Investigating the Intrinsic Anisotropy of VO2(101) Thin Films Using Linearly Polarized Resonant Photoemission Spectroscopy

IF 1.9 Q3 PHYSICS, CONDENSED MATTER

Condensed Matter Pub Date : 2023-04-26 DOI:10.3390/condmat8020040

A. D’Elia, V. Polewczyk, A. Petrov, Liangbin Li, C. Zou, J. Rezvani, A. Marcelli

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Abstract

VO2 is one of the most studied vanadium oxides because it undergoes a reversible metal-insulator transition (MIT) upon heating with a critical temperature of around 340 K. One of the most overlooked aspects of VO2 is the band’s anisotropy in the metallic phase when the Fermi level is crossed by two bands: π* and d||. They are oriented perpendicularly in one respect to the other, hence generating anisotropy. One of the parameters tuning MIT properties is the unbalance of the electron population of π* and d|| bands that arise from their different energy position with respect to the Fermi level. In systems with reduced dimensionality, the electron population disproportion is different with respect to the bulk leading to a different anisotropy. Investigating such a system with a band-selective spectroscopic tool is mandatory. In this manuscript, we show the results of the investigation of a single crystalline 8 nm VO2/TiO2(101) film. We report on the effectiveness of linearly polarized resonant photoemission (ResPES) as a band-selective technique probing the intrinsic anisotropy of VO2.

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用线性偏振共振发光光谱研究VO2（101）薄膜的本征各向异性

VO2是研究最多的钒氧化物之一，因为它在340K左右的临界温度下加热时会经历可逆的金属-绝缘体转变（MIT）。VO2最被忽视的方面之一是当费米能级被π*和d||两个带穿过时，金属相中的带的各向异性。它们在一个方面与另一个方面垂直定向，因此产生各向异性。调节MIT性质的参数之一是π*和d||带的电子布居的不平衡，这是由于它们相对于费米能级的不同能量位置引起的。在维数降低的系统中，电子布居比例相对于体积不同，导致不同的各向异性。用波段选择光谱工具研究这样的系统是强制性的。在本文中，我们展示了对8nm VO2/TiO2（101）单晶膜的研究结果。我们报道了线偏振共振光电发射（ResPES）作为一种探测VO2本征各向异性的带选择技术的有效性。

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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