Graphene is neither relativistic nor non-relativistic: thermodynamics aspects

IF 1.9 4区物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY

Pramana Pub Date : 2025-01-30 DOI:10.1007/s12043-024-02888-y

Thandar Zaw Win, Cho Win Aung, Gaurav Khandal, Sabyasachi Ghosh

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Abstract

Discovery of electron hydrodynamics in graphene systems has opened a new scope of theoretical research in condensed matter physics, which was traditionally well cultivated in science and engineering as a non-relativistic hydrodynamics and in high energy nuclear and astrophysics as relativistic hydrodynamics. Electrons in graphene follow neither non-relativistic nor relativistic hydrodynamics. Similar to other hydrodynamical descriptions, the energy–momentum tensor of graphene also has an ideal component and a dissipating component, but in an unconventional way, so popularly, it is sometimes called as unconventional hydrodynamics. The unconventional part of the dissipating component for the energy–momentum tensor is recently addressed in Phys. Rev. B 108, 235172 (2023) but its ideal component, which is connected with the thermodynamics of graphene, has not been zoomed in a very systematic way. This article has gone through systematic microscopic calculations of thermodynamical quantities like pressure, energy density, etc., of electron-fluid in graphene and compared with the corresponding estimations for non-relativistic and ultra-relativistic cases. We have sketched the temperature and Fermi energy dependency of electron thermodynamics for graphene and other cases where the transition from Fermi liquid to Dirac fluid domain is explored. An equivalent transition for quark matter is also discussed. Interestingly, an enhancement of specific heat within the low-temperature and Fermi energy region is found, which may be connected to the recently observed Wiedemann–Franz law violation.

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石墨烯既不是相对论性的也不是非相对论性的：热力学方面

石墨烯体系中电子流体力学的发现为凝聚态物理的理论研究开辟了一个新的领域。凝聚态物理传统上作为非相对论流体力学在科学和工程中得到很好的培养，作为相对论流体力学在高能核和天体物理学中得到很好的培养。石墨烯中的电子既不遵循非相对论性也不遵循相对论性流体力学。与其他流体力学描述类似，石墨烯的能量动量张量也有理想分量和耗散分量，但以一种非常规的方式，如此普遍，有时被称为非常规流体力学。能量-动量张量耗散分量的非常规部分最近在物理学中得到了解决。Rev. B 108,235172(2023)，但它的理想成分，与石墨烯的热力学有关，还没有以非常系统的方式放大。本文对石墨烯中电子流体的压力、能量密度等热力学量进行了系统的微观计算，并与非相对论和超相对论情况下的相应估计进行了比较。我们已经概述了石墨烯电子热力学的温度和费米能量依赖关系，以及探索从费米液体到狄拉克流体域转变的其他情况。讨论了夸克物质的等效跃迁。有趣的是，在低温和费米能区发现了比热的增强，这可能与最近观察到的Wiedemann-Franz定律违反有关。

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

Pramana 物理-物理：综合

CiteScore

3.60

自引率

7.10%

发文量

206

审稿时长

3 months

期刊介绍： Pramana - Journal of Physics is a monthly research journal in English published by the Indian Academy of Sciences in collaboration with Indian National Science Academy and Indian Physics Association. The journal publishes refereed papers covering current research in Physics, both original contributions - research papers, brief reports or rapid communications - and invited reviews. Pramana also publishes special issues devoted to advances in specific areas of Physics and proceedings of select high quality conferences.