THERMAL EQUILIBRIUM AND KMS CONDITION AT THE PLANCK SCALE

THERMAL EQUILIBRIUM AND KMS CONDITION AT THE PLANCK SCALE

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摘要 Considering the expected thermal equilibrium characterizing the physics at the Planck scale, it is here stated, for the first time, that, as a system, the space-time at the Planck scale must be considered as subject to the Kubo-Martin-Schwinger (KMS) condition. Consequently, in the interior of the KMS strip, i.e. from the scale B = 0 to the scale B = lplanck, the fourth coordinate g44 must be considered as complex, the two real poles being 6 = 0 and B = lplanck. This means that within the limits of the KMS strip, the Lorentzian and the Euclidean metric are in a 'quantum superposition state' (or coupled), this entailing a 'unification' (or coupling) between the topological (Euclidean) and the physical (Lorentzian) states of space-time.

作者 G.BOGDANOFF I.BOGDANOFF

机构地区 Mathematical Physics Laboratory CNRS UPRES A

出处《Chinese Annals of Mathematics,Series B》 SCIE CSCD 2003年第2期267-274,共8页 数学年刊（B辑英文版）

关键词 KMS state Planck scale KMS strip 热平衡 Planck尺度 Kubo-Martin-Schwinger条件 Lorentz矩阵 Euclid矩阵宇宙模型量子理论空间-时间系统正则时间流

分类号 O175.24 [理学—基础数学]

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1Atick, J. J. & Witten, E., The Hagedorn transition and the number of freedom in string theory, Nucl.Phys., B 310(1988), 291-334.
2Huang, K. & Weinberg, S., Ultimate temperature and the early universe, Phys. Rev. Letters, 25(1970),895-897.
3Weinberg, S., Gauge and global symmetries at high temperature, Phys. Rev. D., 9:12(1974), 3357-3378.
4Witten, E., Lectures on quantum field theory, Quantum Fields and Strings, Am. Math. Soc., 1-2, 1991.
5Antoniadis, I., Deredinger, J. P. & Kounnas, C., Non-perturbative supersymmetry breaking and finite temperature instabilities in N ＝ 4 superstrings, hep-th, 9908137, 1999.
6Kounnas, C., Universal termal instabilities and the high-temperature phase of the N ＝ 4 superstrings,hep-th, 9902072, 1999.
7Trucks, M., A KMS-like state of Hadamard type on Robertson-Walker spacetimes and its time evolution,Commun. Math. Phys, 197(1998), 387-404.
8Longo, R., Notes for a quantum index theorem, CERN Preprint Math., OA-0003082, 2000.
9Buchholz, D. A. & Longo, R., Graded KMS Functionals and the breakdown of supersymmetry, Adv.Theor. Math. Phys., 3(1999), 615-626.
10Bogdanov, G., Fluctuations quantiques de la signature de la metrique a l'Echelle de Planck, Th. Doctorat Univ. de Bourgogne, 1999.

1田谷基.Planck尺度的Hopf代数的Poisson括符(英文)[J].数学杂志,2004,24(4):355-360.
2张华明.关于Lorentz矩阵的标准形和Lorentz群的弧连通性[J].五邑大学学报（自然科学版）,1998,12(2):38-41.
3武俐利,宋丽军,宋金沙.拉曼增益对三类有限背景解传输特性的影响[J].量子光学学报,2016,22(3):270-275. 被引量：1
4武俐利,宋丽军.自陡峭和自频移效应对有限背景解的影响[J].量子光学学报,2017,23(1):52-60.
5段广森,齐迎春.两类图的k-优美性[J].郑州大学学报（理学版）,2002,34(2):36-38.
6赵萍,罗兆富.Lorentz意义上的共形映射[J].宁夏大学学报（自然科学版）,2000,21(3):203-206.
7吴岳良,K.C.Chou,周光召.A possible unification model for all basic forces[J].Science China Mathematics,1998,41(3):324-329. 被引量：2
8申北智,袁萍.黑洞熵起源的探讨[J].淮海工学院学报（自然科学版）,2009,18(1):7-10.
9李永福.B-型双曲运动与Lorentz群[J].湖州师范学院学报,1988,0(5):12-20. 被引量：1
10LING Yin-Sheng School of Physical Science and Technology,Suzhou University,Suzhou 215006,China.Calculation of Pairwise Thermal Entanglement for Odd Qubit XX Chain[J].Communications in Theoretical Physics,2007(12):1017-1020.

Chinese Annals of Mathematics,Series B

2003年第2期

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THERMAL EQUILIBRIUM AND KMS CONDITION AT THE PLANCK SCALE

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