The direct exchange mechanism of induced spin polarization of low-dimensional π-conjugated carbon- and h-BN fragments at LSMO(001) MnO-terminated interfaces

Artem V. Kuklin, Alexander A. Kuzubov, Evgenia A. Kovaleva, Hyosun Lee, Pavel B. Sorokin, Seiji Sakai, Shiro Entani, Hiroshi Naramoto, Paul Avramov

Research output: Contribution to journalArticlepeer-review

2 Scopus citations

Abstract

Induced spin polarization of π-conjugated carbon and h-BN low dimensional fragments at the interfaces formed by deposition of pentacene molecule and narrow zigzag graphene and h-BN nanoribbons on MnO2-terminated LSMO(001) thin film was studied using GGA PBE+U PAW D3-corrected approach. Induced spin polarization of π-conjugated low-dimensional fragments is caused by direct exchange with Mn ions of LSMO(001) MnO-derived surface. Due to direct exchange, the pentacene molecule changes its diamagnetic narrow-band gap semiconducting nature to the ferromagnetic semiconducting state with 0.15 eV energy shift between spin-up and spin-down valence bands and total magnetic moment of 0.11 μB. Direct exchange converts graphene nanoribbon to 100% spin-polarized half-metal with large amplitude of spin-up electronic density at the Fermi level. The direct exchange narrows the h-BN nanoribbon band gap from 4.04 to 1.72 eV in spin-up channel and converts the h-BN ribbon semiconducting diamagnetic nature to a semiconducting magnetic one. The electronic structure calculations demonstrate a possibility to control the spin properties of low-dimensional π-conjugated carbon and h-BN fragments by direct exchange with MnO-derived LSMO(001) surface for spin-related applications.

Original languageEnglish
Pages (from-to)23-29
Number of pages7
JournalJournal of Magnetism and Magnetic Materials
Volume440
DOIs
StatePublished - 15 Oct 2017

Keywords

  • DFT
  • Graphene nanoribbons
  • h-BN nanoribbons
  • Half-metal
  • Induced spin polarization
  • LSMO thin films

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