Piers Coleman

Last updated
Piers Coleman
Piers Coleman 2018.jpg
Coleman in 2018
Born1958 (age 6465)
Education Cheltenham Grammar School
Alma mater University of Cambridge
Princeton University
Known for Slave Boson, quantum criticality, Heavy Fermion superconductivity [1]
Scientific career
Fields Condensed matter theory
Institutions Rutgers University
Royal Holloway, University of London
Doctoral advisor Philip W. Anderson

Piers Coleman (born 1958)[ citation needed ] is a British-born theoretical physicist, working in the field of theoretical condensed matter physics. [2] Coleman is professor of physics at Rutgers University in New Jersey and at Royal Holloway, University of London.

Contents

Education and career

Coleman was raised in Cheltenham, England, where he attended Cheltenham Grammar School, graduating in 1976. He completed his undergraduate education at Trinity College, Cambridge, pursuing the Natural Sciences Tripos and the Mathematics Tripos part III under the mentorship of Gilbert Lonzarich. In 1980 he won a Jane Eliza Procter Fellowship to Princeton University where he studied theoretical condensed matter physics [3] with Philip Warren Anderson. Contemporaries in the Princeton graduate physics program included Gabriel Kotliar, Cumrun Vafa, Nathan Mhyrvold and Jennifer Chayes. He was awarded a Junior Research Fellowship at Trinity College, Cambridge, which he held from 1983 to 1988. He was a postdoctoral fellow at the Kavli Institute for Theoretical Physics Santa Barbara from 1984 to 1986. He joined the faculty at Rutgers University in 1987. Since 2010 he has also held the position of University of London Chair of Theoretical Condensed Matter Physics at Royal Holloway, University of London. In 2011, Piers Coleman replaced David Pines as a director of the Institute for Complex Adaptive Matter. [4]

Research

Coleman is known for his work related to strongly correlated electron systems, and in particular, the study of magnetism, superconductivity and topological insulators. He is the author of the popular text Introduction to Many-Body Physics.

In his early career at Princeton University Coleman worked on the problem of valence fluctuations in solids. In the 1960s the physicist John Hubbard introduced a mathematical operator, the "Hubbard operator" [5] for describing the restricted fluctuations in valence between two charge states of an ion. In 1983 Coleman invented the slave boson formulation of the Hubbard operators, [6] which involves the factorization of a Hubbard operator into a canonical fermion and a boson . The use of canonical fermions enabled the Hubbard operators to be treated within a field-theoretic approach, [7] allowing the first mean-field treatments of the heavy fermion problem. The slave boson approach has since been widely applied to strongly correlated electron systems, and has proven useful in developing the resonating valence bond theory (RVB) of high temperature superconductivity [8] [9] and the understanding of heavy fermion compounds. [10]

At Rutgers, he became interested in the interplay of magnetism with strong electron correlations. With Natan Andrei he adapted the resonating valence bond theory of high temperature superconductivity [8] to heavy fermion superconductivity. [11] In 1990 with Anatoly Larkin and Premi Chandra, they explored the effect of thermal and zero-point magnetic fluctuations on two dimensional frustrated Heisenberg magnets. [12] Conventional wisdom maintained that because of the Mermin–Wagner theorem, two dimensional Heisenberg magnets are unable to develop any form of long-range order. Chandra, Coleman and Larkin demonstrated that frustration can lead to a finite temperature Ising phase transition into a striped state with long range spin-nematic order. This kind of order is now known to develop in high temperature iron-based superconductors. [13]

Working with Alexei Tsvelik, Coleman carried out some of the earliest applications of Majorana Fermions to condensed matter problems. In 1992, Coleman, Miranda and Tsvelik examined the application of the Majorana representation of spins to the Kondo lattice, showing that if local moments fractionalize as Majorana, rather than Dirac fermions, the resulting ground-state is an odd-frequency superconductor. [14] [15] Working with Andrew Schofield and Alexei Tsvelik, they later advanced a model to account for the unusual magneto-resistance properties of high temperature superconductors in their normal state, in which the electrons fractionalize into Majorana fermions. [16]

In the late 1990s, Coleman became interested in the breakdown of Fermi liquid behavior at a quantum critical point. Working with Gabriel Aeppli and Hilbert von Löhneysen, they demonstrated established the presence of local quantum critical fluctuations in the quantum critical metal CeCu6-xAux, identified as a consequence of the break-down of the Kondo effect that accompanies the development of magnetism. [17] This led to the prediction that the Fermi surface will change discontinuously at a quantum critical point, [18] a result later observed in field tuned quantum criticality in the material YbRh2Si2 [19] and in pressure-tuned quantum criticality in the material CeRhIn5. [20]

After the discovery of topological insulators, Coleman became interested in whether topological insulating behavior could exist in materials with strong correlation. In 2008, the team of Maxim Dzero, Kai Sun and Victor Galitski and Piers Coleman predicted that the class of Kondo insulators can develop a topological ground-state, proposing samarium hexaboride (SmB6) as a Topological Kondo Insulator. [21] The observation of the development of robust conducting surface states in SmB6 is consistent with this early prediction. [22] [23]

Notable former research students and postdoctoral fellows in his group include Ian Ritchey, [24] Eduardo Miranda, [25] Andrew Schofield, Maxim Dzero, [26] Andriy Nevidomskyy [27] and Rebecca Flint [28]

Personal life

Piers Coleman is married to the American theoretical physicist Premala Chandra and they have two sons. He is the elder brother of musician and composer Jaz Coleman. [29]

Science outreach

Along with his younger brother Jaz, Coleman worked on a concert and physics outreach website Music of the Quantum. The concert has pieces composed by Jaz Coleman, based on themes from physics such as quantum criticality, emergence and symmetry breaking. They delivered performances of Music of the Quantum at the Bethlehem Chapel in Prague and at Columbia University in New York. [29] He has also produced a short documentary on Emergence with Paul Chaikin, as part of the Annenberg series Physics in the 21st Century. [30]

Awards and honors

Coleman was awarded a Sloan Fellowship in 1988. In 2002 he was elected a Fellow of the American Physical Society "for innovative approaches to the theory of strongly correlated electron systems". [31] In 2018 he was elected to the board of the Aspen Center for Physics. His research is supported by the National Science Foundation, Division of Materials Theory, and the Department of Energy, division of Basic Energy Sciences.

Books

See also

Related Research Articles

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Condensed matter physics is the field of physics that deals with the macroscopic and microscopic physical properties of matter, especially the solid and liquid phases which arise from electromagnetic forces between atoms. More generally, the subject deals with condensed phases of matter: systems of many constituents with strong interactions among them. More exotic condensed phases include the superconducting phase exhibited by certain materials at extremely low cryogenic temperature, the ferromagnetic and antiferromagnetic phases of spins on crystal lattices of atoms, and the Bose–Einstein condensate found in ultracold atomic systems. Condensed matter physicists seek to understand the behavior of these phases by experiments to measure various material properties, and by applying the physical laws of quantum mechanics, electromagnetism, statistical mechanics, and other physics theories to develop mathematical models.

<span class="mw-page-title-main">Kondo effect</span> Physical phenomenon due to impurities

In physics, the Kondo effect describes the scattering of conduction electrons in a metal due to magnetic impurities, resulting in a characteristic change i.e. a minimum in electrical resistivity with temperature. The cause of the effect was first explained by Jun Kondo, who applied third-order perturbation theory to the problem to account for scattering of s-orbital conduction electrons off d-orbital electrons localized at impurities. Kondo's calculation predicted that the scattering rate and the resulting part of the resistivity should increase logarithmically as the temperature approaches 0 K. Experiments in the 1960s by Myriam Sarachik at Bell Laboratories provided the first data that confirmed the Kondo effect. Extended to a lattice of magnetic impurities, the Kondo effect likely explains the formation of heavy fermions and Kondo insulators in intermetallic compounds, especially those involving rare earth elements such as cerium, praseodymium, and ytterbium, and actinide elements such as uranium. The Kondo effect has also been observed in quantum dot systems.

<span class="mw-page-title-main">Topological order</span> Type of order at absolute zero

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<span class="mw-page-title-main">Majorana fermion</span> Fermion that is its own antiparticle

A Majorana fermion, also referred to as a Majorana particle, is a fermion that is its own antiparticle. They were hypothesised by Ettore Majorana in 1937. The term is sometimes used in opposition to a Dirac fermion, which describes fermions that are not their own antiparticles.

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References

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  2. "Quantum Mechanical Triplet May Lead to Superconductivity at High Temperatures". Azonano. AZNanotechnology. 2008-07-22. Retrieved 31 January 2011.
  3. "Princeton University Graduate Alumni Index, 1839-1998".
  4. "Directors of the Institute for Complex Adaptive Matter (ICAM)".
  5. Hubbard, J. (1964). "Electron correlations in narrow energy bands. II. The degenerate band case". Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences. 277 (1369): 237–259. Bibcode:1964RSPSA.277..237H. doi:10.1098/rspa.1964.0019. S2CID   122573530.
  6. Coleman, Piers (1984). "A New Approach to the Mixed Valence Problem". Physical Review B. 29 (6): 3035–3044. Bibcode:1984PhRvB..29.3035C. doi:10.1103/PhysRevB.29.3035.
  7. Read, N.; Newns, D. M. (1983). "A new functional integral formalism for the degenerate Anderson model". Journal of Physics C: Solid State Physics. 16 (29): L1055–L1060. Bibcode:1983JPhC...16.1055R. doi:10.1088/0022-3719/16/29/007.
  8. 1 2 Anderson, P. W.; Baskaran, G.; Zou, Z.; Hsu, T. (1987). "Resonating–valence-bond theory of phase transitions and superconductivity in La2CuO4-based compounds". Physical Review Letters. 58 (26): 2790–2793. Bibcode:1987PhRvL..58.2790A. doi:10.1103/PhysRevLett.58.2790. PMID   10034850.
  9. Kotliar, Gabriel; Liu, Jialin (1988). "Superexchange mechanism and d-wave superconductivity". Physical Review B. 38 (7): 5142–5145. Bibcode:1988PhRvB..38.5142K. doi:10.1103/PhysRevB.38.5142. PMID   9946940.
  10. Millis, A. J.; Lee, P. A. (1986). "Large-orbital-degeneracy expansion for the lattice Anderson model". Physical Review B. 35 (7): 3394–3414. doi:10.1103/PhysRevB.35.3394. PMID   9941843.
  11. Coleman, P.; Andrei, N. (1989). "Kondo-stabilised spin liquids and heavy fermion superconductivity". Journal of Physics: Condensed Matter. The Institute of Physics. 1 (26): 4057–4080. Bibcode:1989JPCM....1.4057C. doi:10.1088/0953-8984/1/26/003.
  12. Chandra, P.; Coleman, P.; Larkin, A. I. (1990). "Ising Transition in Frustrated Heisenberg Models". Physical Review Letters. 64 (1): 88–91. Bibcode:1990PhRvL..64...88C. doi:10.1103/PhysRevLett.64.88. PMID   10041280.
  13. Xu, Cenke; Müller, Markus; Sachdev, Subir (2008). "Ising and spin orders in the iron-based superconductors". Physical Review B. 79 (2): 020501(R). arXiv: 0804.4293 . Bibcode:2008PhRvB..78b0501X. doi:10.1103/PhysRevB.78.020501. S2CID   6815720.
  14. Coleman, P.; Miranda, E.; Tsvelik, A. (1993). "Possible realization of odd-frequency pairing in heavy fermion compounds". Physical Review Letters. 70 (19): 2960–2963. arXiv: cond-mat/9302018 . Bibcode:1993PhRvL..70.2960C. doi:10.1103/PhysRevLett.70.2960. PMID   10053697. S2CID   17236854.
  15. Coleman, P.; Miranda, E.; Tsvelik, A. (1994). "Odd-frequency pairing in the Kondo lattice". Physical Review B. 49 (13): 8955–8982. arXiv: cond-mat/9305017 . Bibcode:1994PhRvB..49.8955C. doi:10.1103/PhysRevB.49.8955. PMID   10009677. S2CID   16281393.
  16. Coleman, P.; Schofield, A. J.; Tsvelik, A. M. (1996). "Phenomenological Transport Equation for the Cuprate Metals". Physical Review Letters. 76 (8): 1324–1327. arXiv: cond-mat/9602001 . Bibcode:1996PhRvL..76.1324C. doi:10.1103/PhysRevLett.76.1324. PMID   10061692. S2CID   44549797.
  17. Schröder, A.; Aeppli, G.; Coldea, R.; Adams, M.; Stockert, O.; Löhneysen, H.v.; Bucher, E.; Ramazashvili, R.; Coleman, P. (2000). "Onset of antiferromagnetism in heavy-fermion metals". Nature. 407 (6802): 351–355. arXiv: cond-mat/0011002 . Bibcode:2000Natur.407..351S. doi:10.1038/35030039. PMID   11014185. S2CID   4414169.
  18. Coleman, P.; Pépin, C.; Si, Qimiao; Ramazashvili, R. (2001). "How do Fermi liquids get heavy and die?". Journal of Physics: Condensed Matter. 13 (35): R723–R738. arXiv: cond-mat/0105006 . doi:10.1088/0953-8984/13/35/202. S2CID   15940806.
  19. Paschen, S.; Lühmann, T.; Wirth, S.; Gegenwart, P.; Trovarelli, O.; Geibel, C.; Steglich, F.; Coleman, P.; Si, Q. (2004). "Hall-effect evolution across a heavy-fermion quantum critical point". Nature. 432 (7019): 881–885. arXiv: cond-mat/0411074 . Bibcode:2004Natur.432..881P. doi:10.1038/nature03129. PMID   15602556. S2CID   4415212.
  20. Shishido, Hiroaki; Settai, Rikio; Harima, Hisatomo; Ōnuki, Yoshichika (2005). "A Drastic Change of the Fermi Surface at a Critical Pressure in CeRhIn 5: dHvA Study under Pressure". Journal of the Physical Society of Japan. 74 (4): 1103–1106. Bibcode:2005JPSJ...74.1103S. doi:10.1143/JPSJ.74.1103.
  21. Dzero, Maxim; Sun, Kai; Galitski, Victor; Coleman, Piers (2010). "Topological Kondo Insulators". Physical Review Letters. 104 (10): 106408. arXiv: 0912.3750 . Bibcode:2010PhRvL.104j6408D. doi:10.1103/PhysRevLett.104.106408. PMID   20366446. S2CID   119270507.
  22. Reich, Eugenie Samuel (2012). "Hopes surface for exotic insulator". Nature. 492 (7428): 165. Bibcode:2012Natur.492..165S. doi: 10.1038/492165a . PMID   23235853.
  23. Wolchover, Natalie (2 July 2015). "Paradoxical Crystal Baffles Physicists". Quanta Magazine.
  24. "Ian Ritchey - Royal Academy of Engineering".
  25. "About me". 6 January 2014.
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  27. "An9 | Physics and Astronomy | Rice University".
  28. "Rebecca Flint". Archived from the original on 2019-09-02. Retrieved 2022-07-15.
  29. 1 2 Tomlin, Sarah (2 September 2004). "Brothers in Art". Nature. 431 (7004): 14–16. doi: 10.1038/431014a . PMID   15343304. S2CID   4379887.
  30. Coleman, Piers; Chaikin, Paul (2010). "Emergent Behavior in Quantum Matter". Annenburg Learner.
  31. APS Fellows, 1995-present, American Physical Society. Accessed July 21, 2011