Spin-charge separation for paired Dirac fermions in (1 + 1) dimensions

IF 5.4 1区物理与天体物理 Q1 Physics and Astronomy Journal of High Energy Physics Pub Date : 2024-11-14 DOI:10.1007/JHEP11(2024)088

Laith H. Haddad

引用次数: 0

Abstract

We study Dirac fermions at finite density coupled to a complex pairing field assumed to obey scalar field theory with quartic self-repulsion. The bulk of our work develops the mathematics that elucidates the propagation of fermionic excitations in such systems as independent spin (boosts) and charge (fermion number) degrees of freedom. A necessary ingredient is the presence of broken U(1) symmetry in the pairing field and decoupling of its density and phase. In the fermion sector, these elements give rise to an emergent spin-dependent gauge coupling which binds in-vacuum spin and charge into elementary fermions, while driving proliferation of unbound spin and charge for finite condensation in the pairing field. Notably, the onset of spin-charge separation is signaled by \( \mathcal{PT} \)-symmetry breaking and decoupling of spin components under Lorentz transformations. Our investigation concludes with two theorems that identify generic features of spin-charge separation in such systems.

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成对狄拉克费米子在 (1 + 1) 维的自旋-电荷分离

我们研究的是在有限密度下与复杂配对场耦合的狄拉克费米子，假定该配对场服从标量场理论，具有四元自斥性。我们的主要工作是发展数学，阐明费米子激元在这类系统中的传播，即独立的自旋（助长）和电荷（费米子数）自由度。一个必要的因素是配对场中存在被打破的 U(1) 对称性，以及其密度和相位的解耦。在费米子部门，这些元素产生了一种新出现的自旋相关规规耦合，它将真空中的自旋和电荷绑定到基本费米子中，同时推动非绑定自旋和电荷在配对场中有限凝聚的扩散。值得注意的是，自旋-电荷分离的开始是由（\mathcal{PT} \）对称性破缺和洛伦兹变换下自旋成分的解耦来标志的。我们的研究最后提出了两个定理，确定了这类系统中自旋电荷分离的一般特征。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of High Energy Physics 物理-物理：粒子与场物理

CiteScore

10.30

自引率

46.30%

发文量

2107

审稿时长

1.5 months

期刊介绍： The aim of the Journal of High Energy Physics (JHEP) is to ensure fast and efficient online publication tools to the scientific community, while keeping that community in charge of every aspect of the peer-review and publication process in order to ensure the highest quality standards in the journal. Consequently, the Advisory and Editorial Boards, composed of distinguished, active scientists in the field, jointly establish with the Scientific Director the journal''s scientific policy and ensure the scientific quality of accepted articles. JHEP presently encompasses the following areas of theoretical and experimental physics: Collider Physics Underground and Large Array Physics Quantum Field Theory Gauge Field Theories Symmetries String and Brane Theory General Relativity and Gravitation Supersymmetry Mathematical Methods of Physics Mostly Solvable Models Astroparticles Statistical Field Theories Mostly Weak Interactions Mostly Strong Interactions Quantum Field Theory (phenomenology) Strings and Branes Phenomenological Aspects of Supersymmetry Mostly Strong Interactions (phenomenology).

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