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A List of unusual Chemistry Term Paper Topics

Enjoy our collections on research topics in chemistry between April and September, 2016.

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Take a trip to the education facility: It helps the researcher to keep hands on and make the subject more fascinating. It engrosses the student further in the subject. More and more investment in terms of time and efforts is another key to choose an interesting topic for term paper. Choose a topic that has vast opportunity to explore and seems highly mesmerizing.

Following are some term paper topics that give ideas to Chemistry students: The link between Ozone and our atmosphere: State how various chemical ingredients used by humans have created havoc on the upper layer of atmosphere creating holes in ozone layer. Economical sources of energies used as fuel: Focus on the production and usage of various renewable sources of energy and its advantages in contrast to non-renewable sources of energy.

Use your innovation and think for the ways of transformation of coal, natural gas, electricity etc via chemical structures. The impact of Greenhouse gases: Cite exchange of energy between sun and global surface, its effect on vegetation, animal life, atmosphere and humans. Effects of Arsenic on drinking H2O: State relation between the poisonous waste of factories and the carcinogenic ailments.

Mention development of skin and lung cancer, spasms, cancer, nervous system, night blindness etc by relating its consequences with drinking water. Cover the subject in various disciplines of science and medicines. The mechanisms and physiological targets of these redistributions are almost completely unknown.

The Cotruvo lab has developed protein-based fluorescent sensors that respond to GSH selectively and that can be targeted to organelles to probe the proteins involved in GSH movement within cells. In this project, students would aid in sensor optimization and targeting to organelles of interest, and investigate putative transporters via genetic knockdown.

The REU student would gain experience in a variety of biochemical and chemical biology methods such as protein engineering, protein purification, molecular biology, mammalian cell culture and transfection, and confocal microscopy. Understanding Macromolecular dynamics Faculty Mentors: Scott Showalter and Will Noid. A central problem in modern physical biochemistry is to quantify the conformational dynamics of highly flexible biological macromolecules, such as intrinsically disordered proteins, and then to establish the connection between those dynamics and molecular function.

This REU project will focus specifically on the role of conformational dynamics in producing specific and reversible proteinprotein and protein-nucleic acid interactions that drive the process of gene transcription. REU students will gain experience with recombinant protein expression in bacterial cell culture as well as protein purification and characterization.

Depending on the interests and background of the individual student, projects will emphasize different areas of analytical and physical chemistry, including high-resolution NMR spectroscopy, mass spectrometry, micro-calorimetry, and functional assays involving introductory mammalian cell culture, as well as computational analyses to generated detailed molecular structure sets for highly flexible biomolecules.

It has been found that receptor molecules, such as porphyrins, nanoparticles and proteins, can migrate up a concentration gradient of their corresponding ligands. This phenomenon, which is called chemotaxis, may have physiological consequences and can be exploited to create a new generation of nanomotors that respond to subtle changes in the chemical environment of the surrounding medium. We are exploring ligand-receptor binding systems to determine the underlying molecular mechanism of this process as well as to build a new generation of devices that can produce chromatographic separation of receptor materials.

Significantly, many of the proteins that display chemotaxis are also enzyme-based catalysts wherein their ligand fuel may provide a direction of motion for the substrate. Students involved in this project will obtain a unique opportunity to study the motion of nanomaterials using novel spectroscopic techniques as well as help in the development of microfluidic platforms and assays.

REU projects will involve the design, characterization, and study of autonomous, chemically powered, particles. One of the projects will involve the fabrication of bimetallic nanorods and the examination of their movement arising from redox reactions occurring at the two-ends of the rods. The second project will involve the synthesis of enzyme-anchored particles powered by catalytic reactions and the study of their collective behavior in the presence of external and internal stimuli.

Such systems can be further configured to observe predator-prey behavior among the swimmers, where groups of particles functionalized with different enzymes will form interaction cascades and display emergent dynamic patterns. The projects will expose the REU students to a variety of synthesis and materials characterization techniques, More broadly, the students will learn how chemistry, physics, nanotechnology, and fluid dynamics can be integrated to create synthetic materials that exhibit unprecedented biologically-inspired behavior.

The specific activity of enzymes changes depending on the rate at which the ribosome synthesizes the enzyme during the elongation phase of translation. The molecular origins of this phenomenon is unknown, although the most likely hypothesis is that translation kinetics alters cotranslational folding events that influence the population of soluble, but kinetically-trapped non-functional protein molecules.

The goal of this project is to understand the extent to which protein structure around the active sites of enzymes can be perturbed by changes in codon translation rates. REU students will gain experience in computer coding, molecular dynamics simulations, and statistical and kinetic analyses of simulation trajectories.

And ultimately, they will help contribute to the emerging paradigm about how kinetics more than thermodynamics determines protein structure and function. The electrochemical reduction of carbon dioxide CO 2 may provide an economical means of storing renewable energy - generated as electricity from wind or sunlight - in the form of liquid fuel.

This program focuses on the discovery of better electrocatalysts for the reduction of CO 2 to small molecule feedstocks for the synthesis of liquid hydrocarbons.

In this project, REU students will synthesize bi- and trimetallic alloy catalysts and characterize them structurally and electrochemically. Structural characterization techniques will include X-ray powder diffraction, electron microscopy, and X-ray photoelectron spectroscopy. Students will use electrochemical methods to measure the onset potentials for CO 2 reduction and proton reduction as a function of catalyst and additive composition.

Product distributions will be measured by gas chromatography. The choice of catalyst materials will be guided by theoretical and mechanistic considerations.

In this project, REU students will engage in multi-disciplinary efforts to discover new heterogeneous catalysts that are relevant to applications in solar energy conversion, fuel cells, and target-oriented organic synthesis. Representative types of catalytic transformations include the oxygen evolution reaction, the oxygen reduction reaction, CO 2 reduction, and selective hydrogenations and oxidations. Students will first synthesize a variety of solid-state materials as nanoparticles, films, powders, and single crystals, and then analyze them using a suite of materials characterization and catalytic testing techniques.

Inspiration for target catalytic materials will be drawn from computational and mechanistic predictions, as well as from structural and compositional analogies with known homogeneous and biological catalysts.

Catalysis is the foundation of the modern chemical economy, allowing the accomplishment and commercialization of reactions that would otherwise be cost and energy prohibitive. The traditional means of increasing catalytic efficiency is to modify the catalyst to lower the barrier for any given specific reaction. This REU project will focus on understanding how to use the properties of nanoparticles to control more precisely the distribution of this heat, and to understand the impact that this increased control has over the efficiency of catalyzed reactions.

Students involved in this project will design and synthesize nanoparticle systems and characterize these systems using microscopy and diffraction techniques.

They will then incorporate the nanoparticles into catalytically primed reaction mixtures and measure the efficacy of the photothermal effect for driving catalysis using a variety of analytical techniques. John Asbury and Ray Schaak. A central problem in the development of solar power as an alternative energy supply is the ability to store the energy for later use when the sun is not shining.

Catalytic materials based on inexpensive and earth-abundant elements are attractive alternatives to noble metal and rare-earth catalysts. This REU project will work toward development of new earth abundant nanocrystalline materials systems that enable high efficiency photocatalysts for hydrogen production and oxygen evolution. This REU project will involve use of inorganic solution chemistry methods to synthesize novel metal-phosphide catalysts with a variety of structures.

These catalysts will be coupled to light absorbing copper-zinc-tin-sulfide nanocrystals to combine light harvesting and catalysis together in the same system. The corresponding surface chemistry and photocatalytic activity will be characterized by monitoring the evolution of hydrogen and oxygen gases. Search Site only in current section. List of types of available research projects.

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A List of unusual Chemistry Term Paper Topics. Chemistry papers can be challenging, not because of the topic, but because of choosing the topic. Most chemistry papers are written in a formulaic style, so whatever topic you write about will be written in the same way. Postgraduate research topics in Chemistry The list below shows the wide range of our postgraduate research in the School of Chemical Sciences. Use it as a source of inspiration if .