JACS所有25位副主编列表:
/page/jacsat/editors.html
Eric V. Anslyn: Supramolecular Analytical Chemistry, small molecule therapeutics
utexas.edu/research/sm.html
Stephen J. Lippard: bioinorganic chemistry. The core activities include both structural and mechanistic studies of macromolecules as well as synthetic inorganic chemistry. The focus is on the synthesis, reactions, physical and structural properties of metal complexes as models for the active sites of metalloproteins and as anti-cancer drugs. Also included is extensive structural and mechanistic work on the natural systems themselves. A program in metalloneurochemistry is also in place.
web.mit.edu/lippardlab/
Weston Thatcher Borden: Computational Chemistry; Organic Chemistry; Organometallic Chemistry; Application of quantitative electronic structure calculations and qualitative molecular orbital theory to the understanding and prediction of the structures and reactivities of organic and organometallic compounds.
chemistry.unt.edu/people-node/weston-t-borden
Thomas E. Mallouk: Chemistry of Nanoscale Inorganic Materials: Solar Photochemistry and Photoelectrochemistry; Nanowires; Functional Inorganic Layered Materials; In-Situ Remediation of Contaminants in Soil and Groundwater Using Nanoscale Reagents
research.chem.psu.edu/mallouk/
Benjamin F. Cravatt: Chemical Strategies for the Global Analysis of Enzyme Function; Technology Development: Activity-Based Protein Profiling (ABPP); Biological applications of ABPP - profiling enzyme activities in human cancer.; Advancing the ABPP technology; Technology Development: Protease Substrate Identification; Basic Discovery: The Enzymatic Regulation of Chemical Signaling
www.scripps.edu/cravatt/research.html
Chad A. Mirkin: He is a chemist and a world renowned nanoscience expert, who is known for his development of nanoparticle-based biodetection schemes, the invention of Dip-Pen Nanolithography, and contributions to supramolecular chemistry. Our research focuses on developing strategic and surface nano-optical methods for controlling the architecture of molecules and materials on a 1-100 nm scale. Our researchers, with backgrounds ranging from medicine, biology, chemistry, physics and material science, are working together in solving fundamental and applied problems of modern nanoscience. Research in the Mirkin laboratories is divided into the five areas listed below: Anisotropic Nanostructures; On-Wire Lithography (OWL); Dip-Pen Nanolithography; Organometallic Chemistry; Spherical Nucleic Acids
hwestern.edu/mirkin-group/research/
Paul Cremer: works at the crossroads of biological interfaces, metamaterials, spectroscopy, and microfluidics. Biophysical and analytical studies are tied togeth
er through the employment of novel lab-on-a-chip platforms which enable high throughput/low sample volume analysis to be performed with unprecedented signal-to-noise. From neurodegenerative diseases to artificial hip implants, a huge variety of processes occur at biological interfaces. Our laboratory uses a wide variety of surface specific spectroscopy and microfluidic technologies to probe mechanisms of disease, build new biosensors against pathogens, and understand the molecular-level details of the water layer hugging a cell membrane. Research projects in the Cremer Group are divided into the five areas listed below.  Click on your area(s) of interest to learn more. SFG of Water and Ions at Interfaces; Hofmeister Effects in Protein Solutions; Bioinorganic Chemistry and Biomaterial Properties of Lipid Bilayers; pH Modulation Sensing at Biomembranes; Metamaterials
sites.psu.edu/cremer/
Jeffrey S. Moore: Our research involves the synthesis and study of large organic molecules and the discovery of new polymeric materials. Most projects relate to one of thr
ee areas: new macromolecular architectures and their supramolecular organization; responsive polymers including self-healing materials; mechanochemical transduction. In general, our group uses the tools of synthetic and physical organic chemistry to address problems at the interface of chemistry and materials science. More in-depth information about our research can be found on our research page.
sulfur.scs.uiuc.edu/
Lyndon Emsley: NMR
s-lyon.sley/Lyndon_Emsley/Research.html
Klaus Müllen: The group pursues a broad program of experimental research in macromolecular chemistry and material science. It has a wide range of research interests: from new polymer-forming reactions including methods of organometallic chemistry, multi-dimensional polymers with complex shape-persistent architectures, molecular materials with liquid crystalline properties for electronic and optoelectronic devi
ces to the chemistry and physics of single molecules, nanocomposites or biosynthetic hybrids.
www2.mpip-mainz.mpg.de/groups/muellen
Jean M. J. Fréchet: Our research is largely concerned with functional polymers, from fundamental studies to applications. The research is highly multidisciplinary at the interface of several fields including organic, polymer, biological, and materials chemistry. Chemical Engineering is also well represented with our research in energy-related materials and microfluidics.
html主页hem.berkeley.edu/
Eiichi Nakamura: Fascination to learn about the nature of the elements and molecules and to control their behavior goes back to ancient times. The research programs in our laboratories focus on the development of new and efficient synthetic reactions, new reactive molecules, and new chemical principles that will exert impact on the future of che
mical, biological and material sciences. Under the specific projects listed below, we seek for the new paradigm of chemical synthesis and functional molecules. Discovery based on logical reasoning and imagination is the key term of our research and educational programs.

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