Thickness-Dependent Polaron Crossover in Tellurene

arXiv - PHYS - Mesoscale and Nanoscale Physics Pub Date : 2024-09-13 DOI:arxiv-2409.08458

Kunyan Zhang, Chuliang Fu, Shelly Kelly, Liangbo Liang, Seoung-Hun Kang, Jing Jiang, Ruifang Zhang, Yixiu Wang, Gang Wan, Phum Siriviboon, Mina Yoon, Peide Ye, Wenzhuo Wu, Mingda Li, Shengxi Huang

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Abstract

Polarons, quasiparticles arising from electron-phonon coupling, are crucial in understanding material properties such as high-temperature superconductivity and colossal magnetoresistance. However, scarce studies have been performed to investigate the formation of polarons in low-dimensional materials with phonon polarity and electronic structure transitions. In this work, we studied polarons of tellurene that are composed of chiral chains of tellurium atoms. The frequency and linewidth of the A1 phonon, which becomes increasingly polar for thinner tellurene, exhibit an abrupt change when the thickness of tellurene is below 10 nm. Meanwhile, the field effect mobility of tellurene drops rapidly as the thickness is smaller than 10 nm. These phonon and transport signatures, combined with the calculated phonon polarity and band structure, suggest a crossover from large polarons for bulk tellurium to small polarons for few-layer tellurene. Effective field theory considers the phonon renormalization in the strong coupling (small polaron) regime, and semi-quantitatively reproduces the observed phonon hardening and broadening effects in few-layer tellurene. This polaron crossover stems from the quasi-1D nature of tellurene where modulation of the interchain distance reduces the dielectric screening and promotes electron-phonon coupling. Our work provides valuable insights into the influence of polarons on phononic, electronic, and structural properties in low-dimensional materials.

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碲中厚度相关的极龙交叉

极子是电子-声子耦合产生的准粒子，在理解高温超导性和巨大磁阻等材料特性方面至关重要。然而，人们对低维材料中极子的形成与声子极性和电子结构转变的研究还很少。在这项工作中，我们研究了由碲原子手性链组成的碲烯的极子。当碲烯的厚度低于 10 nm 时，A1 声子的频率和线宽发生了突变，其极性随碲烯厚度的增加而增加。同时，当碲的厚度小于 10 纳米时，碲的场效应迁移率迅速下降。这些声子和输运特征与计算得出的声子极性和能带结构相结合，表明了从大块碲的大极子到几层碲的小极子的跨越。有效场理论考虑了强耦合（小极子）机制中的声子归一化，并半定量地再现了在几层碲中观察到的声子硬化和展宽效应。这种极子交叉源于碲的准一维性质，其中链间距离的调节降低了介电屏蔽，促进了电子-声子耦合。我们的工作为深入了解极子对低维材料的声子、电子和结构特性的影响提供了宝贵的见解。

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arXiv - PHYS - Mesoscale and Nanoscale Physics

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