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William A. Bardeen

From Wikipedia, the free encyclopedia
William A. Bardeen
Born (1941-09-15) September 15, 1941 (age 83)
Washington, Pennsylvania
NationalityAmerican
Alma materCornell University
University of Minnesota
Known forChiral anomaly; Quantum Chromodynamics; Top quark condensate; Chiral symmetry breaking.
Scientific career
InstitutionsStony Brook University, Stanford University, Institute for Advanced Study, Fermilab
Doctoral advisorStephen Gasiorowicz

William Allan Bardeen (born September 15, 1941, in Washington, Pennsylvania) is an American theoretical physicist who worked at the Fermi National Accelerator Laboratory. He is renowned for his foundational work on the chiral anomaly (the Adler-Bardeen theorem), the Yang-Mills and gravitational anomalies, the development of quantum chromodynamics and the scheme frequently used in perturbative analysis of experimentally observable processes such as deep inelastic scattering, high energy collisions and flavor changing processes.

He also played a major role in developing a theory of dynamical breaking of electroweak symmetry via top quark condensates, leading to the first composite Higgs models. His work on the chiral symmetry breaking dynamics of heavy-light quark bound states correctly predicted abnormally long-lived resonances which are chiral symmetry partners of the ground states, such as the . He also developed an analytic, non-perturbative approach for the calculation of non-leptonic decays of Kaons, known as Dual QCD.

Bardeen is considered one of the world's leading authorities on quantum field theory in its application to real-world physical phenomena.

Biography and Family

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After graduating from Cornell University in 1962, Bardeen earned his Ph.D. degree in physics from the University of Minnesota in 1968. Following research appointments at Stony Brook University and the Institute for Advanced Study in Princeton, he was an Associate Professor in the physics department at Stanford University. In 1975, Bardeen joined the staff of the Fermi National Accelerator Laboratory where he has served as Head of the Theoretical Physics Department from 1987-1993 and 1994-1996.[1] From 1993-1994, he was Head of Theoretical Physics at the SSC Laboratory before the project was terminated by act of Congress.

Bardeen lives in Warrenville, Illinois, with his wife Marge, who was manager of the Education Department at Fermilab.[2] He has two grown children: Charles a retired Project Scientist at the National Center for Atmospheric Research, Boulder, CO, and Karen, who taught chemistry at Oak Park and River Forest High School, Oak Park, Illinois. He is the son of physicist John Bardeen[3] and Jane Maxwell Bardeen.

Scientific Contributions

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Bardeen is co-inventor of the theory of the chiral anomaly, which is of foundational importance in modern theoretical physics. He developed with Stephen L. Adler the "non-renormalization theorem" (known as the Adler–Bardeen theorem).[4] This proves that the anomaly coefficient is not subject to renormalization to all orders in perturbation theory and anticipates the fact that it is associated with topological index theorems.

Bardeen, in a tour de force, computed the full, nontrivial structure of the chiral anomaly in non-abelian Yang-Mills gauge theories.[5] This leads to the distinction between the "consistent anomaly" and the "covariant anomaly." The consistent anomaly is a definition of the loop integrals that satisfies "Wess-Zumino consistency conditions"[6] and is symmetric between left- and right-handed chiral fermions in the Feynman loop. The consistent anomaly is generally related to topology, e.g., the structure and coefficient obtained by Bardeen's calculation turns out to be equivalent to that generated by a topological Chern-Simons term built of Yang-Mills fields in 5 dimensions.

In this work he introduced the "Bardeen counter-term" which maintains the conservation of the vector current in the definition of the loop integral, and places the anomaly in the axial current. This is known as the "covariant anomaly," and is relevant to physics where the vector current is conserved (and reverts to the Adler result in QED with coefficient increased by a factor of 3 over that of the consistent anomaly).[7] These distinctions are crucial to the Wess-Zumino-Witten term, which is an essential part of chiral Lagrangians, describing the anomalous physics of pseudoscalars and vector mesons,[8] and topological effects in Yang-Mills gauge theories, such as the instanton physics in QCD. With Bruno Zumino, Bardeen formulated the theory of the gravitational anomaly which is of fundamental importance to string theory.[9]

On sabbatical, working at CERN in 1971, Bardeen collaborated with Murray Gell-Mann, Harald Fritzsch, and Heinrich Leutwyler. They considered a gauge theory of quark interactions, in which each quark comes in one of three varieties called “colors.’’ They wrote down the theory now known as quantum chromodynamics (QCD) and, through the chiral anomaly, established the existence of the three quark colors from the rate of decay.[10]

With his colleagues Andrzej Buras, Dennis Duke and Taizo Muta, Bardeen helped to formulate perturbation theory for quantum chromodynamics, introducing the systematic scheme for loop-level perturbation theory, frequently used in the analysis of QCD processes in high energy experiments.[11] With Buras and Jean-Marc Gerard he developed an analytical, non-perturbative framework for the calculation of non-leptonic decays of K-mesons and mixing. This approach, based on QCD with large led to several results, confirmed by numerical lattice calculation 30 years later. One of these results is the identification of the dominant QCD dynamics responsible for the so-called rule in decays, a long-standing puzzle since 1955.[12] With coauthors Sherwin Love and Chung Ngoc Leung, Bardeen also explored theoretical mechanisms for the origin of scale breaking in quantum field theory in conjunction with chiral symmetry breaking and the role of the dilaton.[13] [14]

In the early 1990s it became clear that the top quark was much heavier than originally anticipated, and that top quarks may be strongly coupled at very short distances. This raised the possibility that pairs of top quarks could form a composite Higgs boson, which led to top quark condensates,[15] and novel dynamical approaches to electroweak symmetry breaking. The theory, developed with Christopher T. Hill and Manfred Lindner, predicted a heavy top quark, governed by the infrared fixed point (about 20% heavier than the observed top quark mass of 175 GeV), but it tended to predict too heavy a Higgs boson, almost twice the observed mass of 125 GeV. Nonetheless, this was the first composite Higgs boson model and the general idea remains an intriguing possibility.

Bardeen and Hill, in 1994, recognized that heavy-light mesons, which contain a heavy quark and a light anti-quark, provide a unique window on the chiral dynamics of a single light quark. They showed that the (spin)parity ground states are split from the parity partners by a universal mass gap of about due to the light quark chiral symmetry breaking.[16] This correctly predicted an abnormally long-lived resonance ten years before it was discovered by the BABAR collaboration: the . The theory was further developed by Bardeen, Hill and Estia Eichten, and various decay modes were predicted that have been confirmed by experiment.[17] Similar phenomena should be seen in the mesons and (heavy-heavy-light baryons).

Honors

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William Bardeen was elected a Fellow of the American Physical Society in 1984. In 1985, Bardeen was awarded a John S. Guggenheim Memorial Foundation Fellowship for research on the application of quantum field theory to elementary particle physics. Previously, he had received the Senior Scientist Award of the Alexander von Humboldt Foundation and an Alfred P. Sloan Foundation Fellowship for research in theoretical physics. Bardeen was awarded the 1996 J.J. Sakurai Prize of the American Physical Society for his work on anomalies and perturbative quantum chromodynamics.[18] He was elected a Fellow of the American Academy of Arts and Sciences in 1998[19] and a member of the National Academy of Sciences in 1999.[20]

Visiting Appointments

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  • 1971-72: Visiting Scientist, CERN-TH, Geneva, Switzerland
  • 1974: Guest Scientist, Fermi National Accelerator Laboratory
  • 1977: Guest Scientist, Max-Planck Institute for Physics, Munich, FRG
  • 1985: Visitor, Research Institute for Fundamental Physics, Kyoto, Japan
  • 1985: Visitor, Academia Sinica, Beijing, China
  • 1985-86: Visitor, The Tata Institute for Fundamental Research, Mumbai, India
  • 1986: Visitor, Technion, Haifa, Israel
  • 1986: Visiting Scientist, Max-Planck Institute for Physics, Munich, FRG
  • 1986: Visiting Professor, University of Paris, Paris, France
  • 1997: Visiting Scientist, Max-Planck Institute for Physics, Munich, FRG
  • 2007: Visiting Professor, Yukawa Institute of Theoretical Physics, Kyoto, Japan
  • 2010: Visiting Professor, University of Valencia, Valencia, Spain
  • 2013: Investigator Doctor Senior, University of Valencia, Valencia, Spain
  • 2015: Visiting Scientist, University of Valencia, Valencia, Spain

See also

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Selected publications

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  • Bardeen's publications are available on the INSPIRE-HEP Literature Database [2].

Notes

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  1. ^ [1] William Bardeen, bio from Fermilab
  2. ^ Fermilab Office of Education and Public Outreach: Marge Bardeen
  3. ^ John Bardeen's Nobel Foundation biography
  4. ^ Adler, S.L.; Bardeen, W.A. (1969). "Absence of higher-order corrections in the anomalous axial-vector divergence equation". Physical Review. 182 (5): 1517–1536. Bibcode:1969PhRv..182.1517A. doi:10.1103/PhysRev.182.1517.
  5. ^ Bardeen, William A. (1969). "Anomalous Ward identities in spinor field theories". Phys. Rev. 184 (5): 1848–1857. Bibcode:1969PhRv..184.1848B. doi:10.1103/PhysRev.184.1848.
  6. ^ Wess, J.; Zumino, B. (1971). "Consequences of anomalous Ward identities". Phys. Lett. B. 37 (1): 95–97. Bibcode:1971PhLB...37...95W. doi:10.1016/0370-2693(71)90582-X.
  7. ^ Bardeen's calculation was done slightly before, and provided hints to, the non-renormalization at higher orders. The "left-right symmetric anomaly" is not manifestly gauge invariant and a prolonged argument among theorists ensued. The Wess-Zumino consistency conditions appeared afterward and confirmed Bardeen's calculation of the left-right symmetric anomaly as the consistent anomaly. The gauge variation of the D=5 Chern-Simons term produces the consistent anomaly on a D=4 bounding surface.
  8. ^ The Bardeen counter-term is implemented in the Wess-Zumino-Witten term in: Kaymakcalan, O.; Rajeev, S.; Schechter, J. (1984). "Nonabelian Anomaly and Vector Meson Decays". Phys. Rev. D. 30 (3): 594–602. Bibcode:1984PhRvD..30..594K. doi:10.1103/PhysRevD.30.594.; In the Standard Model the gauged electroweak currents must be conserved and the Bardeen counter-term is modified: Harvey, Jeffrey A.; Hill, Christopher T.; Hill, Richard (2007). "Standard Model Gauging of the Wess-Zumino-Witten Term: Anomalies, Global Currents and pseudo-Chern-Simons Interactions". Phys. Rev. D. 30 (8): 085017. arXiv:0712.1230. doi:10.1103/PhysRevD.77.085017. This reproduces B+L violation by the anomaly in the Standard model, and predicts numerous other anomalous processes.
  9. ^ Bardeen, William A.; Zumino, Bruno (1984). "Consistent and Covariant Anomalies in Gauge and Gravitational Theories". Nucl. Phys. B. 244 (2): 421–453. Bibcode:1984NuPhB.244..421B. doi:10.1016/0550-3213(84)90322-5. This is an extremely well written analysis, almost a tutorial, of anomalies, cohomology and general covariance as a local gauge symmetry.
  10. ^ W. A. Bardeen, H. Fritzsch, and M. Gell-Mann, "Light cone current algebra, decay, and annihilation," published in the "Topical Meeting on the Outlook for Broken Conformal Symmetry in Elementary Particle Physics", hep-ph/0211388, "CERN-TH-1538" (July 1972).
  11. ^ Bardeen, William A.; Buras, A.J.; Duke, D. W.; Muta, T. (1978). "Deep Inelastic Scattering Beyond the Leading Order in Asymptotically Free Gauge Theories". Phys. Rev. D. 18 (11): 3998–4017. Bibcode:1978PhRvD..18.3998B. doi:10.1103/PhysRevD.18.3998.
  12. ^ Bardeen, William A.; Buras, A.J.; Gerard, J. M. (1987). "A Consistent Analysis of the Rule for K Decays". Phys. Lett. B. 192: 138–144. doi:10.1016/0370-2693(87)91156-7.
  13. ^ Bardeen, William A.; Leung, Chung Ngoc; Love, Sherwin (1986). "The Dilaton and Chiral Symmetry Breaking". Phys. Rev. Lett. 56 (12): 1230–1233. arXiv:hep-ph/9304265. Bibcode:1986PhRvL..56.1230B. doi:10.1103/PhysRevLett.56.1230. PMID 10032607. S2CID 1763576.
  14. ^ Bardeen, William A.; Leung, Chung Ngoc; Love, Sherwin (1986). "Spontaneous Symmetry Breaking in Scale Invariant Quantum Electrodynamics". Nucl. Phys. B. 273 (3–4): 649–662. arXiv:hep-ph/9304265. Bibcode:1986NuPhB.273..649L. doi:10.1016/0550-3213(86)90382-2. S2CID 1763576.
  15. ^ Bardeen, William A.; Hill, Christopher T.; Lindner, Manfred (1990). "Minimal dynamical symmetry breaking of the standard model". Phys. Rev. D. 41 (5): 1647–1660. Bibcode:1990PhRvD..41.1647B. doi:10.1103/PhysRevD.41.1647. PMID 10012522.
  16. ^ Bardeen, William A.; Hill, Christopher T. (1994). "Chiral dynamics and heavy quark symmetry in a solvable toy field theoretic model". Physical Review D. 49 (1): 409–425. arXiv:hep-ph/9304265. Bibcode:1994PhRvD..49..409B. doi:10.1103/PhysRevD.49.409. PMID 10016779. S2CID 1763576.
  17. ^ Bardeen, William A.; Eichten, Estia; Hill, Christopher T. (2003). "Chiral multiplets of heavy-light mesons". Physical Review D. 68 (5): 054024. arXiv:hep-ph/0305049. Bibcode:2003PhRvD..68e4024B. doi:10.1103/PhysRevD.68.054024. S2CID 10472717.
  18. ^ William A. Bardeen, homepage at Fermilab
  19. ^ "Book of Members, 1780-2010: Chapter B" (PDF). American Academy of Arts and Sciences. Retrieved May 17, 2011.
  20. ^ List of members of the National Academy of Sciences (Physics)
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