David Pines (born June 8, 1924)is the Founding Director of the Institute for Complex Adaptive Matter (ICAM) and the International Institute for Complex Adaptive Matter (I2CAM) (respectively, US wide and international institutions dedicated to research in and the understanding of emergent phenomena), Distinguished Professor of Physics, UC Davis, Research Professor of Physics and Professor Emeritus of Physics and Electrical and Computer Engineering in the Center for Advanced Study, University of Illinois at Urbana-Champaign, and a staff member in the office of the Materials, Physics, and Applications Division at Los Alamos.
His seminal contributions to the theory of many-body systems and to theoretical astrophysics have been recognized by two Guggenheim Fellowships, the Feenberg Medal, Friemann, Dirac, and Drucker Prizes, and by his election to the National Academy of Sciences, American Philosophical Society, American Academy of Arts and Sciences, Russian Academy of Sciences, and Hungarian Academy of Sciences and Visiting Professorships at Caltech, College de France, Trinity College, University of Cambridge, University of Leiden, and Universite de Paris.
He is the Founding Director of the Center for Advanced Study, UIUC (1968—70), was Vice-President of the Aspen Center for Physics from 1968—1972, founder and Co-chair of the US-USSR Cooperative Program in Physics, 1968—89; and a Co-founder, Vice-President, Chair of the Board of Trustees, and Co-Chair of the Science Board the Santa Fe Institute, from 1982 to 1996.
He has been the organizer or co-organizer of fifteen workshops and two summer schools of theoretical physics, is currently an Honorary Trustee and Honorary Member of the Aspen Center for Physics, and a member of the Board of Overseers, Sabanci University, Istanbul.
His current research concerns the search for the organizing principles responsible for emergent behavior in materials where unexpectedly new classes of behavior emerge in response to the strong and competing interactions among their elementary constituents. Some recent research results on correlated electron materials are the development of a consistent phenomenological description of protected magnetic behavior in the pseudogap state of underdoped cuprate superconductors and the discovery of the protected emergence of itinerancy in the Kondo lattice in heavy electron materials and its description using a two-fluid model. He continues his interest in the superfluidity of neutron stars revealed by pulsar glitches and in elementary excitations in the helium liquids.
Protected Behavior in the Pseudogap State of Underdoped Cuprate Superconductors (with V. Barzykin), Phys.Rev.Lett , in the press and condmat 0601396, 2006
Scaling and the Magnetic Origin of Emergent Behavior in Correlated Electron Superconductors (with N. Curro and Z. Fisk), MRS Bulletin 30, pp442—446, 2005
The Pseudogap: Friend or Foe of High Temperature Superconductivity (with M. Norman and C. Kallin), Adv. Phys. 54, 715, 2005.
Scaling in the Emergent Behavior of Heavy Electron Materials, (with N. Curro, B-L. Young, and J. Schmalian) Phys. Rev.B. 70, 235117 (2004)
Two Fluid Description of the Kondo Lattice (with S. Nakatsuji and Z. Fisk), Phys Rev. Lett. 92,016401, 2004
Low Frequency Spin Dynamics in the CeMIn5 Materials (with N. Curro et al.), Phys, Rev. Lett.90, 227202, 2003
A Spin Fluctuation Model for d-wave Superconductors (with A. Chubukov and j. Schmalian), in “The Physics of Conventional and Unconventional
Superconductors”, ed. K.H. Benneman and J. B. Ketterson, Springer Pub, 2003 (cond-mat/0201140)
The Quantum Criticality Conundrum (with R.B. Laughlin, G. Lonzarich, and P. Monthoux) , Advances in Physics 50, 361-365, 2001
The Middle Way (with R. B.Laughlin, B.Stojkovic, J. Schmalian, P.Wolynes),, PNAS 97,32-37, 2000
The Theory of Everything (with R. B. Laughlin), PNAS 97, 27-32 (2000)
Significant Publications on Quantum Liquidsmoreless
1. A Collective Description of Electron Interactions: III. Coulomb Interactions in a Degenerate Electron Gas (with D. Bohm). Phys. Rev. 92, 609-625 (1953).
2. A Collective Description of Electron Interactions: IV. Electron Interaction in Metals. Phys. Rev. 92, 626-636 (1953).
3. Electron Interaction in Metals. Solid State Physics, eds. F. Seitz and D. Turnbull, Academic, N.Y., 1, 3-51 (1955).
4. The Correlation Energy of a Free Electron Gas (with P. Nozières). Phys. Rev. 111, 442-454 (1958).
5. Collective Energy Losses in Solids. Rev. Mod. Phys. 28, 184-199 (1956).
6. The Motion of Slow Electrons in Polar Crystals (with T. D. Lee and F. Low). Phys. Rev. 90, 297-302 (1953).
7. Electron-Phonon Interaction in Metals (with J. Bardeen). Phys. Rev. 99, 1140-1150 (1955).
8. Nuclear Superconductivity, Proc. of the Rehovoth Conf. on Nuclear Structure, Interscience Press, 26-27 (1957).
9. Possible Analogy Between the Excitation Spectra of Nuclei and Those of the Superconducting Metallic State (with A. Bohr and B. Mottelson). Phys. Rev. 110, 936-938 (1958).
10. Ground-State Energy and Excitation Spectrum of a System of Interacting Bosons (with N. Hugenholtz). Phys. Rev. 116, 489-506 (1959)
11. Effective Interaction of He3 Atoms in Dilute Solutions of He3 in He4 at Low Temperatures (with J. Bardeen and G. Baym). Phys. Rev. 156, 207-221 (1967).
12. Zero Sound in Liquid 4He and 3He, Quantum Fluids, Proc. of the Sussex University Symp., 16—20 August 1965, ed. D. F. Brewer, North-Holland Pub. Co., Amsterdam), pp. 257—277 (1966).
13. Polarization Potentials and Elementary Excitations in He II at Low Temperatures (with C. H. Aldrich III). J. Low Temp. Phys. 25, 677-690 (1976).
14. Polarization Potentials and Elementary Excitations in Liquid 3He (with C. H. Aldrich III). J. Low Temp. Phys. 32, 689-715 (1978).
15. Roton Liquid Theory (with K. Bedell and I. Fomin). J. Low Temp. Phys. 48, 417-433 (1982).
16. Pseudopotential Theory of Interacting Roton Pairs in Superfluid 4He (with K. Bedell and A. Zawadowski). Phys. Rev. B 29, 102-122 (1984).
17. Superfluidity in Neutron Stars (with G. Baym and C. Pethick). Nature 224, 673-674 (1969).
18. Inside Neutron Stars, Proc. of 12th Int. Conf. on Low Temperature Physics, ed. Eizo Kanda, Academic Press of Japan, pp. 7—21 (1971).
19. Superfluidity in Neutron Stars (with M. A. Alpar). Nature 316, 27-32 (1985).
20. Quasiparticle Interactions in Neutron Matter for Applications in Neutron Stars (with J. Wambach and T. L. Ainsworth). Nucl. Phys. A555, 128-150 (1993).
21. Phenomenological Model of Nuclear Relaxation in the Normal State of YBa2Cu3O7 (with A. Millis and H. Monien). Phys. Rev. B 42, 167-177 (1990).
22. Toward a Theory of High Temperature Superconductivity in the Antiferro-magnetically Correlated Cuprate Oxides (with P. Monthoux and A. Balatsky). Phys. Rev. Lett. 67, 3448-3451 (1991).
23. Spin-fluctuation-induced Superconductivity in the Copper Oxides: A Strong Coupling Calculation (with P. Monthoux). Phys. Rev. Lett. 69, 961-964 (1992).
24. Nearly Antiferromagnetic Fermi Liquids are High Temperature Supercon-ductors: Are the Superconducting Cuprates Nearly Antiferromagnetic Liquids? J. Chem. Phys. Solids 54, 1447-1455 (1993).
26. Scaling in the Emergent Behavior of Heavy Electron Materials (with N. Curro, B-L. Young, and J. Schmalian, Phys.Rev.B.70,235117 (2004)
27. Protected Behavior in the Pseudogap State of Underdoped Cuprate Superconductors (with V. Barzykin), Phys.Rev. Lett., in the press and condmat 0601396, 2006.
1. The Many-Body Problem. (W. A. Benjamin: N.Y) 456 pp. (1961) (Russian translation, State Publishing House, Moscow, 1963).
2. Elementary Excitations in Solids. (W. A. Benjamin: N. Y.) 312 pp. (1963) (Russian translation, State Publishing House, Moscow, 1965). Japanese translation (Syokabo Press, Tokyo, 1974).
3. The Theory of Quantum Liquids, Vol. I Normal Fermi Liquids. W. A. Benjamin: NY, 1, 355 pp. (1966). (Russian Translation, Publishing House MIR, Moscow, 1968).
4. The Theory of Quantum Liquids Vol. II: Superfluid Bose Liquids (with P. Nozières), Addison-Wesley, 180pp (1990).
Co-Founder of the Center for Advanced Study, UIUC, 1967; the Aspen Center for Physics, 1967—69; the US-USSR Cooperative Program in Physics, 1968; the Santa Fe Institute, 1982—84; and the Institute for Complex Adaptive Matter, 1998-1999.
Organizer or co-organizer of fifteen workshops and two summer schools of theoretical physics
Aspen Center for Physics: Vice-President, 1968—72;
Board of Trustees 1968-80; Honorary Trustee, 1980-; Member, 1980-
Santa Fe Institute: Co-Founder, 1984; Vice-President,
Institute for Complex Adaptive Matter: Founding Director and Member of Board of Trustees (now Board of Governors) and Science Steering Committee, 1999—present
National Academy of Sciences; Chair, Panel on Condensed Matter Physics, 1994—98
National Academy of Sciences/National Research Council:
Physics Survey Committee, 1965—66;
Board on International Scientific Exchange, Founder and Chair, 1973—1977
US/USSR Workshops in Condensed Matter Theory, Founder and Co-Chair, 1968; 1970; 1974; 1978; 1988
US/USSR Commission on Cooperation in Physics, Founder and Co-Chair, 1975—80
American Academy of Arts and Sciences: Chair, Physics Section and Class Membership Committee, 1996—99
Los Alamos National Laboratory:
T Division Advisory Committee: Member 1975-82; Chair, 1977—1982
Institute for Defense Analyses, Mentor, Defense Sciences Study Group, 1985—2000