Tin-Lun Ho Explained

Tin-Lun "Jason" Ho (born August 12, 1951) is a Chinese-American theoretical physicist, specializing in condensed matter theory, quantum gases, and Bose-Einstein condensates.^[1] He is known for the Mermin-Ho relation.^[2]

Education and career

Ho graduated in 1972 with a B.Sc. from Chung Chi College, Chinese University of Hong Kong. He was a graduate student for the academic year 1972–1973 at the University of Minnesota and in 1973 transferred to Cornell University. There he graduated in 1977 with a Ph.D. under the supervision of N. David Mermin.^{[3] [4]} Ho was a postdoc from 1977 to 1980 under the supervision of Christopher J. Pethick at the University of Illinois, from 1978 to 1980 at NORDITA, and from 1980 to 1982 at the Kavli Institute for Theoretical Physics at the University of California, Santa Barbara.^[5] At Ohio State University (OSU), he was an assistant professor from 1983 to 1989 and an associate professor from 1989 to 1996, when he became a full professor. At OSU he is since 2002 a Distinguished Professor of Mathematical and Physical Sciences.^[3] From 2007 to 2014 he was a member of the editorial board of the Journal of Low Temperature Physics.^[5]

Ho was an Alfred P. Sloan Foundation Fellow for the academic year 1984–1985^[5] and a Fellow of the John Simon Guggenheim Memorial Foundation for the academic year 1999–2000.^[6]

In 2008 he received the Lars Onsager Prize for "his contributions to quantum liquids and dilute quantum gases, both multi-component and rapidly rotating, and for his leadership in unifying condensed matter and atomic physics research in this area."^[3]

Ho was elected in 1999 a Fellow the American Physical Society,^[7] in 2011 a Fellow of the American Association for the Advancement of Science,^[8] and in 2015 a Member of the American Academy of Arts and Sciences.^[9]

Most recently, he has been working on Bose-Einstein condensatess and optical lattices, for which he proposed a cooling mechanism in 2009.^[10]

Selected publications

• 10.1103/PhysRevLett.77.3276. Binary Mixtures of Bose Condensates of Alkali Atoms. 1996. Ho. Tin-Lun. Shenoy. Vivek B.. Physical Review Letters. 77. 16. 3276–3279. 10062180. 1996PhRvL..77.3276H. (over 650 citations)
• 10.1103/PhysRevLett.81.742. Spinor Bose Condensates in Optical Traps. 1998. Ho. Tin-Lun. Physical Review Letters. 81. 4. 742–745. cond-mat/9803231. 1998PhRvL..81..742H. 18956040. (over 1750 citations)
• 10.1103/PhysRevA.61.033607. Phase diagrams of F=2 spinor Bose-Einstein condensates. 2000. Ciobanu. C. V.. Yip. S.-K.. Ho. Tin-Lun. Physical Review A. 61. 3. 033607. cond-mat/9908018. 2000PhRvA..61c3607C. 13881807.
• 10.1103/PhysRevLett.84.4031. Fragmented and Single Condensate Ground States of Spin-1 Bose Gas. 2000. Ho. Tin-Lun. Yip. Sung Kit. Physical Review Letters. 84. 18. 4031–4034. 10990603. cond-mat/9905339. 2000PhRvL..84.4031H. 29387943.
• 10.1103/PhysRevLett.87.060403. Bose-Einstein Condensates with Large Number of Vortices. 2001. Ho. Tin-Lun. Physical Review Letters. 87. 6. 060403. 11497818. cond-mat/0104522. 2001PhRvL..87f0403H. 7933125.
• 10.1103/PhysRevLett.88.180403. Two-Component Bose-Einstein Condensates with a Large Number of Vortices. 2002. Mueller. Erich J.. Ho. Tin-Lun. Physical Review Letters. 88. 18. 180403. 12005671. cond-mat/0201051. 2002PhRvL..88r0403M. 1388421.
• 10.1103/PhysRevLett.92.090402. Universal Thermodynamics of Degenerate Quantum Gases in the Unitarity Limit. 2004. Ho. Tin-Lun. Physical Review Letters. 92. 9. 090402. 15089456. cond-mat/0309109. 2004PhRvL..92i0402H. 30208714. (over 550 citations)
• 10.1103/PhysRevLett.92.160404. High Temperature Expansion Applied to Fermions near Feshbach Resonance. 2004. Ho. Tin-Lun. Mueller. Erich J.. Physical Review Letters. 92. 16. 160404. 15169207. cond-mat/0306187. 2004PhRvL..92p0404H. 19270421.
• 10.1103/PhysRevA.74.033612. Fragmentation of Bose-Einstein condensates. 2006. Mueller. Erich J.. Ho. Tin-Lun. Ueda. Masahito. Baym. Gordon. Gordon Baym. Physical Review A. 74. 3. 033612. cond-mat/0605711. 2006PhRvA..74c3612M. 119385837.
• 10.1038/nphys1477. Obtaining the phase diagram and thermodynamic quantities of bulk systems from the densities of trapped gases. 2010. Ho. Tin-Lun. Zhou. Qi. Nature Physics. 6. 2. 131–134. 2010NatPh...6..131H. 118417606. 0901.0018.
• 10.1103/PhysRevLett.107.150403. Bose-Einstein Condensates with Spin-Orbit Interaction. 2011. Ho. Tin-Lun. Zhang. Shizhong. Physical Review Letters. 107. 15. 150403. 22107273. 2011PhRvL.107o0403H. free.
• 10.1073/pnas.2004268117. Imaging the Holon string of the Hubbard model. 2020. Ho. Tin-Lun. Proceedings of the National Academy of Sciences. 117. 42. 26141–26144. 33020280. 7584989. 2020PNAS..11726141H. free. (See Hubbard model.)

References

1. Web site: Prof. Tin-Lun (Jason) Ho. Department of Physics, The Ohio State University.
2. Mermin, N. D.. Ho, T. L.. March 1976. Circulation and angular momentum in the A phase of superfluid Helium-3. Physical Review Letters. 36. 11. 594–597. 10.1103/PhysRevLett.36.594. (This article has over 500 citations.)
3. Web site: Tin-Lun Ho. 2008 Lars Onsager Prize Recipient, American Physical Society.
4. Web site: Tin-Lun Ho. Physics Tree.
5. Web site: Tin-Lun Ho, Curriculum Vita. Physics Department, Ohio State University.
6. Web site: Tin-Lun Ho. John Simon Guggenheim Memorial Foundation.
7. Web site: APS Fellow Archive. American Physical Society.
8. Web site: Physics Professors named AAAS Fellows. December 8, 2011. Department of Physics, Ohio State University.
9. Web site: Member Directory, election year 2015, Ohio State University. American Academy of Arts & Sciences.
10. Ho, Tin-Lun. Zhou, Qi. Squeezing out the entropy of fermions in optical lattices. Proceedings of the National Academy of Sciences. 106. 17. 2009. 6916-6920. 10.1073/pnas.0809862105. 2678422.
11. ^[10]

External links

• Web site: Tin-Lun (Jason) Ho. October 17, 2018. ITAMP Physics.

  lecture entitled "Signature of spin, charge, and pairing correlation in fermions in optical lattices from thermodynamic and density measurements"

  . YouTube.