JAMES G. ANDERSON

 Philip S. Weld Professor of Atmospheric Chemistry
 Harvard School of Engineering and Applied Sciences
 Harvard University    
    B.S., 1966, Physics, University of Washington 
    Ph.D., 1970, Physics/Astrogeophysics, University of Colorado
Date：18th Oct. 2013 (Friday)
Time：15:00-16:00 pm
Venue：Room 301, Laodixue Building
Profile
James G. Anderson was born in Spokane, Washington. He earned his B.S. in Physics from the University of Washington and his PhD in Physics and Astrogeophysics from the University of Colorado. He joined the faculty of Harvard University in 1978 as the Robert P. Burden Professor of Atmospheric Chemistry; in 1982 he was appointed the Philip S. Weld Professor of Atmospheric Chemistry. Anderson served as Chairman of the Department of Chemistry and Chemical Biology from July 1998 through June 2001. He was elected to the National Academy of Sciences, the American Philosophical Society and the American Academy of Arts and Sciences, and a frequent contributor to National Research Council Reports. He is a Fellow of the American Geophysical Union and the American Association for the Advancement of Sciences Arthur L. Day Prize and Lectureship; the E.O. Lawrence Award in Environmental Science and Technology; the American Chemical Society’s Gustavus John Esselen Award for Chemistry in the Public Interest; and the University of Washington’s Arts and Sciences Distinguished Alumnus Achievement Award. In addition, he received the United Nations Vienna Convention Award for Protection of the Ozone Layer in 2005; The United Nations Earth Day International Award; Harvard University’s  Ledlie Prize for Most Valuable Contribution to Science by a Member of the Faculty; and the American Chemical Society’s National Award for Creative Advances in Environmental Science and Technology.
The Anderson research group addresses three domains in the physical sciences: (1) chemical reactivity viewed from the microscopic perspective of electron structure, molecular orbitals and reactivities of radical-radical and radical-molecule systems; (2) chemical catalysis sustained by free radical chain reactions that dictate the macroscopic rate of chemical transformation in Earth’s stratosphere and troposphere; and (3) mechanistic links between chemistry, radiation, and dynamics in the atmosphere that control climate