of nanoparticles for drug delivery applications
Surface chemistry of semiconductors and its effect on photovoltaic properties
Development of surface-enhanced Raman scattering (SERS) substrates for trace analyte detection
Surface functionalization of graphene oxide for water purification applications
Investigating the role of surface tension in emulsion formation and stabilization
Surface modification of membranes for water desalination and purification
Synthesis and characterization of metal nanoparticles for catalytic applications
Development of surfaces with controlled wettability for microfluidic applications.

Atmospheric Chemistry Research Topics

Atmospheric Chemistry Research Topics are as follows:

The impact of wildfires on atmospheric chemistry
The role of aerosols in atmospheric chemistry
The chemistry and physics of ozone depletion in the stratosphere
The chemistry and dynamics of the upper atmosphere
The impact of anthropogenic emissions on atmospheric chemistry
The role of clouds in atmospheric chemistry
The chemistry of atmospheric particulate matter
The impact of nitrogen oxides on atmospheric chemistry and air quality
The effects of climate change on atmospheric chemistry
The impact of atmospheric chemistry on climate change
The chemistry and physics of atmospheric mercury cycling
The impact of volcanic eruptions on atmospheric chemistry
The chemistry and physics of acid rain formation and effects
The role of halogen chemistry in the atmosphere
The chemistry of atmospheric radicals and their impact on air quality and health
The impact of urbanization on atmospheric chemistry
The chemistry and physics of stratospheric polar vortex dynamics
The role of natural sources (e.g. ocean, plants) in atmospheric chemistry
The impact of atmospheric chemistry on the biosphere
The chemistry and dynamics of the ozone hole over Antarctica.

Photochemistry Research Topics

Photochemistry Research Topics are as follows:

Investigating the mechanisms of photoinduced electron transfer reactions in organic photovoltaic materials.
Developing novel photoredox catalysts for photochemical reactions.
Understanding the effects of light on DNA and RNA stability and replication.
Studying the photochemistry of atmospheric pollutants and their impact on air quality.
Designing new photoresponsive materials for advanced photonic and electronic devices.
Exploring the photochemistry of metalloporphyrins for potential applications in catalysis.
Investigating the photochemistry of transition metal complexes and their use as photodynamic therapy agents.
Developing new photocatalytic systems for sustainable energy production.
Studying the photochemistry of natural products and their potential pharmaceutical applications.
Investigating the role of light in the formation and degradation of environmental contaminants.
Designing new photochromic materials for smart windows and displays.
Exploring the photochemistry of carbon nanomaterials for energy storage and conversion.
Developing new light-driven molecular machines for nanotechnology applications.
Investigating the photochemistry of organic dyes for potential applications in dye-sensitized solar cells.
Studying the effects of light on the behavior of biological macromolecules.
Designing new photoresponsive hydrogels for drug delivery applications.
Exploring the photochemistry of semiconductor nanoparticles for potential applications in quantum computing.
Investigating the mechanisms of photochemical reactions in ionic liquids.
Developing new photonic sensors for chemical and biological detection.
Studying the photochemistry of transition metal complexes for potential applications in water splitting and hydrogen production.

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Current research topics

Topics currently pursued in the group of Prof. Sarkar

Research topics

Electron transfer and optically switchable molecules with non-innocent ligands.

Complexes that display electrochromic behaviour are ideal starting materials for optically switchable devices. In this project, we aim to combine the redox and optical properties of non-innocent ligands to obtain metal complexes with strong, redox-switchable NIR absorption bands. A long-term goal is to transfer these processes to surfaces to develop smart optical windows .

Metal complexes of bidentate and tripodal "Click"-triazoles and catalysis

Bidentate and tripodal ligands bearing triazole-based donor functionalities can be synthesised in high yields with excellent selectivity be means of the CuAAC "Click" reaction. The resulting metal complexes are competent catalysts for C-H oxygenation and amination reactions, N -arylations as well as for olefine polymerisation and oligomerisation.

Metal complexes of meso-ionic/anomalous carbenes and catalysis

The use of meso-ionic carbenes, a novel class of carbene ligands, as powerful ligands in metal catalysed reactions has strongly increased in recent years. We were able to show that such metal complexes serve as highly efficient catalysts for a variety of reactions, e. g. C-C cross couplings, C-H oxygenation cycloaddition, transfer hydrogenations as well as α-arylation of amides. Our current focus is on the synthesis of multinuclear complexes to investigate possible catalytic cooperativity between the metal centres.

Non-innocent ligands in homogenous catalysis

In contrast to most of our catalytically active systems, this project puts emphasis on making use of the ligand's electrons and protons for bond formation and activation reactions. Recently, we have accomplished (electro-)catalytical C-C bond formation, reduction of C=O functionalities and cyclisation reaction using these unconventional catalytic systems. The project aims at using electrons of the metal centre and the non-innocent ligand in a cooperative fashion to obtain active homogenous catalysts.

Small molecule activation and bio-inspired catalysis

Nature has mastered the art of using non-innocent ligands in highly effective transition metal complexes that allow the activation and chemical transformation of small molecules. Inspired by these enzymatic processes, we try to use quinoid systems and meso-ionic carbenes in metal complexes as electron-reservoirs for both the activation and formation of H 2 as well as for the activation of O 2 , CO 2 and H 2 O. By incorporatong non-innocent ligands into the metal complexes, multi-electron and proton transfer reactions are facilitated and thereby the desired reactions made possible. Furthermore, we try to extend these activation reactions to catalytic transformations that allow for the production of useful chemicals.

Metal complexes of tripodal "Click" ligands for photo- & electrochemical bond activation

Triazolhaltige tripodale Liganden welche mithilfe der „Click“-Chemie hergestellt werden, bieten eine ideale Koordinationsumgebung für photochemische und elektrochemische Bindungsaktivierungsreaktionen an Metallzentren. In diesem Projekt versuchen wir die elektrochemische und photochemische Reaktivität durch die gezielte Variation der sterischen und elektronischen Eigenschaften der tripodalen Liganden einzustellen. Anspruchsvolle photochemische Messungen werden teilweise durch unsere Kollaborationspartner durchgeführt. Triazole-based tripodal ligands, synthesized via "Click" chemistry, offer an ideal coordination environment for photo- and electrochemical bond activation reactions at metal centres. We try to tune the electro- and photochemical reactivity via targeted variation of the sterixc and electronic properties of the tripodal ligands. Complex photochemical measurements are performed by our collaborators, mostly within the DFG-funded priority programme "Light Controlled Reactivity of Metal Complexes" (SPP2102)

Magnetically switchable molecules

We believe that ligand systems such as quinones, triazoles and meso-ionic carbenes have great potential in devising novel magnetically switchable molecular materials. While earlier work resulted in mononuclear Co(II) and Fe(II) complexes displaying SCO behaviour with a large hysteresis loop close to room temperature, we recently extended our work on Co(II)-based Single Molecule Magnets to dinuclear systems in order to investigate relaxation processes. These projects entail a close collaboration with groups that are specialised in molecular magnetism and theoretical chemistry. These fascinating molecules might be used as molecular data storage devices in future applications.

Metal complexes for (potential) pharmaceutical applications

A new research topic in our group is the use of metal complexes bearing diimines, triazoles and meso-ionic carbenes for (potential) applications in anti-tuomr research or as antibacterial agents. This projects is worked on in conjunction with biochemists and medicinal chemists.

Functionality via synthesis

We apply organic methodology to synthesize tailor-made ligand systems. These are subsequently used to form metal complexes with a defined coordination sphere. Principles from organometallic and traditional coordination chemistry as well as photochemistry and microwave-assisted synthesis are employed in this regard. This holistic approach allows for the targeted synthesis of catalytically active or switchable complexes. Reactive species and catalytic intermediates can be accessed by working under inert conditions.

Heteronuclear and multidimensional NMR

Initial characterisation of new compounds is often performed via one-dimensional 1 H and 13 C NMR spectroscopy. If the corresponding nuclei are present, this is complemented by e. g. 31 P, 19 F, or 15 N spectra. Multi-dimensional NMR spectroscopy is used for the precise assignment of nuclei in more complex molecules. Additionally, these methods are sued to detect and characterise intermediates in catalyse, which can lead to important mechanistic insights. Also in the case of paramagnetic substances, temperature-dependent measurements are invaluable to gather information on spin state and possible spin state witching in solution.

Cyclic voltammetry, differential pulse voltammetry and Coulometry

Redox-active organic compounds and their metal complexes are at the heart of our research. In order to elucidate electron transfer processes, we use a combination of CV and DPV. The same methods are also employed to investigate electrocatalytic processes such H 2 activation and production, CO 2 reduction and C-C bond formation. These methods are supplemented by bulk electrolysis. Our current focus is the use of electrochemical methods to investigate the reaction mechanism of electrocatalytic reactions.

IR spectroscopy and spectro-electrochemistry

Besides NMR spectroscopy, IR spectroscopy is extremely powerful for gaining structural information on molecules. Often this method is used as a simple characterization tool. However, we also use IR spectroscopy in combination with electrochemistry (IR spectroelectrochemistry). Such an approach allows us to gather structural information on chemical systems in their various redox states. IR spectroelectrochemistry also provides useful information on the charge distribution in molecules. Additionally, IR spectroelectrochemistry helps us in determining the donor properties of new redox-active ligands and in probing mechanisms of electrocatalytic reactions.

UV/vis-NIR spectroscopy and spektro-electrochemistry

Many compounds synthesized in our labs are strongly colored. Hence, absorption spectroscopy in the visible region is extremely useful for the characterization of such compounds. As one focus of our research is the generation of visible and NIR electrochromic dyes, the combination of electrochemistry and UV-vis-NIR spectroscopy (spectroelectrochemistry) is widely used in our labs. This combination allows us to determine optical switching in the visible and the NIR region. Additionally, we use UV-vis-NIR spectroelectrochemistry to gain information on the electronic structures of the compounds in their various redox states, to investigate electron transfer processes, and to investigate electrocatalytic reaction mechanisms.

Multi-frequency EPR spectroscopy and spectro-electrochemistry

Crystallography

For an inorganic chemist, the epitome of structural characterization is single crystal X-ray diffraction. We often characterize all our metal complexes through this method. In cases, where information from spectroscopic methods are not sufficient for the prediction of the structure of a new compound, information from single crystal X-ray diffraction is extremely useful. Additionally, for paramagnetic compounds, this method delivers direct structural information on the samples, which is otherwise hard to obtain through other methods. In some cases, intermediates obtained from chemical reactions are investigated with single crystal X-ray diffraction to obtain valuable information about the reaction mechanism.

Density Functional Theory

In modern chemistry, DFT calculations play a vital role in elucidating diverse chemical and physical properties of chemical compounds. In our group, DFT calculations are used to probe the electronic structures of metal complexes, and to complement and comprehend the spectroscopic data obtained from several spectroscopic techniques. Such a combined theoretical and experimental approach helps us in understanding our systems better, and also provides us with some predictive power over newly synthesized systems. While basic DFT is carried out in the group itself, we collaborate with expert theoreticians on advanced problems.

Photochemistry

Light is an extremely powerful, benign and environmentally friendly energy source for carrying out various chemical reactions including catalysis. In our laboratories, we use light for both catalysis, as well as for bond activation reactions resulting in highly reactive and exotic chemical species. In many cases, it is not possible to carry out these light-induced reactions through normal thermal activations. A first focus of these investigations is to convert light into useful chemistry. However, the mid- and long-term goals of these projects are to understand the photochemical landscapes of such species, and to correlate these with the observed chemical reactivity. Many of the spectroscopic methods mentioned above are combined with photochemical reactions to probe mechanisms. Additionally, we collaborate with photochemists and photophysicists to have a closer look at the excited states of these molecules.

Inorganic Chemistry

MASTERING THE SYNTHESIS, PHYSICAL PROPERTIES AND REACTIVITIES OF METAL CONTAINING MOLECULES, MATERIALS AND ENZYMES

Inorganic chemists characterize, create, understand and develop tools to research inorganic and hybrid organic–inorganic molecules, metalloenzymes and materials, with applications spanning catalysis, green energy, and more. At the lightsources of SLAC National Accelerator Laboratory , Stanford scientists pioneered the use of synchrotron radiation to study the relationships of molecular and electronic structure to function, and continue to explore the power of the free-electron laser to resolve structure and capture chemical reactions in stop-action. Studies examining electronic and metrical details of metal ions at the active sites of enzymes have provided important insights into environmental catalysts, such as the nitrogenase responsible for conversion of atmospheric di-nitrogen to ammonia.

X-ray Spectroscopy

Stanford pioneers in synchrotron x-ray research employ the Stanford Synchrotron Radiation Lightsource at SLAC to probe the electronic and structural environment of metallobiomolecules, demonstrating how molecular structure at different organizational levels relates to biological and chemical function. Using a variety of x-ray absorption, emission, diffraction and scattering techniques, they characterize electronic and metrical details of metalloproteins that are important in Earth’s biosphere, such as those that convert nitrogen to ammonia, oxygen to water or methane to methanol. Related efforts develop methods using the next-generation light source, the free electron laser, to image noncrystalline molecules and study chemical reactivity and photodynamics on ultrafast time scales.

Transition Metal Sites

Stanford chemists combine experimental and theoretical approaches to define the electronic and geometric structures of biologically- and catalytically-relevant transition metal sites , working toward a detailed understanding of relationships among electronic structure, reactivity and function. They have made substantial advances in our understanding of dioxygen activation by copper-containing enzymes and catalysts – making strides toward moving redox-active enzyme sites onto solid substrates.

Green Chemistries

Using mechanistic principles, department faculty develop new catalytic strategies for the selective synthesis of both macromolecules and fine chemicals, including cyclic polymers derived from renewable resources as a potential replacement for fossil fuel-based plastics and cost-efficient catalysts and chemical reactions that recycle CO2 into fuels and commodity chemicals using renewable energy sources. Pursuing applications in clean energy, Stanford chemists are successfully designing hybrid materials with the structural tunability of organic molecules and varied electronic and optical properties of extended inorganic solids , for use as sorbents for capturing environmental pollutants, electrodes for rechargeable batteries, and more.

Associated Faculty

Keith Hodgson

Matthew Kanan

Hemamala Karunadasa

Edward I. Solomon

Daniel Stack

Robert Waymouth

Department of Chemistry - UC Santa Barbara

Research areas - inorganic & organometallic.

Inorganic/Organometallic Research Faculty

Organic materials
Iron transport, bioinorganic chemistry
inorganic synthesis, kinetics and mechanism, nitric oxide delivery
organometallic synthesis, actinides, high-oxidation states
catalyst design, first row and main group synthesis, sustainable chemistry
Surface chemistry and catalysis
Inorganic materials, metal oxides, magnetism
Mesoporous materials, nanomaterials

Lecturer Faculty

Laverman, Leroy Lecturer/Lab director

Emeritus Faculty

Kaska, William C. inorganic synthesis, pincer complexes
Watts, Richard Inorganic photochemistry

Frontiers in Chemistry
Inorganic Chemistry
Research Topics

Inorganic Chemistry Editor’s Pick 2021

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We are pleased to introduce the collection Inorganic Chemistry Editor’s Pick 2021 . This collection showcases most well-received spontaneous articles from the past couple of years, and have been specially handpicked by our Chief Editor Prof. Luis Carlos. The work presented here highlights the ...

Important Note : All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.

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Reviews in Inorganic Chemistry

Online ISSN: 2191-0227
Print ISSN: 0193-4929
Type: Journal
Language: English
Publisher: De Gruyter
First published: October 1, 1985
Publication Frequency: 4 Issues per Year
Audience: Researchers in inorganic and metallorganic chemistry in academia and industry

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Bioinorganic chemistry articles from across Nature Portfolio

Bioinorganic chemistry is the study of the structures and biological functions of inorganic biological substances, that is, those not containing carbon, such as metals.

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Ion transport
Metalloproteins

Latest Research and Reviews

Mutational dissection of a hole hopping route in a lytic polysaccharide monooxygenase (LPMO)

Lytic polysaccharide monooxygenases (LPMOs) are mono copper enzymes with outstanding industrial applicability. Here, the authors investigate the “hole hopping” mechanism in a bacterial LPMO and show that a strictly conserved tryptophan is critical for radical formation and hole transference, as well as reveal a correlation between the efficiency of hole transference and enzyme performance under oxidative stress.

Iván Ayuso-Fernández
Tom Z. Emrich-Mills
Vincent G. H. Eijsink

Synthesis, characterization, biological potency, and molecular docking of Co 2+ , Ni 2+ and Cu 2+ complexes of a benzoyl isothiocyanate based ligand

Eida S. Al-Farraj
Adel M. Younis
Gaber M. I. Abu El-Reash

A hemoprotein with a zinc-mirror heme site ties heme availability to carbon metabolism in cyanobacteria

Heme is an abundant cofactor required by nearly all known organisms. Here, authors discover a cyanobacterial protein with a distinct Zn-mirror heme site, which may function to sense heme and regulate energy metabolism.

Nicolas Grosjean
Estella F. Yee
Crysten E. Blaby-Haas

Widespread extracellular electron transfer pathways for charging microbial cytochrome OmcS nanowires via periplasmic cytochromes PpcABCDE

How do cells put electrons to rest? Using a minimal pathway to get rid of excess metabolic electrons, diverse environmentally important microbes overcome large spatial, kinetic, and thermodynamic barriers in order to survive in extreme anoxic conditions.

Pilar C. Portela
Catharine C. Shipps
Nikhil S. Malvankar

Utilizing Ni(II) complex for metal drug-gel particles in cervical cancer treatment and designing novel drugs through machine learning methods

Meiping Jiang
Xiaoli Wang

Carotenoid cleavage enzymes evolved convergently to generate the visual chromophore

NinaB is an isomerooxygenase that generates visual chromophore (11- cis -retinal) from carotenoid substrates. Here Solano et al. reveal the structural basis for NinaB isomerase activity, providing new insights into the evolution of visual chromophore synthesis by carotenoid cleavage enzymes.

Yasmeen J. Solano
Michael P. Everett
Philip D. Kiser

News and Comment

Lifting iron higher and higher

Biological and synthetic catalysts often utilize iron in high oxidation states (+IV and greater) to perform challenging molecular transformations. A coordination complex featuring an Fe(VII) ion has now been synthesized through sequential oxidations of nonheme iron–nitrido precursors.

Adam T. Fiedler
Laxmi Devkota

Anticancer platinum-based photo-oxidants in a new light

Pharmacologically inactive prodrugs that can be activated by near-infrared light are attractive candidates for clinical applications. Now, platinum-based photo-oxidants have been shown to eradicate tumours in mice with a new mode of action.

Gloria Vigueras
Gilles Gasser

In-cell protein stability promotes antimicrobial resistance of metallo-β-lactamases

Protein stability is important for biological function, but little is known about in-cell stability. In the New Delhi metallo-β-lactamase NDM-1, enhancement of zinc binding or amino acid substitutions at the C terminus increase in-cell kinetic stability and prevent proteolysis. These findings link NDM-1-mediated resistance with its in-cell stability and physiology.

Core strength

Benjamin Martindale

Boosting solid stability

Drying DNA with crystalline calcium phosphate can help boost its stability.

Stacey-Lynn Paiva

Open questions on the biological roles of first-row transition metals

First-row transition metals play several roles in biological processes and in medicine, but can be toxic in high concentrations. Here the authors comment on the sensitive biochemistry and speciation chemistry of the first-row transition metals, and outline some of the remaining questions that have yet to be answered.

Debbie C. Crans
Kateryna Kostenkova

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Chemistry Research Topics: A List of 150 Winning Ideas

A chemistry science student conducts research works that are associated with their interests and seeks to study different chemical phenomena or reactions within their fields.

A top-notch research topic is an essential foundation of a good research paper. A good research paper carries the potential to boost your academic grades. On the contrary, a poorly written research paper can severely affect your grades. Most chemistry students often end up making the same mistake of choosing the wrong chemistry research topics for their papers. It significantly affects the quality of their academic grades.

Read our blog to dig deeper to get the best research topics for chemistry. We are sure this article will be helpful for you. We have prepared lists of more than 150 exciting chemistry research topics. These topics will help you attain the highest grades and enjoy your research process simultaneously.

Table of Contents

Organic Versus In- Organic Chemistry

Chemistry is an old age of science for which human knowledge has enhanced over the past decades. It was in the 17 th century when scientists discovered that there are in total two branches of chemistry: organic chemistry and in- organic chemistry.

Now, for a better understanding let us explore the differences between these two branches of chemistry.

Both of these fields include analytical laboratory techniques to analyze the behavior of different compounds within their disciplines.

Before moving forward to the topics selection, we suggest you to have a look at this guide for creating or choosing the ideal chemistry research topic.

Noteworthy Guidance for Selecting a Successful Chemistry Research Topic:

Indeed selecting chemistry research topics is not easy, but it’s not impossible, is it? Well, obviously, no. All you need is some expert help with chemistry research topics. But first, whilst you are in your selection phase, narrow down the chemistry research topics and select the topics that are:

Interesting to you : Interesting research topics are your way to a successful research paper. Avoid selecting tedious, dull and difficult topics; choose a chemistry topic for which you have good knowledge and understanding.
Analytical: Before selecting your topic, make sure it’s analytical. Read previous scholarly articles to understand the thought process of renowned scientists. Thinking about analytical chemistry research topics would improve the credibility of your research paper.
Researchable : conduct background research for your chemistry topics. It will help you to structure a strong foundation for your research paper. Popular topics are always helpful for making a successful paper. You can get numerous authorized content regarding popular topics. However, to draft a unique research paper, include some new studies and hypotheses on that topic.
Supporting references and materials: Make sure your research topic has enough reliable sources. Before selecting your research topic, see if it consist well- trusted books, article or journals.
Following university guidelines: Before choosing your chemistry research topics, you must analyze whether your topic follows the university writing requirements or not. An impactful research paper includes all the essential norms acknowledged by the scientific community.

List of 150 Enticing Chemistry Research Topics

Here we go! In this section, we have created the best chemistry research topics in a nutshell.

Let’s have a look at some of the best chemistry research topics. Select the one that’s best for you and get started with your research work. For a better understanding, we want you to read every topic thoroughly and then decide what works best for you.

So what are you waiting for? Let’s get started!

Organic Chemistry Research Topics

Organic chemistry is a vast study area that studies carbon-containing molecules. This field contains various organic chemistry research topics to write and study about in this area. To draft an impressive chemistry research topic, invest your time and energy in conducting the prerequisite research first.

Here are just a few of the best organic chemistry science research topics for you to consider:

Investigation of the recent advancements in the methods for synthesizing chiral molecules
Studying the electronic structure and chemical reactivity of carbon nanotubes
Define and explain the oil in a nutshell
Chlorination of phenol
Exploring the preparations and properties of metal complexes with organometallic ligands
Towards rational crafting of benzene derivatives with improved thermal stability
Exploring the new ways of molecular reaction dynamics
Learning stereochemistry in organic compounds
A handbook on learning the isomerism types in organic compounds
Nucleophiles: reactions of nucleophiles with ethylenic substrates
Conceptive research on nucleophiles
Discovery of aniline dyes
The ups and downs of nucleic acids stability
Process modelling for hydrocarbon fuel conversion
Exploring the new C-O electrophiles in cross-coupling reactions
New directions toward structure formation and stability
Regulations of nitrogen compounds in water
A review of the effect of alcohols on micro-organisms
Snow pollution management in urban areas
Exploring the effects of cell-surface sugars on health, illness, and aging

Inorganic Chemistry Research Topics

Inorganic chemistry deals with in-organic compounds which consist of ionic bases into them. Excluding carbon, all the other elements mentioned in the periodic table are included in inorganic chemistry. It includes inorganic compounds such as minerals, metals, etc. But let us not dive into the details and leave that part to your research paper.

Here are some interesting inorganic chemistry research topics for you:

A detailed study on how metals react with each other
Needs trends and new alloys of inorganic chemicals
Inorganic chemistry and its relationship with the pharmaceutical industry
Effects of different chemicals and their reactions on the human body
Past, present, and future of inorganic chemicals
A conceptive study on inorganic chemistry and its role in the environment
The future of inorganic chemistry and sustainable development
The method of creating new alloys and how to improve the existing ones
Inorganic chemistry and its relationship with the food industry
The relationship between inorganic chemistry and the cosmetic industry
Principals of inorganic chemistry: theory, practice, and applications
Modifications of NaCI structure: why is it salty?
A detailed study on the formation of sapphires
The law of multiple proportions
Different states of matter: on Earth and in the Cosmos
Hydrodynamics of soft active matter handbook on the effects of sulfuric acid on organic materials
A comparative study of the difference between organic and inorganic compounds
Importance of inorganic chemistry
Explanation of Lewis structures and Electron Dot models

Advanced Physical Topics in Chemistry

These topics are widely focused on advanced physical topics in chemistry. If you are still confused about your chemistry-related research topics, we hope these topic ideas might interest you:

A concise study on the relationship between chemical reactions and heat
Introduction and progress in the fields of spectroscopy
Introduction to quantum chemistry in the age of quantum computing
Ideas and variations of methods in quantum chemistry
Recent advancements in mechanistic organic photochemistry
Definition and standardization of pH measures
A handbook on the structure of atoms on a quantum scale
The chemical bonding across atoms and molecules
The relationship between temperature and chemical reactions
Introductions and principles of chemical kinetics
Recent advancements in the role of light in in-body chemical reactions
The influence of surface tension and its effects on mixtures
An overview of interfacing of advanced computing in the electron microscope
Advanced technology paths towards a science of global climate stability
Catalytic reaction: structure sensitivity and nanoplasmonic probes
A detailed study on the nanoelectrodes and Sensors

Easy Research Topics in Chemistry

These are a few chemistry research topics that are important and easy simultaneously. So here are some essential chemistry topics which may interest you:

Introduction to modern liquid chromatography
Rational molecular design for achieving persistence and reducing toxicity
Properties of mesoscopic structure at ultrafast time scales
Climate chemistry: role of chemistry for preserving climate issues
The chemistry of allergy
Host-Guest Interactions of Fullerene Fragments
Lewis structure study

General Chemistry Topics for Research

If you are looking for general chemistry research topics, this section is specifically made for you. Have a look at this section before selecting your chemistry topics. This section comprises various general chemistry topics that are important simultaneously.

Batteries for vehicular applications: building better batteries
Conductive polymers as the new established thermoelectric material
Pesticides use in vegetable production: a survey of American farmers
The harmful impacts of pesticides on human health
Explain the fast dynamics of water droplets upon freezing
What is the reason behind the breakage of freezing rocks
Formation of cholesterol crystallites
A meta-analysis of the controversy of steroids
A meta-analysis on the biological synthesis of cholesterol
Fritz Haber: as a damned scientist

Analytical Chemistry Topics for Research

Analytical chemistry studies and identifies matter’s composition, status, determination, and structure. Scientists use analytical chemistry to determine the matter and how much it is helpful in something. So, if you are keen to research analytical chemistry topics, here are some of the great ideas to move forward with your research:

Introduction to liquid chromatography
Environmental analytical chemistry
Identifying chemical reaction hazards in the laboratory
Introduction to chromatography
Understanding molecular dynamics and targeted thermostat schemes
An overview of chiral class drug analysis in forensic laboratories
Optical enantiomers flaw: symmetry and molecular chirality
Learning chemical equilibrium with the jigsaw technique
Application of electrochemical biosensor for toxic detections
Revisiting qualitative analysis of chemistry
An overview and an update on the clinical pharmacology of ibuprofen
Evaluation of Isomerism framework advantages
Principals and classifications of chromatography
Exploring multiple time-scale molecular dynamics
Effects of chemical equilibrium
The adulteration of drugs
Rethinking amide bond’s effects in polypeptide field

Innovative Research Topics for Chemistry

Innovative chemistry refers to linking your creative ideas with your chemistry research topics. So, if you were thinking of making a groundbreaking chemistry research paper, here are some chemistry topics to write about:

Side-chain conformational effects in protein folding
An overview of thiophene compounds
Sonochemical synthesis of nanomaterials for green chemistry
Enzymes and their significance in chemical reactions
The tragedy with fritz
The functions of enzymes in maintaining soil health
Fabrication and application of photocatalysis in 3Dprinting
Farming with fewer pesticides: health and environmental cost of pesticides
Cellular transportation of drugs
The introduction and science of flavonoids
Black drug intermediates
Scatter research for chemical and bio-process optimization
Development of responsive sensors of upconversion nanomaterials
The philosophy of quantum mechanics: a modern development
Identifying the significance of astrochemical research on extraterrestrial molecules
A deep analysis of cellular transport systems in facility logistics
Evolving medicinal chemistry: fusion of traditional and modern chemistry
The significance of Meta- organic frameworks
Monitoring chemical reactions of pressurized organic components
Deep research on active pharmaceutical ingredients

Controversial Chemistry Topics for Research

Controversial topic includes all those exciting buzzing topics, which make people curious to know more. If you still haven’t found your topic, have a look at these below given controversial chemistry research topics to get started with your research:

Chemicals in war: the history of chemicals and biological warfare agents
Interaction between hydrogen and dipole and their functions in protein
Current concepts of bioengineering
Association of food chemicals with the human brain
Production of food flavouring agent
Modulations of hydrophobic effects
Hydrophobic interactions
State’s role in regulating chemicals
Cigarettes and cigarette smoking: Evolution of chemicals in cigarettes
The chemical effects and trouble associated with cannabidiol oil
Bad chemical reactions: the rise and rise of antidepressants
DNA and decentralization of electrons
A handbook on
chemistry and the origin of life
Chemical warfare ethics
A structure-based platform for predicting chemical reaction
Synthetic self-replicating molecules
The growing danger of bioconjugation chemistry
Fritz Haber’s experiments in life and death
Principals and practices of green chemistry

Read Also – Interesting Biology Research Topics

Biochemical Engineering Topics in Chemistry

Biochemical engineering is an important pillar industry of this century. It is the interdisciplinary combining biotechnology and chemical engineering. So, if you are interested in this field but wondering which topic to choose. We are here to provide our help with research papers . Here are a few exciting chemistry research topics:

Thermodynamics in biochemical engineering
Transmembrane transporters
An ontology of advanced engineering
Understanding the mathematical modelling of metabolism
The harmful effects of food industry chemicals
The future of biochemical engineering
Perceptions and developments of epigenetic
Autophagy: process and functions
An introduction to the mechanisms of apoptosis
Mechanisms of tetracycline drugs

Biochemistry Research Topics

While this term might sound obscure, it includes critical fields such as environmental protection, rehabilitation, genetics, use of opioids, etc. If you are keen to analyze more about these subjects, we have selected the ten most essential biochemistry topics. Before selecting the topic, we suggest you read each topic thoroughly and conduct primary research on the selected ones:

Significance of biochemistry for cancer treatment
The extraordinary mitochondrion citric acid cycle
The role of biochemistry in building the immune system
Epigenetic: the science of probiotic research
Unravelling the cell metabolism process
Behavioural study of biochemistry
Significance of
biochemistry in heart diseases
The visible history of the visible sheep: the legacy of dolly the sheep
Industrial applications and utilization of amino acid
New therapies for treating hemophilia

Final Thoughts

At last, we hope this article has provided help with selecting chemistry science research topics. We agree that choosing science research topics is difficult, especially when you are supposed to write a paper on chemistry topics. The research topic for chemistry consists of various pertinent sub fields under this domain, but you must focus on that one topic that highlights your skills and knowledge in the best way.

The above-given topics will help you to take a step toward a successful academic career. Interesting chemical research topics can create a strong foothold of your entire work in your research proposal . Highlight the importance of the topic in your research proposal. Elaborate how your research work can create a massive difference in your field, etc.

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The mission of the Department of Chemistry and Biochemistry is to provide a general knowledge of chemistry and biochemistry for the student desiring a liberal arts education. For chemistry and biochemistry majors, the Department introduces students to the five major divisions of chemistry (analytical, biochemistry, inorganic, organic, and physical) and trains them in the type of reasoning necessary to thrive in these fields. The Department prepares students for further studies in graduate school, professional schools (including medicine and other healthcare fields), and for careers in the chemistry profession. The Department of Chemistry and Biochemistry affords the students opportunities to get involved in scientific research on cutting-edge topics using current methods and instrumentation, while being mentored and trained in analysis, interpretation of research results, and the written and oral communication of these results. Students also have opportunities to present their research findings within both the university community and the larger scientific community.

Distinctives of the Chemistry and Biochemistry Department

The training provided by the Department of Chemistry and Biochemistry is intended to meet the diverse needs of students interested in chemistry and/or biochemistry. The majors in the Department aim to prepare students for graduate school, professional school, or the workplace by providing experiences and training in the five major areas of chemistry which include: organic, inorganic, biological, analytical, and physical. The goals of majors in the Department are to build a strong foundation of chemical knowledge and skills through lecture and laboratory components that can be expanded upon in the students’ training and career. The Department also offers advanced specialty courses that are based on student interest that aims to expose students to cutting-edge work in chemistry fields. Aside from training in the five major areas of chemistry, the Department helps connect students to research opportunities on-and off-campus while providing students with tools to discuss ethics and faith in the context of science.

Career Opportunities

The Department of Chemistry and Biochemistry offers five majors, each intended to prepare students for a different path:

The Chemistry (B.S., B.A.) and Biochemistry (B.S., B.A.) majors are intended to prepare students for graduate schools and/or the chemical industry. Students will have the opportunity to take additional lecture courses and laboratories that enrich their training in the five major areas of chemistry. Students within these majors are heavily encouraged to do research, and they will be connected with opportunities in-and off-campus.
The Applied Chemistry (B.S., B.A.) major is intended for students who want to couple their chemistry training with another academic area, such as business, math, computer science, environmental science, and many others. Students interested in professional school (medical school, pharmacy school, dental school, etc.) may choose this major over Biochemistry for Health Professions if they want training in other areas outside of the chemistry and biology curricula. This major is intended to be flexible, and the Department is open to building an Applied Chemistry major for students that provides them with the necessary training they are seeking.
The Biochemistry for Health Professions (B.S., B.A.) major is primarily intended for students who are planning to go to professional school, including medical school, pharmacy school, dental school, and other health-related programs. Students within this major will be able to complete their prerequisite coursework for professional school admissions while working toward a chemistry degree.
The Chemistry Teaching (B.S., B.A.) major is intended for students interested in teaching at secondary level (middle and high school). Students within this major will receive training in all major areas of chemistry as well as specialized practice courses on teaching chemistry.

Future steps for graduates of the Department of Chemistry and Biochemistry largely depends on the major they choose. Students interested in a major in the Department are invited to open a conversation with one of the professors to determine which major is best suited to their interests and aspirations.

Program of Study Requirements

Applied Chemistry, B.A., B.S.
Biochemistry for Health Professions, B.A., B.S.
Biochemistry Major, B.S., B.A.
Chemistry Education Major(General Science-Chemistry), B.A., B.S.
Chemistry Major, B.A., B.S.
Chemistry Minor
CM 411V - Independent Study and Research (1, 2) F, SP, SU
CM 1013 - Introduction to Chemistry (3) F, SP, SU
CM 1024 - Chemistry for Health Sciences (4) F,SP
CM 1113 - General Chemistry I (3) F, SU
CM 1123 - General Chemistry II (3) SP, SU
CM 1211 - General Chemistry I Laboratory (1) F, SU
CM 1221 - General Chemistry II Laboratory (1) SP, SU
CM 2113 - Organic Chemistry I (3) F, SU
CM 2123 - Organic Chemistry II (3) SP, SU
CM 2211 - Organic Chemistry I Laboratory (1) F, SU
CM 2221 - Organic Chemistry II Laboratory (1) SP, SU
CM 2314 - Analytical Chemistry (4) SP
CM 2910 - Chemistry Colloquium (0) F
CM 3053 - Methods of Teaching Chemistry (3) Offered on demand
CM 3113 - Physical Chemistry I (3) F
CM 3124 - Physical Chemistry II (4) SP Offered even-numbered years
CM 3211 - Physical Chemistry I Laboratory (1) F Offered odd-numbered years
CM 3214 - Environmental Chemistry (4) Offered on demand
CM 3313 - Biochemistry I (3) F, SU Offered in the summer on demand
CM 3321 - Biochemistry Lab (1) SP
CM 3323 - Biochemistry II (3) SP
CM 3333 - Green Chemistry (3) Offered on demand
CM 3341 - Green Chemistry Lab (1) SP
CM 3414 - Instrumental Methods of Analysis (4) F
CM 3613 - Inorganic Chemistry (3) SP
CM 3621 - Inorganic Chemistry Laboratory (1) SP Offered odd-numbered years
CM 4213 - Advanced Inorganic Chemistry (3) Offered on demand
CM 4221 - Advanced Integrated Laboratory (1) Offered on demand
CM 4313 - Advanced Analytical Chemistry (3) SP Offered on demand
CM 4413 - Advanced Organic Chemistry (3) Offered on demand
CM 4513 - Advanced Physical Chemistry (3) Offered on demand
CM 4613 - Advanced Biochemistry 3 SP
CM 4910 - Directed Research (0) F, SP, SU
CM 4922 - Chemistry Capstone (2) SP

IMAGES

240 Best Chemistry Research Topics and Ideas to Get Started
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COMMENTS

110 Great Chemistry Research Topics [2024]
Inorganic Chemistry is the study of the chemistry of materials that do not contain carbon. Unlike other chemistry research topics, these include elements such as metals, minerals, and inorganic compounds. If you are looking for inorganic chemistry research topics on inorganic chemistry, here are some ideas to get you started:
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Inorganic chemistry articles from across Nature Portfolio. Inorganic chemistry is the study of the structure, properties and reactions of all chemical elements and compounds except for organic ...
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Inorganic Chemistry. Inorganic chemistry is concerned with the properties and behavior of inorganic metals, minerals, and organometallic compounds. The critical distinction from organic chemistry is that inorganic compounds do not contain carbon. But there can be overlap; for example, organometallic compounds usually contain a metal or ...
28 Must-Read Topics in Chemistry
ACS Publications regularly produces collections of the most important chemistry research topics. These Virtual Collections of the most important chemistry research topics bring together the most important ideas in the field in a variety of ways, including Special Issues and ACS Selects from across the portfolio journals. These collections reflect the most important chemistry research […]
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An isolable germylyne radical with a one-coordinate germanium atom. Heavy analogues of carbynes of the type R- \ ( { { {\dot {\mathrm E:}}}}\), where E is a group 14 element, are difficult to ...
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Issue Publication Information. Inorganic Chemistry 2024, 63, 18, XXX-XXX (Article) Publication Date (Web): May 6, 2024. First Page. PDF. Check out the latest edition of the Inorganic Chemistry on ACS Publications, a trusted source for peer-reviewed journals.
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Progress in Inorganic Chemistry : Current Research Topics in
This comprehensive series of volumes on inorganic chemistry provides inorganic chemists with a forum for critical, authoritative evaluations of advances in every area of the discipline. Every volume reports recent progress with a significant, up-to-date selection of papers by internationally recognized researchers, complemented by detailed discussions and complete documentation. Each volume ...
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We are pleased to introduce the collection Inorganic Chemistry Editor's Pick 2021. This collection showcases most well-received spontaneous articles from the past couple of years, and have been specially handpicked by our Chief Editor Prof. Luis Carlos.The work presented here highlights the broad diversity of research performed across the section, and aims to put a spotlight on the main ...
10 Hot Topics in Chemistry So Far in 2023
Hot Articles in Inorganic/Organic Chemistry. Look, it's a hot topics collection within a hot topics collection! This next list includes 58 Editors' Choice articles spanning ACS Publications' core organic and inorganic journals. These editor-curated articles showcase innovative thinking in a variety of areas, including synthetic methodology ...
Inorganic Chemistry Frontiers journal
Inorganic Chemistry Frontiers belongs to Frontiers Journal portfolio, an enterprising collaboration between the Chinese Chemical Society and the Royal Society of Chemistry. The Frontiers project aims to publish a series of high impact, quality chemistry journals that showcase the very best research from China, Asia and the rest of the world to ...
300+ Chemistry Research Topics
Organic Chemistry Research Topics. Organic Chemistry Research Topics are as follows: Development of novel synthetic routes for the production of biologically active natural products. Investigation of reaction mechanisms and kinetics for organic transformations. Design and synthesis of new catalysts for asymmetric organic reactions.
Current research topics
A new research topic in our group is the use of metal complexes bearing diimines, triazoles and meso-ionic carbenes for (potential) applications in anti-tuomr research or as antibacterial agents. This projects is worked on in conjunction with biochemists and medicinal chemists.
Inorganic Chemistry
Inorganic chemists characterize, create, understand and develop tools to research inorganic and hybrid organic-inorganic molecules, metalloenzymes and materials, with applications spanning catalysis, green energy, and more. At the lightsources of SLAC National Accelerator Laboratory, Stanford scientists pioneered the use of synchrotron ...
Research Areas
The inorganic chemistry research area of the Department of Chemistry and Biochemistry at the University of California at Santa Barbara performs cutting-edge research that spans the entire inorganic disipline. ... These topics lie at the heart of energy science, making our division the front line in our quest to build a new energy economy. ...
Special Issue : Recent Advances in Modern Inorganic Chemistry
Bio-inorganic chemistry—investigations of structural and functional models of important natural metal-containing systems, and seeking new biologically active compounds to fight different diseases. This issue will contain the most recent results obtained in research laboratories of prominent inorganic chemists from around the world working in ...
Inorganic Chemistry Editor's Pick 2021
About this Research Topic. Submission closed. We are pleased to introduce the collection Inorganic Chemistry Editor's Pick 2021. This collection showcases most well-received spontaneous articles from the past couple of years, and have been specially handpicked by our Chief Editor Prof. Luis Carlos. The work presented here highlights the ...
Reviews in Inorganic Chemistry
Objective Reviews in Inorganic Chemistry (REVIC) is a quarterly, peer-reviewed journal that focuses on developments in inorganic chemistry. Technical reviews offer detailed synthesis protocols, reviews of methodology and descriptions of apparatus. Topics are treated from a synthetic, theoretical, or analytical perspective. The editors and the publisher are committed to high quality standards ...
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Bioinorganic chemistry is the study of the structures and biological functions of inorganic biological substances, that is, those not containing carbon, such as metals. Ion pumps. Ion transport ...
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Both of you made Inorganic Chemistry a safe harbor for our authors' articles to dock and continue sailing. My dream for Inorganic Chemistry is that the journal be the first choice for high-level publications by chemists of all facets of inorganic chemistry. This includes both the typical topics, such as unique main-group compounds, functional ...
Chemistry Research Topics: A List of 150 Winning Ideas
Read our blog to dig deeper to get the best research topics for chemistry. We are sure this article will be helpful for you. We have prepared lists of more than 150 exciting chemistry research topics. ... Inorganic Chemistry Research Topics. Inorganic chemistry deals with in-organic compounds which consist of ionic bases into them. Excluding ...
CURRENT RESEARCH TOPICS IN BIOINORGANIC CHEMISTRY
Work at the interface between the areas of inorganic and biological chem- istry has greatly intensified in recent years. Organization of the subject material of this growing field of bioinorganic chemistry along topical lines is fairly straightforward, if not completely satisfying. Thus whole litera- tures have grown up around such problems as nitrogen fixation, heme
Comprehensive Inorganic Chemistry III
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Department of Chemistry and Biochemistry
The Department of Chemistry and Biochemistry offers five majors, each intended to prepare students for a different path: The Chemistry (B.S., B.A.) and Biochemistry (B.S., B.A.) majors are intended to prepare students for graduate schools and/or the chemical industry. Students will have the opportunity to take additional lecture courses and ...
LSU Chemistry Students Recognized at Choppin Honors Convocation
May 10, 2024. At the close of each spring semester, the College of Science and its departments celebrate the achievements of students, faculty, and staff at the Arthur R. Choppin Honors Convocation. This year, LSU Chemistry students were distinguished for their exceptional academic performance, research, and service to the College.
Inorganic Chemistry Vol. 63 No. 19
The cover illustrates the aromatic C-N bond scission of a coordinated 1,10-phenanthroline (top) to yield a pyridine ring-opening product (bottom). We have found that C-N bond cleavage of 2,2'-bipyridine or 1,10-phenanthroline ligands results from a reaction sequence involving dearomatization by nucleophilic addition, two at-N methylations, and C-H deprotonation. Computational and ...

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