APS March Meeting 2016
Volume 61, Number 2
Monday–Friday, March 14–18, 2016;
Baltimore, Maryland
Session C28: Quantum Anomalous Hall Effect I
2:30 PM–5:30 PM,
Monday, March 14, 2016
Room: 327
Sponsoring
Unit:
DMP
Chair: Nikesh Koirala, Rutgers University
Abstract ID: BAPS.2016.MAR.C28.1
Abstract: C28.00001 : Achieving High-Temperature Ferromagnetic Topological Insulator
2:30 PM–3:06 PM
Preview Abstract
Abstract
Author:
Ferhat Katmis
(Massachusetts Institute of Technology)
Topological insulators (TIs) are insulating materials that display
conducting surface states protected by time-reversal symmetry, wherein
electron spins are locked to their momentum. This unique property opens new
opportunities for creating next-generation electronic and spintronic
devices, including TI-based quantum computation. Introducing ferromagnetic
order into a TI system without compromising its distinctive quantum coherent
features could lead to a realization of several predicted novel physical
phenomena. In particular, achieving robust long-range magnetic order at the
TI surface at specific locations without introducing spin scattering centers
could open up new possibilities for devices. Here, we demonstrate
topologically enhanced interface magnetism by coupling a ferromagnetic
insulator (FMI) to a TI (Bi2Se3); this interfacial ferromagnetism persists
up to room temperature, even though the FMI (EuS) is known to order
ferromagnetically only at low temperatures (\textless 17 K). The induced
magnetism at the interface resulting from the large spin-orbit interaction
and spin-momentum locking feature of the TI surface is found to greatly
enhance the magnetic ordering (Curie) temperature of the TI/FMI bilayer
system. Due to the short range nature of the ferromagnetic exchange
interaction, the time-reversal symmetry is broken only near the surface of a
TI, while leaving its bulk states unaffected. The topological
magneto-electric response originating in such an engineered TI could allow
for an efficient manipulation of the magnetization dynamics by an electric
field, providing an energy efficient topological control mechanism for
future spin-based technologies. Work supported by MIT MRSEC through the
MRSEC Program of NSF under award number DMR-0819762, NSF Grant DMR-1207469,
the ONR Grant N00014-13-1-0301, and the STC Center for Integrated Quantum
Materials under NSF grant DMR-1231319.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2016.MAR.C28.1