P. R. Wallace

P. R. (Philip Russell; "Phil") Wallace (April 19, 1915 – March 20, 2006) was a Canadian theoretical physicist and long-time professor at McGill University. He was a Fellow of the Royal Society of Canada and Fellow of the National Academy of Sciences (India). He had a distinguished career as educator, researcher, and activist in science and society, but he is increasingly well known for his pioneering paper [1] in 1947 on the band structure of graphite, and particularly graphene,[2] the subject of the 2010 Nobel Prize in Physics.

P. R. Wallace
Born(1915-04-19)April 19, 1915
Toronto, Ontario, Canada
DiedMarch 20, 2006(2006-03-20) (aged 90)
NationalityCanadian
Alma materUniversity of Toronto
Scientific career
FieldsTheoretical physics
InstitutionsUniversity of Cincinnati
MIT
NRC (Can)
McGill University
Université Paul Sabatier, Toulouse, France
Concordia University
Doctoral advisorLeopold Infeld

Early and wartime years

Born in Toronto in 1915, Wallace entered the University of Toronto in 1933, achieving a B.A. in mathematics in 1937, an M.A. in 1938, and a Ph.D. in applied mathematics in 1940 under Leopold Infeld with a thesis on electromagnetism in general relativity.[3] Advised by L. J. Synge, then head of the Applied Mathematics Department at Toronto, to hold himself ready for war work in Canada, Wallace took a two-year job at the University of Cincinnati and then moved to a lectureship at MIT. In 1943 he was recruited to join the British-Canadian Atomic Energy Project at the National Research Council of Canada's Montreal Laboratory. From 1943 to 1946 Wallace worked as one of an impressive group of theorists and mathematicians led by George Placzek on nuclear reactor fundamentals, including study of the effects on graphite and other materials of intense neutron and ion bombardment.[4] His assignment to visit N. F. Mott in Bristol, England for several months to learn what was known about graphite led Wallace to a lifelong interest in graphite and a career in condensed matter physics, not least his 1947 paper on the band structure of graphite.[1]

Academic and professional career

From mathematics to physics

When the Montreal effort moved to the Chalk River site in 1946, Wallace joined the Mathematics Department at McGill University and began to build a group of young theoretical physicists there. The anomaly, at least in North America, of theoretical physicists in the Math department, not in Physics, had historic roots at McGill, dating from Ernest Rutherford's time. More generally, Canadian universities followed the British model of separation of mathematics from physics, perhaps deigning to have a small separate department of applied mathematics. Rutherford's strongly expressed views solidified things at McGill for 50 years. But by the early 1960s circumstances had changed; Wallace and his group moved into the Physics Department. He has documented the post-war story of the growth of a tiny number of isolated theoretical physicists in Canada, basically "outsiders," into a viable community of "insiders," not only at McGill.[5]

Research

Initially working in nuclear physics and properties of graphite, in the mid-1950s Wallace turned his attention to the newly discovered positron annihilation in solids and liquids. In 1960 he published what became a standard reference in the field.[6] His later research focused on semiconductors and semimetals, particularly their behaviour under intense magnetic fields, with regular returns to properties of graphite. In addition to summer school proceedings, in 1969 he edited two volumes on superconductivity [7] and in 1973 he co-edited a volume on new developments in semiconductors.[8]

Teaching and mentoring

Wallace was a superb lecturer and mentor of students. His undergraduate course in methods of mathematical physics was inspirational. It allowed many students to see what a disciplined and well-trained mind could accomplish by applying mathematics to physical problems. More than a few careers were encouraged on their paths by Wallace's course. A text based on his notes was finally published in 1973.[9] Over his career at McGill Wallace supervised over 30 graduate students to M.Sc. and Ph.D. degrees, more than one third of them Ph.D.s.

Professional activities

Wallace was active in professional affairs, a co-founder of the Canadian Association of Physicists and founder and first chair of its Theoretical Physics Division, 1957–58. He served as Editor of the Canadian Journal of Physics, 1973–80, and on numerous advisory and planning committees for conferences. At McGill he was Director of the Institute of Theoretical Physics, 1966–70, and active in faculty and university affairs.

Retirement

Retiring as Professor Emeritus in Physics in 1982, Wallace soon became Principal of the Science College, Concordia University in Montreal, 1984–1987. In the 1990s he began writing semi-popular books explaining physics to the layperson, "Physics: Imagination and Reality"[10] and "Paradox Lost: Images of the Quantum".[11] He died on March 20, 2006 in Victoria, British Columbia of complications of old age.

Obituaries appear in Physics in Canada[12] and Physics Today.[13]

gollark: Yes, there is (I don't think it's fully reliable though), but they shouldn't be doing it in the first place.
gollark: They literally added code to their drivers to make consumer cards' drivers not function in VMs, so that people would have to buy more expensive cards for no good reason.
gollark: Well, thanks to AMD being less evil, on Linux the drivers are just built into the kernel or something and work with basically no hassle.
gollark: Nvidia's drivers are worse. They try and push you into this "GeForce Experience" thing or something, work poorly on Linux, and deliberately don't work in VMs because Nvidia is Nvidia.
gollark: Better in what way?

References

  1. Wallace, P. R. (1947). "The Band Theory of Graphite". Physical Review. 71 (9): 622–634. Bibcode:1947PhRv...71..622W. doi:10.1103/PhysRev.71.622.
  2. Geim, A. K. and Novoselov, K. S. (2007). "The Rise of Graphene". Nature Materials. 6 (3): 183–191. arXiv:cond-mat/0702595. Bibcode:2007NatMa...6..183G. doi:10.1038/nmat1849. PMID 17330084.CS1 maint: uses authors parameter (link)
  3. Philip Russell Wallace at the Mathematics Genealogy Project
  4. Wallace, P. R. (2000). "Atomic Energy in Canada:Personal Recollections of the Wartime Years". Physics in Canada. Mar/Apr 2000: 123–131.
  5. Wallace, P. R. (1993). "The beginnings of theoretical physics in Canada". Physics in Canada. Nov 1993: 358–364.
  6. Wallace, P. R. (1960). "Positron Annihilation in Solids and Liquids". Solid State Physics. 10: 1–69. doi:10.1016/S0081-1947(08)60700-6. ISBN 9780126077100.
  7. Wallace, P. R., ed. (1969). Superconductivity (2 vols.). New York: Gordon and Breach.CS1 maint: multiple names: authors list (link) CS1 maint: extra text: authors list (link)
  8. Harris, R., Wallace, P. R., and Zuckermann, M. J., eds. (1973). New Developments in Semiconductors. Leyden: Nordhoff International Publishing.CS1 maint: uses authors parameter (link)
  9. Wallace, P. R. (1984) [1972]. Mathematical Analysis of Physical Problems. New York: Holt, Rinehart and Winston.
  10. Wallace, P. R. (1991). Physics: Imagination and Reality. Singapore: World Scientific.
  11. Wallace, P. R. (1996). Paradox Lost: Images of the Quantum. New York: Springer.
  12. Joós, Béla (2006). "In Memoriam: Philip Russell Wallace, 1915–2006". Physics in Canada. July/August 2006: 134.
  13. Gottfried, K., Jackson, J. D., and Lam, H. C. S. (Sep 2006). "Philip Russell Wallace". Physics Today. 59 (9): 78. Bibcode:2006PhT....59i..78G. doi:10.1063/1.2364256.CS1 maint: multiple names: authors list (link)
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.