Llewellyn Thomas
Llewellyn Hilleth Thomas | |
---|---|
Born | London, United Kingdom | 21 October 1903
Died | 20 April 1992 Raleigh, North Carolina, USA | (aged 88)
Known for | Thomas precession Thomas algorithm Thomas-Fermi model Thomas-Fermi screening Thomas-Fermi equation |
Awards | Smith's Prize (1925) |
Scientific career | |
Thesis | Contributions to the theory of the motion of electrified particles through matter and some effects of that motion (1927) |
Llewellyn Hilleth Thomas (21 October 1903 – 20 April 1992) was a British physicist and applied mathematician.[1] He is best known for his contributions to atomic and molecular physics and solid-state physics. His key achievements include calculating relativistic effects on the spin-orbit interaction in a hydrogen atom (Thomas precession), creating an approximate theory of -body quantum systems (Thomas-Fermi theory), and devising an efficient method for solving tridiagonal system of linear equations (Thomas algorithm).
Life and education
[edit]Born in London, he studied at Cambridge University, receiving his BA, PhD, and MA degrees in 1924, 1927 and 1928 respectively. While on a Traveling Fellowship for the academic year 1925–1926 at Bohr's Institute in Copenhagen, he proposed Thomas precession in 1926, to explain the difference between predictions made by spin-orbit coupling theory and experimental observations.
In 1929 he obtained a job as a professor of physics at the Ohio State University, where he stayed until 1943. He married Naomi Estelle Frech in 1933.[2] In 1935 he was the master's thesis advisor for Leonard Schiff, whose thesis was published with Thomas as coauthor.[3] From 1943 until 1945 Thomas worked on ballistics at the Aberdeen Proving Ground in Maryland. In 1946 he became a member of the staff of the Watson Scientific Computing Laboratory at Columbia University, remaining there until 1968. In 1958 he was elected as a member of the National Academy of Sciences. In 1963, Thomas was appointed as IBM's First Fellow in the Watson Research Center.[4] He was appointed professor at North Carolina State University in 1968, retiring from this position in 1976.[2] In 1982 he received the Davisson-Germer Prize.[5] He died in Raleigh, North Carolina.[2][6]
Contributions
[edit]Thomas was responsible for multiple advances in physics. The Thomas precession is a correction to the atomic spin-orbit interaction in quantum mechanics, which takes into account the relativistic time dilation between the electron and the atomic nucleus. The Thomas–Fermi model is a statistical model for electron-ion interactions, which later formed the basis of density functional theory. The Thomas collapse is effect in few-body physics, which corresponds to infinite value of the three body binding energy for zero-range potentials.
In mathematics, his name is frequently attached to an efficient Gaussian elimination method for tridiagonal matrices—the Thomas algorithm.
Notable publications
[edit]- Thomas L. H. The motion of the spinning electron // Nature. — 1926. — Vol. 117. — P. 514. — doi:10.1038/117514a0.
- Thomas L. H. The calculation of atomic fields // Mathematical Proceedings of the Cambridge Philosophical Society. — 1927. — Vol. 23. — P. 542–548. — doi:10.1017/S0305004100011683.
- Thomas L. H. The kinematics of an electron with an axis // Philosophical Magazine. — 1927. — Vol. 3. — P. 1—22. — doi:10.1080/14786440108564170.
- Thomas L. H. Radiation field in a fluid in motion // Quarterly Journal of Mathematics. — 1930. — Vol. 1. — P. 239–251. — doi:10.1093/qmath/os-1.1.239.
- Thomas L. H. The interaction between a neutron and a proton and the structure of H3 // Physical Review. — 1935. — Vol. 47. — P. 903–909. — doi:10.1103/PhysRev.47.903.
- Thomas L. H. The paths of ions in the cyclotron I. Orbits in the magnetic field // Physical Review. — 1938. — Vol. 54. — P. 580–588. — doi:10.1103/PhysRev.54.580.
- Shaffer W. H., Nielsen H. H., Thomas L. H. The rotation-vibration energies of tetrahedrally symmetric pentatomic molecules. I // Physical Review. — 1939. — Vol. 56. — P. 895–907. — doi:10.1103/PhysRev.56.895.
- Thomas L. H. A Practical Method for the Solution of Certain Problems in Quantum Mechanics by Successive Removal of Terms from the Hamiltonian by Contact Transformations of the Dynamical Variables Part I. General Theory // Journal of Chemical Physics. — 1942. — Vol. 10. — P. 532–537. — doi:10.1063/1.1723760.
- Thomas L. H. Note on Becker's Theory of the Shock Front // Journal of Chemical Physics. — 1944. — Vol. 12. — P. 449–453. — doi:10.1063/1.1723889.
- Sheldon J., Thomas L. H. The use of large scale computing in physics // Journal of Applied Physics. — 1953. — Vol. 24. — P. 235–242. — doi:10.1063/1.1721257.
- Thomas L. H. The stability of plane Poiseuille flow // Physical Review. — 1953. — Vol. 91. — P. 780–783. — doi:10.1103/PhysRev.91.780.
- Bakamjian B., Thomas L. H. Relativistic particle dynamics. II // Physical Review. — 1953. — Vol. 92. — P. 1300–1310. — doi:10.1103/PhysRev.92.1300.
- Thomas L. H. Satellite Countermeasures // Time. — 1954, May 3.
- Thomas L. H., Umeda K. Atomic Scattering Factors Calculated from the TFD Atomic Model // Journal of Chemical Physics. — 1957. — Vol. 26. — P. 293–303. — doi:10.1063/1.1743287.
Gallery
[edit]- Yoshio Nishina, Thomas, and Friedrich Hund in Copenhagen in 1926
- Thomas in Copenhagen in 1963
See also
[edit]References
[edit]- ^ Price, Peter J. (September 1994). "Obituary: Llewellyn H. Thomas". Physics Today. 47 (9): 115–116. doi:10.1063/1.2808649.
- ^ a b c Jackson, John David (2009). "Llewellyn Hilleth Thomas 1903 — 1992" (PDF). Biographical Memoirs. Washington, D.C.: National Academy of Sciences. Archived from the original (PDF) on 4 March 2016. Retrieved 9 August 2014.
- ^ Bloch, Felix (1983), "LEONARD ISAAC SCHIFF", Biographical Memoirs, vol. 54, Washington, D.C.: National Academy Press, pp. 300–323, ISBN 0-309-03391-8
- ^ "IBM - IBM Fellows". www.ibm.com. 30 January 2012.
- ^ "Llewellyn Thomas, Array of Contermporary American Physicists".
- ^ Jackson, John David (14 February 2010). "Llewellyn Hilleth Thomas 1903 – 1992" (PDF).