Baryon density correlations in the quark plasma

C. Bernard; T. A. DeGrand; C. DeTar; S. Gottlieb; A. Krasnitz; R. L. Sugar; D. Toussaint

doi:10.1016/0920-5632(93)90217-T

Baryon density correlations in the quark plasma

C. Bernard, T. A. DeGrand, C. DeTar, S. Gottlieb, A. Krasnitz, R. L. Sugar, D. Toussaint

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

1 Scopus citations

Abstract

As part of an ongoing effort to characterize the high temperature phase of QCD, we measure the quark baryon density in the vicinity of a fixed test quark and compare it with similar measurements at low temperature and at the crossover temperature. Such an observable has also been studied by the Vienna group. We find an extremely weak correlation at high temperature, suggesting that small color singlet clusters are unimportant in the thermal ensemble. We also find that at T = 0.75T_c the induced quark number shows a surprisingly large component attributable to baryonic screening. A simulation of a simple flux tube model produces results that suggest a plausible scenario: As the crossover temperature is approached from below, baryonic states proliferate. Above the crossover temperature the mean size of color singlet clusters grows explosively, resulting in an effective electrostatic deconfinement.

Original language	English (US)
Pages (from-to)	319-322
Number of pages	4
Journal	Nuclear Physics B (Proceedings Supplements)
Volume	30
Issue number	C
DOIs	https://doi.org/10.1016/0920-5632(93)90217-T
State	Published - Mar 1993
Externally published	Yes

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics
Nuclear and High Energy Physics

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10.1016/0920-5632(93)90217-T

Cite this

@article{18fb1d4d75564979a64de42781309e67,

title = "Baryon density correlations in the quark plasma",

abstract = "As part of an ongoing effort to characterize the high temperature phase of QCD, we measure the quark baryon density in the vicinity of a fixed test quark and compare it with similar measurements at low temperature and at the crossover temperature. Such an observable has also been studied by the Vienna group. We find an extremely weak correlation at high temperature, suggesting that small color singlet clusters are unimportant in the thermal ensemble. We also find that at T = 0.75Tc the induced quark number shows a surprisingly large component attributable to baryonic screening. A simulation of a simple flux tube model produces results that suggest a plausible scenario: As the crossover temperature is approached from below, baryonic states proliferate. Above the crossover temperature the mean size of color singlet clusters grows explosively, resulting in an effective electrostatic deconfinement.",

author = "C. Bernard and DeGrand, {T. A.} and C. DeTar and S. Gottlieb and A. Krasnitz and Sugar, {R. L.} and D. Toussaint",

note = "Funding Information: Code development and testing were carried out on the nCUBE and Intel iPSC/860 at the San Diego Supercomputer Center. Computations in QCD were carried out on an Intel iPSC/860 at the NASA-Ames Research Center and on a Thinking Machines Corporation CM-5 at the Pittsburgh Supercomputer Center. We are extremely grateful for the support of these three centers. Flux tube model calculations were carried out on IBM RS/6000's at the University of Utah. This work was supported by the U.S. Department of Energy and by the National Science Foundation.",

year = "1993",

month = mar,

doi = "10.1016/0920-5632(93)90217-T",

language = "English (US)",

volume = "30",

pages = "319--322",

journal = "Nuclear Physics B (Proceedings Supplements)",

issn = "0920-5632",

publisher = "Elsevier B.V.",

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TY - JOUR

T1 - Baryon density correlations in the quark plasma

AU - Bernard, C.

AU - DeGrand, T. A.

AU - DeTar, C.

AU - Gottlieb, S.

AU - Krasnitz, A.

AU - Sugar, R. L.

AU - Toussaint, D.

N1 - Funding Information: Code development and testing were carried out on the nCUBE and Intel iPSC/860 at the San Diego Supercomputer Center. Computations in QCD were carried out on an Intel iPSC/860 at the NASA-Ames Research Center and on a Thinking Machines Corporation CM-5 at the Pittsburgh Supercomputer Center. We are extremely grateful for the support of these three centers. Flux tube model calculations were carried out on IBM RS/6000's at the University of Utah. This work was supported by the U.S. Department of Energy and by the National Science Foundation.

PY - 1993/3

Y1 - 1993/3

N2 - As part of an ongoing effort to characterize the high temperature phase of QCD, we measure the quark baryon density in the vicinity of a fixed test quark and compare it with similar measurements at low temperature and at the crossover temperature. Such an observable has also been studied by the Vienna group. We find an extremely weak correlation at high temperature, suggesting that small color singlet clusters are unimportant in the thermal ensemble. We also find that at T = 0.75Tc the induced quark number shows a surprisingly large component attributable to baryonic screening. A simulation of a simple flux tube model produces results that suggest a plausible scenario: As the crossover temperature is approached from below, baryonic states proliferate. Above the crossover temperature the mean size of color singlet clusters grows explosively, resulting in an effective electrostatic deconfinement.

AB - As part of an ongoing effort to characterize the high temperature phase of QCD, we measure the quark baryon density in the vicinity of a fixed test quark and compare it with similar measurements at low temperature and at the crossover temperature. Such an observable has also been studied by the Vienna group. We find an extremely weak correlation at high temperature, suggesting that small color singlet clusters are unimportant in the thermal ensemble. We also find that at T = 0.75Tc the induced quark number shows a surprisingly large component attributable to baryonic screening. A simulation of a simple flux tube model produces results that suggest a plausible scenario: As the crossover temperature is approached from below, baryonic states proliferate. Above the crossover temperature the mean size of color singlet clusters grows explosively, resulting in an effective electrostatic deconfinement.

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VL - 30

SP - 319

EP - 322

JO - Nuclear Physics B (Proceedings Supplements)

JF - Nuclear Physics B (Proceedings Supplements)

IS - C

ER -

Baryon density correlations in the quark plasma

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