Dense QCD: Overhauser or BCS pairing?

Byung Yoon Park; Mannque Rho; Andreas Wirzba; Ismail Zahed

doi:10.1103/PhysRevD.62.034015

Dense QCD: Overhauser or BCS pairing?

Byung Yoon Park
, Mannque Rho
, Andreas Wirzba
, Ismail Zahed

Physics and Astronomy

Korea Institute for Advanced Study
Chungnam National University
CEA Saclay
Stony Brook University
Jülich Research Centre

Research output: Contribution to journal › Article › peer-review

102 Scopus citations

Abstract

We discuss the Overhauser effect (particle-hole pairing) versus the BCS effect (particle-particle or hole-hole pairing) in QCD at large quark density. In weak coupling and to leading logarithm accuracy, the pairing energies can be estimated exactly. For a small number of colors, the BCS effect overtakes the Overhauser effect, while for a large number of colors the opposite takes place, in agreement with a recent renormalization group argument. In strong coupling with large pairing energies, the Overhauser effect may be dominant for any number of colors, suggesting that QCD may crystallize into an insulator at a few times nuclear matter density, a situation reminiscent of dense Skyrmions. The Overhauser effect is dominant in QCD in 1+1 dimensions, although susceptible to quantum effects. It is sensitive to temperature in all dimensions.

Original language	English
Article number	034015
Pages (from-to)	1-13
Number of pages	13
Journal	Physical Review D
Volume	62
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevD.62.034015
State	Published - Aug 1 2000

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10.1103/PhysRevD.62.034015

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abstract = "We discuss the Overhauser effect (particle-hole pairing) versus the BCS effect (particle-particle or hole-hole pairing) in QCD at large quark density. In weak coupling and to leading logarithm accuracy, the pairing energies can be estimated exactly. For a small number of colors, the BCS effect overtakes the Overhauser effect, while for a large number of colors the opposite takes place, in agreement with a recent renormalization group argument. In strong coupling with large pairing energies, the Overhauser effect may be dominant for any number of colors, suggesting that QCD may crystallize into an insulator at a few times nuclear matter density, a situation reminiscent of dense Skyrmions. The Overhauser effect is dominant in QCD in 1+1 dimensions, although susceptible to quantum effects. It is sensitive to temperature in all dimensions.",

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AB - We discuss the Overhauser effect (particle-hole pairing) versus the BCS effect (particle-particle or hole-hole pairing) in QCD at large quark density. In weak coupling and to leading logarithm accuracy, the pairing energies can be estimated exactly. For a small number of colors, the BCS effect overtakes the Overhauser effect, while for a large number of colors the opposite takes place, in agreement with a recent renormalization group argument. In strong coupling with large pairing energies, the Overhauser effect may be dominant for any number of colors, suggesting that QCD may crystallize into an insulator at a few times nuclear matter density, a situation reminiscent of dense Skyrmions. The Overhauser effect is dominant in QCD in 1+1 dimensions, although susceptible to quantum effects. It is sensitive to temperature in all dimensions.

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ER -

Dense QCD: Overhauser or BCS pairing?

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