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American chemist From Wikipedia, the free encyclopedia
Sharon Hammes-Schiffer (born May 27, 1966) is a physical chemist who has contributed to theoretical and computational chemistry. She is currently a Sterling Professor of Chemistry at Yale University.[1] She has served as senior editor and deputy editor of the Journal of Physical Chemistry[2] and advisory editor for Theoretical Chemistry Accounts.[3] As of 1 January 2015[update] she is editor-in-chief of Chemical Reviews.[2]
Sharon Hammes-Schiffer | |
---|---|
Born | Sharon Hammes-Schiffer May 27, 1966 (age 58) |
Nationality | American |
Alma mater | Princeton University Stanford |
Known for | Computational chemistry |
Awards | National Academy of Sciences (2013) Willard Gibbs Award (2021) |
Scientific career | |
Fields | Chemistry Biophysical Chemistry Physical Chemistry Materials Chemistry |
Institutions | Yale University |
Website | http://www.hammes-schiffer-group.org/ |
Hammes-Schiffer studies "chemical reactions in solution, in proteins and at electrochemical interfaces, particularly the transfer of charged particles driving many chemical and biological processes."[4] Her research draws upon the areas of chemistry, physics, biology, and computer science and is significant for the fields of biochemistry, inorganic chemistry, physical chemistry and physical organic chemistry. A theoretician who works with computational models, Hammes-Schiffer blends classical molecular dynamics and quantum mechanics into theories that have direct relevance to a variety of experimental areas. In studying proton, electron and proton coupled electron transfer, Hammes-Schiffer has formulated a general theory of proton-coupled electron transfer reactions that explains the behavior of protons in energy conversion processes.[2][5][6] Her research has enhanced the understanding of hydrogen tunneling and protein motion in enzyme catalysis.[3][7] Her research group has also developed a nuclear-electronic orbital approach that allows scientists to incorporate nuclear quantum effects into electronic structure calculations.[7] Her work has application to a variety of experimental results and has implications for areas such as protein engineering, drug design,[8] catalyst of solar cells, and enzymatic reactions.[4] In 2024, she was elected to the American Philosophical Society.[9]
Hammes-Schiffer completed her B.A. in chemistry at Princeton University in 1988. She completed her Ph.D. in chemistry at Stanford University in 1993 after working with Hans C. Andersen.[10][2][3] She then worked with John C. Tully at AT&T Bell Laboratories as a postdoctoral research scientist.[3]
Hammes-Schiffer held positions on the faculty at the University of Notre Dame as Clare Boothe Luce Assistant Professor of Chemistry and Biochemistry (1995–2000) and at Pennsylvania State University (2000–2012).[3][11] In 2012 she joined the University of Illinois at Urbana-Champaign as Swanlund Professor of Chemistry,[8] where she remained until 2017.[12] Since then, she has led the Hammes-Schiffer Research Group at Yale University, where she was named John Gamble Kirkwood Professor of Chemistry in 2018, and Sterling Professor of Chemistry in 2021.[13] Starting January 2024, she will join the faculty at Princeton University.[14] Hammes-Schiffer is an author or co-author on nearly 200 papers, and has given more than 200 invited talks.[15]
Hammes-Schiffer's work delves primarily into three separate areas of chemistry: Proton-coupled electron transfer (PCET), Enzymatic Processes, and the Nuclear-Electronic Orbital method.[16] A sect of this research engages in the study of the Kinetic isotope effect, a difference in the reaction rate of a chemical based on what isotope is present.
The application of her work in PCET has elucidated the nature of various chemical mechanisms and led to her temperature dependence model of PCET rates.[17][18] One such process, Quinol Oxidation, studied the Kinetic isotope effect on Ubiquinol and Plastoquinol with regards to temperature, finding that the free energy of activation is greater for hydrogen than for deuterium, meaning the reaction is slower for hydrogen and therefore irreversible, if specific conditions are satisfied.[19] This finding has since been used by other investigators to reinforce the notion that reactions may or may not be unidirectional by influencing reaction rates with the kinetic isotope effect.[20] Additionally, her study of PCET in Iron Bi-imidazoline complexes has refined common comprehension of PCET, having proven her theory that electron transfer rate increases under the kinetic isotope effect as "the proton transfer distance increases and the electron transfer distance decreases."[21] These mechanisms have helped support the research of other PCET studies, with her main PCET paper, "Theoretical Studies of Proton-Coupled Electron Transfer Reactions",[17] having been cited over 90 times by papers ranging from studying protein motion to enzyme dynamics.[22]
Hammes-Schiffer studies the effects of quantum tunnelling and hydrogen bonding on enzymatic reactions. Her work on Soybean Lipoxygenase-1 changed common perception of a previously proposed tunneling region diagram,[23] finding that the temperature dependence of KIEs are inversely proportional to each other and that active environmental dynamics leads to less of the KIE and promotes catalysis.[24] This finding should be applicable to any other enzymes which can transfer a proton due to the fact that there aren't as many enzymatic options for non-ionic transfer of a proton and therefore tunneling must be used throughout the process.[24]
Hammes-Schiffer has also pioneered work in what she calls the Nuclear-electronic orbital method (NEO) which allows for a more accurate estimate of nuclear properties such as density, geometry, frequencies, electronic coupling, and nuclear motions.[25] As described in her paper, "Incorporation of Nuclear Quantum effects in electronic structure," Radial basis function kernel, a gaussian algorithm used to support vector machines, is applied to determine electronic and molecular orbitals. The NEO approach is specifically applicable in determining the exact mechanisms of hydrogen transfer reactions while accounting for other variables such as quantum tunneling and zero point energy. Hammes-Schiffer claims that the NEO approach is significantly advantageous over other methods that incorporate nuclear quantum effects because of the method's ability to calculate vibrational states, its avoidance of Born–Oppenheimer approximation and its apparent and inherent incorporation of quantum effects.[26]
In her study, published in September 2016, Hammes-Schiffer contributed towards discovering the effects of the active site of the magnesium ion in the Scissile Phosphate cofactor complex. She discovered that rather than the magnesium ion lying in the center of the complex, the ion lies in a separate site, termed the Hoogsteen Face, where it lowers the pKa of the complex in order to facilitate a deprotonation reaction necessary for a self-cleavage reaction.[27]
Hammes-Schiffer is a Fellow of the American Physical Society (2010), the American Chemical Society (2011), the American Academy of Arts and Sciences (2012), the American Association for the Advancement of Science (2013), the National Academy of Sciences (2013), and the Biophysical Society (2015).[10] She was elected as a member of the International Academy of Quantum Molecular Science in 2014.[4][6][7]
Hammes-Schiffer has received a number of awards, including the following:
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