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狄拉克等离子体在高迁移率石墨烯中的巨磁电阻。

Giant magnetoresistance of Dirac plasma in high-mobility graphene.

机构信息

Department of Physics and Astronomy, University of Manchester, Manchester, UK.

National Graphene Institute, University of Manchester, Manchester, UK.

出版信息

Nature. 2023 Apr;616(7956):270-274. doi: 10.1038/s41586-023-05807-0. Epub 2023 Apr 12.

DOI:10.1038/s41586-023-05807-0
PMID:37045919
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10097601/
Abstract

The most recognizable feature of graphene's electronic spectrum is its Dirac point, around which interesting phenomena tend to cluster. At low temperatures, the intrinsic behaviour in this regime is often obscured by charge inhomogeneity but thermal excitations can overcome the disorder at elevated temperatures and create an electron-hole plasma of Dirac fermions. The Dirac plasma has been found to exhibit unusual properties, including quantum-critical scattering and hydrodynamic flow. However, little is known about the plasma's behaviour in magnetic fields. Here we report magnetotransport in this quantum-critical regime. In low fields, the plasma exhibits giant parabolic magnetoresistivity reaching more than 100 per cent in a magnetic field of 0.1 tesla at room temperature. This is orders-of-magnitude higher than magnetoresistivity found in any other system at such temperatures. We show that this behaviour is unique to monolayer graphene, being underpinned by its massless spectrum and ultrahigh mobility, despite frequent (Planckian limit) scattering. With the onset of Landau quantization in a magnetic field of a few tesla, where the electron-hole plasma resides entirely on the zeroth Landau level, giant linear magnetoresistivity emerges. It is nearly independent of temperature and can be suppressed by proximity screening, indicating a many-body origin. Clear parallels with magnetotransport in strange metals and so-called quantum linear magnetoresistance predicted for Weyl metals offer an interesting opportunity to further explore relevant physics using this well defined quantum-critical two-dimensional system.

摘要

石墨烯电子能谱最显著的特征是其狄拉克点,围绕该点往往会聚集有趣的现象。在低温下,该能区的本征行为常常被电荷非均匀性所掩盖,但热激发可以克服高温下的无序,在狄拉克费米子中产生电子-空穴等离子体。已经发现狄拉克等离子体具有反常的性质,包括量子临界散射和流体动力学流动。然而,人们对磁场中等离子体的行为知之甚少。在这里,我们报告了该量子临界区的磁输运。在低场下,等离子体表现出巨大的抛物型磁阻效应,在室温下磁场为 0.1 特斯拉时,磁阻率超过 100%。这比在相同温度下任何其他系统中发现的磁阻率都要高出几个数量级。我们表明,这种行为是单层石墨烯所特有的,尽管经常发生(普朗克极限)散射,但这是由其无质量谱和超高迁移率支撑的。随着磁场几特斯拉的朗道量子化的出现,电子-空穴等离子体完全位于零级朗道能级上,巨大的线性磁阻率出现。它几乎与温度无关,可以通过近邻屏蔽来抑制,这表明它具有多体起源。与奇异金属中的磁输运以及所谓的 Weyl 金属中预测的量子线性磁阻率之间存在明显的相似之处,为利用这个定义明确的二维量子临界系统进一步探索相关物理提供了一个有趣的机会。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/55d1/10097601/539db44e6188/41586_2023_5807_Fig8_ESM.jpg
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