Thermodynamics in quenched QCD: energy–momentum tensor with two-loop order coefficients in the gradient-flow formalism

We measure correlation functions of the nonperturbatively renormalized energy-momentum tensor in Nf = 2 + 1 full QCD at finite temperature by applying the gradient flow method both to the gauge and quark fields. Our main interest is to study the conservation law of the energy-momentum tensor and to test whether the linear response relation is properly realized for the entropy density. By using the linear response relation we calculate the specific heat from the correlation function. We adopt the nonperturba-tively improved Wilson fermion and Iwasaki gauge action at a fine lattice spacing = 0:07 fm. In this paper the temperature is limited to a single value T ≃ 232 MeV. The u, d quark mass is rather heavy with mπ=mρ ≃ 0:63 while the s quark mass is set to approximately its physical value.

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Correlations of the energy-momentum tensor via gradient flow in SU(3) Yang-Mills theory at finite temperature

Physical Review D ◽

10.1103/physrevd.96.111502 ◽

2017 ◽

Vol 96 (11) ◽

Cited By ~ 10

Author(s):

Masakiyo Kitazawa ◽

Takumi Iritani ◽

Masayuki Asakawa ◽

Tetsuo Hatsuda

Keyword(s):

Finite Temperature ◽

Energy Momentum Tensor ◽

Gradient Flow ◽

Momentum Tensor ◽

Yang Mills

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Equation of state in (2+1)-flavor QCD at physical point with improved Wilson fermion action using gradient flow

EPJ Web of Conferences ◽

10.1051/epjconf/201817507023 ◽

2018 ◽

Vol 175 ◽

pp. 07023 ◽

Cited By ~ 5

Author(s):

Kazuyuki Kanaya ◽

Shinji Ejiri ◽

Ryo Iwami ◽

Masakiyo Kitazawa ◽

Hiroshi Suzuki ◽

...

Keyword(s):

Equation Of State ◽

Quark Mass ◽

Energy Momentum Tensor ◽

Gradient Flow ◽

Chiral Condensate ◽

Momentum Tensor ◽

Mass Point ◽

Physical Point ◽

Preliminary Results ◽

Fermion Action

We study the energy-momentum tensor and the equation of state as well as the chiral condensate in (2+1)-flavor QCD at the physical point applying the method of Makino and Suzuki based on the gradient flow. We adopt a nonperturbatively O(a)- improved Wilson quark action and the renormalization group-improved Iwasaki gauge action. At Lattice 2016, we have presented our preliminary results of our study in (2+1)- flavor QCD at a heavy u; d quark mass point. We now extend the study to the physical point and perform finite-temperature simulations in the range T ≃ 155.544 MeV (Nt = 4-14 including odd Nt’s) at a ≃ 0:09 fm. We show our final results of the heavy QCD study and present some preliminary results obtained at the physical point so far.

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Equation of state for SU(3) gauge theory via the energy-momentum tensor under gradient flow

Physical Review D ◽

10.1103/physrevd.94.114512 ◽

2016 ◽

Vol 94 (11) ◽

Cited By ~ 28

Author(s):

Masakiyo Kitazawa ◽

Takumi Iritani ◽

Masayuki Asakawa ◽

Tetsuo Hatsuda ◽

Hiroshi Suzuki

Keyword(s):

Gauge Theory ◽

Equation Of State ◽

Energy Momentum Tensor ◽

Gradient Flow ◽

Momentum Tensor

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Mass sum rules of the electron in quantum electrodynamics

Journal of High Energy Physics ◽

10.1007/jhep09(2020)067 ◽

2020 ◽

Vol 2020 (9) ◽

Author(s):

S. Rodini ◽

A. Metz ◽

B. Pasquini

Keyword(s):

Quantum Electrodynamics ◽

Rest Frame ◽

Energy Momentum Tensor ◽

Sum Rules ◽

Form Factors ◽

Momentum Tensor ◽

Moving Frame ◽

Nucleon Mass ◽

Loop Order ◽

The Masses

Abstract Different decompositions of the nucleon mass, in terms of the masses and energies of the underlying constituents, have been proposed in the literature. We explore the corresponding sum rules in quantum electrodynamics for an electron at one-loop order in perturbation theory. To this aim we compute the form factors of the energy-momentum tensor, by paying particular attention to the renormalization of ultraviolet divergences, operator mixing and scheme dependence. We clarify the expressions of all the proposed sum rules in the electron rest frame in terms of renormalized operators. Furthermore, we consider the same sum rules in a moving frame, where they become energy decompositions. Finally, we discuss some implications of our study on the mass sum rules for the nucleon.

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