Topological Spintronics: from the Haldane Phase to Spin Devices
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Abstract
We provide a perspective on the recent emergence of “topological spintronics,” which relies on the existence of helical Dirac electrons in condensed matter. Spin‐ and angle‐resolved photoemission spectroscopy shows how the spin texture of these electronic states can be engineered using quantum tunneling [1] or by breaking time‐reversal symmetry [2]. In appropriately designed systems, broken time‐reversal symmetry transforms helical Dirac states into chiral edge states, a realization of Haldane’s Chern insulator phase of matter. This is characterized by a precisely quantized Hall conductance and dissipationless edge transport without a magnetic field. We show how these edge states can be quantitatively characterized by analyzing their giant anisotropic magnetoresistance [3]. At miilikelvin temperatures, the interplay between Chern states and disordered magnetism [4] results in surprising behavior, perhaps consistent with quantum tunneling out of a ‘false vacuum’ [5]. Finally, we show how these helical Dirac electrons provide a possible pathway toward a spin device technology that works at room temperature [6,7].
Bio
Nitin Samarth is Professor and Associate Head in the Physics Department at The Pennsylvania State University. He completed his undergraduate education in physics at the Indian Institute of Technology (Bombay) and received a Ph.D. in physics from Purdue University. He joined Penn State University after postdoctoral research at the University of Notre Dame. His research centers on the synthesis and study of semiconductor and magnetic quantum structures with a view towards applications in spintronics and quantum information. His group has particular interest in understanding the transport and dynamics of spins in semiconductor systems at length scales ranging from the nanoscale to the mesoscopic. Dr. Samarth is a Fellow of the American Physical Society and a recipient of the Faculty Scholar Medal in Physical Sciences at Penn State.
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References
[1] M. Neupane, A. Richardella et al., Nature Communications 5, 3841 (2014). [2] S.‐Y. Xu et al., Nature Physics 8, 616 (2012). [3] A. Kandala, A. Richardella, et al., Nature Communications 6, 7434 (2015). [4] E. Lachman et al., Science Advances 1, e1500740 (2015). [5] Minhao Liu et al., Science Advances 2, e1600167 (2016). [6] A. Mellnik, J. S. Lee, A. Richardella et al., Nature 511, 449 (2014). [7] Hailong Wang et al., Phys. Rev. Lett. 117, 076601 (2016).
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