Heat capacity of nonequilibrium electron-hole plasma in graphene layers and graphene bilayers

arXiv: Mesoscale and Nanoscale Physics Pub Date : 2020-11-07 DOI:10.1103/PhysRevB.103.245414
V. Ryzhii, M. Ryzhii, T. Otsuji, V. Mitin, M. Shur
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引用次数: 3

Abstract

We analyze the statistical characteristics of the quasi-nonequilibrium two-dimensional electron-hole plasma in graphene layers (GLs) and graphene bilayers (GBLs) and evaluate their heat capacity.The GL heat capacity of the weakly pumped intrinsic or weakly doped GLs normalized by the Boltzmann constant is equal to $c_{GL} \simeq 6.58$. With varying carrier temperature the intrinsic GBL carrier heat capacity $c_{GBL}$ changes from $c_{GBL} \simeq 2.37$ at $T \lesssim 300$~K to $c_{GBL} \simeq 6.58$ at elevated temperatures. These values are markedly differentfrom the heat capacity of classical two-dimensional carriers with $c = 1$. The obtained results can be useful for the optimization of different GL- and GBL-based high-speed devices.
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石墨烯层和石墨烯双层中非平衡电子空穴等离子体的热容
本文分析了石墨烯层(GLs)和石墨烯双层(GBLs)中准非平衡二维电子空穴等离子体的统计特性,并评估了它们的热容。经玻尔兹曼常数归一化的弱泵浦本征或弱掺杂GLs的GL热容等于$c_{GL} \simeq 6.58$。随着载流子温度的变化,GBL载流子固有热容$c_{GBL}$从$T \lesssim 300$ K时的$c_{GBL} \simeq 2.37$变为升高温度时的$c_{GBL} \simeq 6.58$。这些值与$c = 1$经典二维载流子的热容有明显的不同。所得结果可用于各种基于GL和gbl的高速器件的优化。
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arXiv: Mesoscale and Nanoscale Physics
arXiv: Mesoscale and Nanoscale Physics
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