| Literature DB >> 33978424 |
Kazuyuki Sakamoto1,2,3,4, Hirotaka Ishikawa3, Takashi Wake3, Chie Ishimoto3, Jun Fujii5, Hendrik Bentmann6, Minoru Ohtaka3, Kenta Kuroda7, Natsu Inoue3, Takuma Hattori7, Toshio Miyamachi7, Fumio Komori7, Isamu Yamamoto8, Cheng Fan3, Peter Krüger3,4, Hiroshi Ota9, Fumihiko Matsui9, Friedrich Reinert6, José Avila10, Maria C Asensio11.
Abstract
Spatially controlling the Fermi level of topological insulators and keeping their electronic states stable are indispensable processes to put this material into practical use for semiconductor spintronics devices. So far, however, such a method has not been established yet. Here we show a novel method for doping a hole into n-type topological insulators Bi2X3 (X= Se, Te) that overcomes the shortcomings of the previous reported methods. The key of this doping is to adsorb H2O on Bi2X3 decorated with a small amount of carbon, and its trigger is the irradiation of a photon with sufficient energy to excite the core electrons of the outermost layer atoms. This method allows controlling the doping amount by the irradiation time and acts as photolithography. Such a tunable doping makes it possible to design the electronic states at the nanometer scale and, thus, paves a promising avenue toward the realization of novel spintronics devices based on topological insulators.Entities:
Keywords: photochemical reaction; photoelectron spectroscopy; photoinduced doping; spintronics; topological insulator
Year: 2021 PMID: 33978424 DOI: 10.1021/acs.nanolett.1c01100
Source DB: PubMed Journal: Nano Lett ISSN: 1530-6984 Impact factor: 11.189