Electromagnetic functionalization of wide-bandgap dielectric oxides by boron interstitial doping

Dae-sung Park, Gregory J. Rees, Haiyuan Wang, Diana Rata, Andrew J. Morris, Igor V. Maznichenko, Sergey Ostanin, Akash Bhatnagar, Chel-jong Choi, Ragnar D. B. Jónsson, Kai Kaufmann, Reza Kashtiban, Marc Walker, Cheng-tien Chiang, Einar B. Thorsteinsson, Zhengdong Luo, In-sung Park, John V. Hanna, Ingrid Mertig, Kathrin DörrHafliði P. Gíslason, Chris F. Mcconville

Research output: Contribution to journalArticlepeer-review

2 Citations (Scopus)
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Abstract

A surge in interest of oxide‐based materials is testimony for their potential utility in a wide array of device applications and offers a fascinating landscape for tuning the functional properties through a variety of physical and chemical parameters. In particular, selective electronic/defect doping has been demonstrated to be vital in tailoring novel functionalities, not existing in the bulk host oxides. Here, an extraordinary interstitial doping effect is demonstrated centered around a light element, boron (B). The host matrix is a novel composite system, made from discrete bulk LaAlO3:LaBO3 compounds. The findings show a spontaneous ordering of the interstitial B cations within the host LaAlO3 lattices, and subsequent spin‐polarized charge injection into the neighboring cations. This leads to a series of remarkable cation‐dominated electrical switching and high‐temperature ferromagnetism. Hence, the induced interstitial doping serves to transform a nonmagnetic insulating bulk oxide into a ferromagnetic ionic–electronic conductor. This unique interstitial B doping effect upon its control is proposed to be as a general route for extracting/modifying multifunctional properties in bulk oxides utilized in energy and spin‐based applications.
Original languageEnglish
Article number1802025
Number of pages9
JournalAdvanced Materials
Volume30
Issue number39
Early online date21 Aug 2018
DOIs
Publication statusPublished - 26 Sept 2018

Keywords

  • first-principle calculations
  • light element interstitial doping
  • oxide composites
  • resistive switching
  • Stoner ferromagnetism

ASJC Scopus subject areas

  • General Materials Science
  • Mechanics of Materials
  • Mechanical Engineering

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