Low-energy effective field theory study of nuclear matter

doi:10.3969/j.issn.1000-5641.202022007

Abstract

Abstract:

In this study, the low-energy effective field theory approach is used to analyze nuclear matter and a zero-temperature Fermi system. By solving the Bethe-Goldstone equation (BGE) in the ¹S₀ channel, we obtain the closed-form Brückner G matrix and derive its renormalized non-perturbative form. Upon selecting values for relevant parameters, a number of physical issues are analyzed with the Brückner G matrix, such as pairing and single particle energy of a Fermi system in the density background. Lastly, the framework and results are compared with those published in the literature.

Key words: effective field theory, Brückner G matrix, renormalization, finite density

CLC Number:

O412.3

Tingwei PAN, Jifeng YANG. Low-energy effective field theory study of nuclear matter[J]. Journal of East China Normal University(Natural Science), 2021, 2021(1): 82-91.

Figures/Tables 12

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p_F/fm^–1	k_p/fm^–1
p_F/fm^–1	x = +0.20	x = –0.20	x = +0.05	x = –0.05
0.02	0.019993	0.095892	0.287473	0.599659
0.10	0.019993	0.095883	0.287139	0.599531
0.30	0.019993	0.095889	0.287364	0.599622
0.60	0.019993	0.095887	0.287282	0.599591

p_F/fm^–1	k_p/fm^–1
p_F/fm^–1	x = +0.20	x = –0.20	x = +0.05	x = –0.05
0.02	0.019993	0.095848	0.292220
0.10	0.019993	0.095815	0.290605
0.30	0.019993	0.095837	0.291721
0.60	0.019993	0.095829	0.291325

p_F/fm^–1	(E/A)₁/MeV				(E/A)₂/MeV
p_F/fm^–1	x = +0.20	x = –0.20	x = +0.05	x = –0.05	(E/A)₂/MeV
0.02	0.004272	0.07010	0.47441	1.39254	0.004334
0.10	0.004272	0.07005	0.46638	1.33538	0.082810
0.30	0.004272	0.07009	0.47179	1.37403	0.610010
0.50	0.004272	0.07007	0.46980	1.35990	1.584170

p_F/fm^–1	(E/A)₁/MeV				(E/A)₂/MeV
p_F/fm^–1	x = +0.20	x = –0.20	x = +0.05	x = –0.05	(E/A)₂/MeV
0.02	0.004272	0.06959	0.42301	1.21512	0.004334
0.10	0.004272	0.06940	0.38721	0.95924	0.082810
0.30	0.004272	0.06953	0.41158	1.13564	0.610010
0.50	0.004272	0.06948	0.40276	1.07292	1.584170
注: 取 ${\varLambda _{ {J_0} } }$ = 35 MeV时, 一部分p_F取值的Brückner G 矩阵没有极点, 所以灰色部分是一般积分所得的结果

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