Hidden orbital polarization in diamond, silicon, germanium, gallium arsenide and layered materials

It was previously believed that the Bloch electronic states of non-magnetic materials with inversion symmetry cannot have finite spin polarizations. However, since the seminal work by Zhang et al. ( Nat. Phys. 10, 387–393 (2014)) on local spin polarizations of Bloch states in non-magnetic, centrosym...

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Bibliographic Details
Published in:NPG Asia materials 2017-05, Vol.9 (5), p.e382-e382
Main Authors: Ryoo, Ji Hoon, Park, Cheol-Hwan
Format: Article
Language:English
Subjects:
639/301/1034/1038
639/301/119/1001
639/301/119/995
Aluminum
Angular momentum
Antiferromagnetism
Arsenides
Biomaterials
Chemistry and Materials Science
Compressing
Diamonds
Electron spin
Electron states
Energy Systems
Gallium arsenide
Germanium
Information technology
Intermetallic compounds
Layered materials
Magnetic materials
Materials Science
Mathematical analysis
Molybdenum disulfide
Optical and Electronic Materials
original-article
Photoelectric emission
Polarization
Signatures
Silicon
Spin-orbit interactions
Spintronics
Structural Materials
Surface and Interface Science
Thin Films
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Summary:It was previously believed that the Bloch electronic states of non-magnetic materials with inversion symmetry cannot have finite spin polarizations. However, since the seminal work by Zhang et al. ( Nat. Phys. 10, 387–393 (2014)) on local spin polarizations of Bloch states in non-magnetic, centrosymmetric materials, the scope of spintronics has been significantly broadened. Here, we show, using a framework that is universally applicable independent of whether hidden spin polarizations are small (e.g., diamond, Si, Ge and GaAs) or large (e.g., MoS 2 and WSe 2 ), that the corresponding quantity arising from orbital—instead of spin—degrees of freedom, the hidden orbital polarization is (i) much more abundant in nature since it exists even without spin–orbit coupling and (ii) more fundamental since the interband matrix elements of the site-dependent orbital angular momentum operator determine the hidden spin polarization. We predict that the hidden spin polarization of transition metal dichalcogenides is reduced significantly upon compression. We suggest experimental signatures of hidden orbital polarization from photoemission spectroscopies and demonstrate that the current-induced hidden orbital polarization may play a far more important role than its spin counterpart in antiferromagnetic information technology by calculating the current-driven antiferromagnetism in compressed silicon. Spintronics: Magnetism in non-magnetic materials Some non-magnetic substances may exhibit the useful properties of magnetic materials according to scientists in Korea. Spintronics, which uses the spin of an electron for information processing, promises a new generation of low power consumption devices. It has conventionally required magnetic materials, or a restricted class of non-magnetic materials with broken spatial-inversion symmetry. However, the number of material choices available for these applications was expanded with the recent discovery that some other non-magnetic substances also exhibit measurable spin-like effects. Now, Ji Hoon Ryoo and Cheol-Hwan Park from Seoul National University have demonstrated that the previously undiscovered magnetism in non-magnetic materials such as common semiconductor silicon and gallium arsenide arises from so-called hidden orbital polarization, namely coordinated orbital motion of electrons around different atoms, mimicking the spins that determine the characteristics of magnets. Recently, it was found that an electronic state can h
ISSN:1884-4049
1884-4057
1884-4057
DOI:10.1038/am.2017.67