MY NOBEL FRIEND

1. MY NOBEL FRIEND

2. Rudolph A. Marcus 1992 Nobel Laureate in Chemistry

3. OUTLINE CHILDHOOD • EDUCATION • WORLD OF SCIENTIFIC DISCOVERIES • HIS CLAIM TO FAME • CURRENT RESEARCH • PUBLICATIONS • IMPORTANT CONTRIBUTIONS • ACADEMIC POSITION • FAMILY

4. Childhood of Marcus • The only son of Myer and Esther Cohen Marcus • Born on July 21, 1923 (Montreal, Canada) • Admired his father’s athletic prowess • Admired his mother’s expressive singing and piano playing • His two paternal uncles were his academic “idols”

5. Education • His interest in the sciences started with mathematics. • Fascinated with chemistry in early high school because of the “proverbial home chemistry set”.

6. Education • 1941- He attended McGill University. • Marcus majored in Chemistry- the field which he felt “most comfortable”. • He took a number of math courses, more than other students in chemistry. • At McGill, he found the course in kinetics “intriguing”.

7. “I always loved school. It was natural to go on to graduate school. It wasn’t though I was going to make terrific discoveries. That didn't play any part” --R.A.M

8. Education • 1943- He received his Bachelor of Science degree. • He specialized in the rates of chemical reactions. • 1946- He received his Ph.D at the age of 22.

9. World of Chemistry • At the NRC, he did experimental work under E.W.R. Steacie on free-radical reactions. • 1949-1951- He obtained a postdoctoral position with Oscar K. Rice at University of North Carolina. • As a beginning of his theoretical work, he examined unimolecular reactions. • Marcus concentrated on the RRK (Rice-Ramsperger-Kassel) theory proposed in the 1920s, before quantum mechanics. • 1952- “putting little pieces together”, RRK eventually became known as the RRKM (Rice-Ramsperger-Kassel-Marcus) theory.

10. RRKM (Rice-Ramsperger-Kassel-Marcus) theory • This method enables the computation of simple estimates of the unimolecular reaction rates from a few characteristics of the potential energy surface.

11. World of Chemistry • He got no positive responses to 35 letters of inquiry for a faculty position. • 1951- he managed to secure a position at the Polytechnic Institute of Brooklyn. • Due to lack of experimental data in unimolecular reactions, he temporarily leave the theoretical area and return to doing experiments and calculations. • 1952- he happened to chance on a symposium journal issue on electron-transfer reactions and was drawn to an electrostatic calculation by W.F. Libby to explain the small rate constants.

12. World of Chemistry • He sensed that something was wrong with Libby’s calculation, although unsure what the error was. • He recognized that Libby’s calculation was not appropriate for thermal electron transfers • He then found a way to calculate the free energy of the ions in solution as a function of a nonequilibrium dielecric polarization. • In an intense period of activity for nine years, he formed the basis of what became the “MARCUS THEORY”.

13. Marcus theory • To explain the rates of electron transfer reactions- the rate at which an electron can move or jump from one chemical species (electron donor) to another (electron acceptor).

14. World of Chemistry • 1960- Marcus felt he needed to commit his time completely to theoretical work. • 1964- He moved to the University of Illinois and concentrated his interest in electron-transfer and reaction dynamics. • 1975-1976- He is a visiting professor at Oxford and Munich - He explored the electron transfer in photosynthesis • 1978- He accepted an offer from the California Institute of Technology (Caltech)

15. Claim to Fame: • awarded the 1992 Nobel Prize in Chemistry “for his development of electron transfer theory during chemical reactions”. • His theory describes the thermodynamics and kinetics of how electron donor chemicals transfer electrons to electron acceptor chemicals during a reaction. • This theory helps explain reactions like oxidation, photosynthesis and cell metabolism.

16. Current Research • “on-water” catalysis of organic reactions and the fluorescent intermittency of semiconductor nanoparticles (quantum dots) • mass-independent isotopic fractionation in the formation of ozone and other stratospheric gases • photolysis of the greenhouse gas N2O and the CO + OH reaction

17. Publications • author of approximately 320 scientific articles • Co-editor of Tunneling in Biological Systems (1979) • Co-editor of Intramolecular Motion and Chemical Reaction (1990)

18. Important Contributions • Theory of electron transfer reactions in solution • Theory of unimolecular reactions (RRKM theory) • Theory of ET reactions at electrodes and other interfaces • Semi classical theory of bound states • Semi classical theory of collisions • Reaction coordinates and Hamiltonians • Theory of product state distributions of unimolecular processes • Tunneling paths in chemical reactions

19. Academic Position • Arthur Amos Noyes Professor of Chemistry, Caltech (1978-)

20. Family of Marcus Wife: Laura Hearne (deceased in 2003) Sons: Alan, Kenneth, and Raymond

21. “ Your theory is a unifying factor in chemistry, promoting understanding of electron transfer reactions of biochemical, photochemical, inorganic and organic nature and thereby contributing to science as a whole. It has led to the development of many new research programs, demonstrating the lasting impact of your work. ” ---Royal Swedish Academy of Sciences

22. Thank you forlistening.