Orbital-Driven Rashba Effect in a Binary Honeycomb Monolayer AgTe

Orbital-Driven Rashba Effect in a Binary Honeycomb Monolayer AgTe

The Rashba effect is fundamental to the physics of two-dimensional electron systems and underlies a variety of spintronic phenomena. It has been proposed that the formation of Rashba-type spin splittings originates microscopically from the existence of orbital angular momentum (OAM) in the Bloch wav...

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Veröffentlicht in:Physical review letters 2020-05, Vol.124 (17), p.176401, Article 176401
Hauptverfasser: Unzelmann, Maximilian, Bentmann, Hendrik, Eck, Philipp, Kisslinger, Tilman, Geldiyev, Begmuhammet, Rieger, Janek, Moser, Simon, Vidal, Raphael C., Kissner, Katharina, Hammer, Lutz, Schneider, M. Alexander, Fauster, Thomas, Sangiovanni, Giorgio, Di Sante, Domenico, Reinert, Friedrich
Format: Artikel
Sprache:eng
Schlagworte:
Angular momentum
Bloch waves
First principles
Low energy electron diffraction
Mathematical analysis
Monolayers
Photoelectric emission
Physical Sciences
Physics
Physics, Multidisciplinary
Science & Technology
Silver compounds
Tellurides
Wave functions
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Zusammenfassung:The Rashba effect is fundamental to the physics of two-dimensional electron systems and underlies a variety of spintronic phenomena. It has been proposed that the formation of Rashba-type spin splittings originates microscopically from the existence of orbital angular momentum (OAM) in the Bloch wave functions. Here, we present detailed experimental evidence for this OAM-based origin of the Rashba effect by angle-resolved photoemission (ARPES) and two-photon photoemission experiments for a monolayer AgTe on Ag(111). Using quantitative low-energy electron diffraction analysis, we determine the structural parameters and the stacking of the honeycomb overlayer with picometer precision. Based on an orbitalsymmetry analysis in ARPES and supported by first-principles calculations, we unequivocally relate the presence and absence of Rashba-type spin splittings in different bands of AgTe to the existence of OAM.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.124.176401