Nanoscale Engineering of Ge-based Diluted Magnetic Semiconductors for Room-Temperature Spintronics Application

Tianxiao Nie, Jianshi Tang, Xufeng Kou, Faxian Xiu, Kang L. Wang

Research output: Chapter in Book/Report/Conference proceedingChapter

2 Citations (Scopus)

Abstract

This chapter gives a systematic investigation of Mn thermal dynamics and kinetics in MnxGe1–x thin film growth. At high growth temperature, Mn preferred to agglomerate to form Mn5Ge3 intermetallic compound, whereas the low growth temperature would induce Mn in the form of Mn-rich MnGe nanocolumn. Furthermore, through engineering of the strain in the Ge space layer, MnGe/Ge superlattice can go through a structural transition from nanocolumn to nanodot and finally to nanowell. To search for the ideal diluted magnetic semiconductor (DMS) system, we focus our study on DMS nanostructures, including QDs, nanodisks, and nanomeshes. Inside, not only high Tc (> 400K) but also electric-field control of ferromagnetism can be realized. Based on this extraordinary property, a transpinor device is proposed in which DMS nanostructures are used as the channel for collective spins switching controlled by gate voltage without need of current flow. And thus, it paves a new way for realizing low power-dissipation spin effect transistor.

Original languageEnglish
Title of host publicationMolecular Beam Epitaxy
Subtitle of host publicationfrom Research to Mass Production
PublisherElsevier
Pages403-419
Number of pages17
ISBN (Electronic)9780128121368
ISBN (Print)9780128121375
DOIs
Publication statusPublished - 2018 Jan 1

All Science Journal Classification (ASJC) codes

  • General Physics and Astronomy

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