Exfoliation of single layer BiTeI flakes

Spin orbit interaction can be strongly boosted when a heavy element is embedded into an inversion asymmetric crystal field. A simple structure to realize this concept in a 2D crystal contains three atomic layers, a middle one built up from heavy elements generating strong atomic spin-orbit interacti...

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Veröffentlicht in:	arXiv.org 2017-09
Hauptverfasser:	Fülöp, Bálint, Tajkov, Zoltán, Pető, János, Kun, Péter, Koltai, János, Oroszlány, László, Tóvári, Endre, Murakawa, Hiroshi, Tokura, Yoshinori, Bordács, Sándor, Tapasztó, Levente, Csonka, Szabolcs
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Schlagworte:	Crystal structure Exfoliation First principles Flakes Gold Heavy elements Heterostructures Locking Physics - Mesoscale and Nanoscale Physics Spin-orbit interactions
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creator	Fülöp, Bálint Tajkov, Zoltán Pető, János Kun, Péter Koltai, János Oroszlány, László Tóvári, Endre Murakawa, Hiroshi Tokura, Yoshinori Bordács, Sándor Tapasztó, Levente Csonka, Szabolcs
description	Spin orbit interaction can be strongly boosted when a heavy element is embedded into an inversion asymmetric crystal field. A simple structure to realize this concept in a 2D crystal contains three atomic layers, a middle one built up from heavy elements generating strong atomic spin-orbit interaction and two neighboring atomic layers with different electron negativity. BiTeI is a promising candidate for such a 2D crystal, since it contains heavy Bi layer between Te and I layers. Recently the bulk form of BiTeI attracted considerable attention due to its giant Rashba interaction, however, 2D form of this crystal was not yet created. In this work we report the first exfoliation of single layer BiTeI using a recently developed exfoliation technique on stripped gold. Our combined scanning probe studies and first principles calculations show that SL BiTeI flakes with sizes of 100 $\mu$m were achieved which are stable at ambient conditions. The giant Rashba splitting and spin-momentum locking of this new member of 2D crystals open the way towards novel spintronic applications and synthetic topological heterostructures.
doi_str_mv	10.48550/arxiv.1709.09732
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A simple structure to realize this concept in a 2D crystal contains three atomic layers, a middle one built up from heavy elements generating strong atomic spin-orbit interaction and two neighboring atomic layers with different electron negativity. BiTeI is a promising candidate for such a 2D crystal, since it contains heavy Bi layer between Te and I layers. Recently the bulk form of BiTeI attracted considerable attention due to its giant Rashba interaction, however, 2D form of this crystal was not yet created. In this work we report the first exfoliation of single layer BiTeI using a recently developed exfoliation technique on stripped gold. Our combined scanning probe studies and first principles calculations show that SL BiTeI flakes with sizes of 100 $\mu$m were achieved which are stable at ambient conditions. 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subjects	Crystal structure Exfoliation First principles Flakes Gold Heavy elements Heterostructures Locking Physics - Mesoscale and Nanoscale Physics Spin-orbit interactions
title	Exfoliation of single layer BiTeI flakes
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