posted on 2017-06-22, 00:00authored bySukrit Sucharitakul, Gaihua Ye, Walter R. L. Lambrecht, Churna Bhandari, Axel Gross, Rui He, Hilde Poelman, Xuan P. A. Gao
V2O5 with a layered van der Waals (vdW) structure has been widely
studied because of the material’s potential in applications
such as battery electrodes. In this work, microelectronic devices
were fabricated to study the electrical and optical properties of
mechanically exfoliated multilayered V2O5 flakes.
Raman spectroscopy was used to determine the crystal structure axes
of the nanoflakes and revealed that the intensities of the Raman modes
depend strongly on the relative orientation between the crystal axes
and the polarization directions of incident/scattered light. Angular
dependence of four-probe resistance measured in the van der Pauw (vdP)
configuration revealed an in-plane anisotropic resistance ratio of
∼100 between the a and b crystal
axes, the largest in-plane transport anisotropy effect experimentally
reported for two-dimensional (2D) materials to date. This very large
resistance anisotropic ratio is explained by the nonuniform current
flow in the vdP measurement and an intrinsic mobility anisotropy ratio
of 10 between the a and b crystal
axes. Room-temperature electron Hall mobility up to 7 cm2/(V s) along the high-mobility direction was obtained. This work
demonstrates V2O5 as a layered 2D vdW oxide
material with strongly anisotropic optical and electronic properties
for novel applications.