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Toward Tailored All-Spin Molecular Devices

Author(s):

Maciej Bazarnik, Bernhard Bugenhage, Micha Elsebach, Emil Sierda, Annika Frank, Marc H. Prosenc, Roland Wiesendanger

Journal:

Nano Letters

Year:

2016

Volume:

16

Pages

577–582

DOI:

10.1021/acs.nanolett.5b04266

Abstract:

Molecular based spintronic devices offer great potential for future energy-efficient information technology as they combine ultimately small size, high-speed operation, and low-power consumption. Recent developments in combining atom-by-atom assembly with spin-sensitive imaging and characterization at the atomic level have led to a first prototype of an all-spin atomic-scale logic device, but the very low working temperature limits its application. Here, we show that a more stable spintronic device could be achieved using tailored Co-Salophene based molecular building blocks, combined with in situ electrospray deposition under ultrahigh vacuum conditions as well as control of the surface-confined molecular assembly at the nanometer scale. In particular, we describe the tools to build a molecular, strongly bonded device structure from paramagnetic molecular building blocks including spin-wires, gates, and tails. Such molecular device concepts offer the advantage of inherent parallel fabrication based on molecular self-assembly as well as an order of magnitude higher operation temperatures due to enhanced energy scales of covalent through-bond linkage of basic molecular units compared to substrate- mediated coupling schemes employing indirect exchange coupling between individual adsorbed magnetic atoms on surfaces.

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