Graham Fleming

Graham R. Fleming (born 1949) is a British born chemist, currently serving as professor at the University of California, Berkeley.[1]

Career

Fleming received a B.S. (with honors) degree in Chemistry from the University of Bristol (1971) and a Ph.D. degree in Physical Chemistry from the University College London (1974). He spent the next five years as a postdoctoral researcher at three institutions: California Institute of Technology (1974–1975); University of Melbourne (1975–1976); and the Royal Institution in the United Kingdom (1976–1979).

In 1979 Fleming received his first academic appointment, as assistant professor at University of Chicago (1979–1983). In 1983 he was appointed associate professor, and in 1985 he was made a full professor (A. H. Compton Distinguished Services Professor). He filled that position until 1997, when he accepted a dual position at the University of California, Berkeley as professor in Chemistry and as the first director of the Physical Bioscience Division of the Lawrence Berkeley National Laboratory; in 2002 he was given the chair of Melvin Calvin Distinguished Professor of Chemistry at UCB. In April, 2009, Fleming was appointed UCB's vice chancellor for research, responsible for administering all federal, state and private research funds received by the campus and overseeing all campus museums and research units.[2] He resigned under protest [3] from this position following accusations of sexual harassment by a previously fired UCB employee.[4] Many UCB faculty members questioned the fairness of UCB's investigation,[5] which provided no mechanism for appeal.[6]

Fields of study pursued by Fleming and his study groups include condensed-phase chemical and biological dynamics, photosynthesis operations, quantum dynamics, quantum information in condensed phases, photochemical reactions, electronic processes at nanoscale, and development of nonlinear optical spectroscopes.

He was the first to apply two-dimensional electronic spectroscopy to photosynthetic systems. He got particularly known for the work published in 2007 claiming evidence for quantum coherence in photosynthetic energy transfer,[7] an explanation of the high efficiency of photosynthesis.[8] This interpretation of the observed spectra has since been proven incorrect.[9] [10] [11] [12][13] [14]

Significant publications

Awards and honors[15]

References

  1. UC Berkeley website
  2. UC Berkeley press release
  3. The Daily Californian, April 13, 2015
  4. The Daily Californian, May 4, 2012
  5. The Daily Californian, April 20, 2015
  6. Chemical & Engineering News, 93(16), April 17, 2015
  7. G. S. Engel; T. R. Calhoun; E. L. Read; T. K. Ahn; T. Mancal; Y. C. Cheng; R. E. Blankenship; G. R. Fleming (2007). "Evidence for wavelike energy transfer through quantum coherence in photosynthetic system". Nature. 446: 782. doi:10.1038/nature05678.
  8. Quantum secrets of photosynthesis revealed, April 12, 2007, physorg.com (retrieved June 4, 2011)
  9. R. Tempelaar; T. L. C. Jansen; J. Knoester (2014). "Vibrational Beatings Conceal Evidence of Electronic Coherence in the FMO Light-Harvesting Complex". J. Phys. Chem. B. 118: 12865–12872. doi:10.1021/jp510074q.
  10. N. Christenson; H. F. Kauffmann; T. Pullerits; T. Mancal (2012). "Origin of Long-Lived Coherences in Light-Harvesting Complexes". J. Phys. Chem. B. 116: 7449–7454.
  11. E. Thyrhaug; K. Zidek; J. Dostal; D. Bina; D. Zigmantas (2016). "Exciton Structure and Energy Transfer in the Fenna−Matthews− Olson Complex". J. Phys. Chem. Lett. 7: 1653–1660. doi:10.1021/acs.jpclett.6b00534.
  12. A. G. Dijkstra; Y. Tanimura (2012). "The role of the environment time scale in light-harvesting efficiency and coherent oscillations". New J. Phys. 14: 073027. doi:10.1088/1367-2630/14/7/073027.
  13. D. M. Monahan; L. Whaley-Mayda; A. Ishizaki; G. R. Fleming (2015). "Influence of weak vibrational-electronic couplings on 2D electronic spectra and inter-site coherence in weakly coupled photosynthetic complexes". J. Chem. Phys. 143: 065101. doi:10.1063/1.4928068.
  14. Halpin, A.; Johnson, P.J.M.; Tempelaar, R.; Murphy, R.S.; Knoester, J.; Jansen, T.L.C.; Miller, R.J.D. (2014). "Two-Dimensional Spectroscopy of a Molecular Dimer Unveils the Effects of Vibronic Coupling on Exciton Coherences". Nature Chemistry. 6: 196–201. doi:10.1038/nchem.1834.
  15. UC Berkeley website
  16. The Fleming Group at UC Berkeley webpage
  17. Chemical & Engineering News, 23 February 2009, "2009 ACS National Award Winners", pp. 64-65
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