Independent and coherent transitions between antiferromagnetic states of   few-molecule systems

Claire Besson (1; 2); Philipp Stegmann (3; 4); Michael Schnee; (2); Zeila Zanolli (5; 6); Simona Achilli (6; 7); Nils Wittemeier (6),; Asmus Vierck (8); Robert Frielinghaus (2); Paul K\"ogerler (9; 2); Janina; Maultzsch (10; 8); Pablo Ordej\'on (6); Claus M. Schneider (2); Alfred; Hucht (3); J\"urgen K\"onig (3); Carola Meyer (11; 2) ((1) Department of; Chemistry; The George Washington University; Washington DC; USA; (2) Peter; Gr\"unberg Institut (PGI-6); Forschungszentrum J\"ulich; J\"ulich Aachen; Research Alliance (JARA)-Fundamentals of Future Information Technology,; J\"ulich; Germany; (3) Theoretische Physik; Universit\"at Duisburg-Essen and; CENIDE; Duisburg; Germany; (4) Department of Chemistry; Massachusetts; Institute of Technology; Cambridge; Massachusetts; USA; (5) Chemistry; Department; ETSF; Debye Institute for Nanomaterials Science; Condensed; Matter; Interfaces; Utrecht University; Utrecht; The Netherlands; (6); Catalan Institute of Nanoscience; Nanotechnology (ICN2); CSIC; BIST,; Campus UAB; Bellaterra; Barcelona; Spain; (7) Dipartimento di Fisica "Aldo; Pontremoli"; Universit\'a degli Studi di Milano; Milan; Italy; (8) Institut; f\"ur Festk\"orperphysik; Technische Universit\"at Berlin; Berlin; Germany,; (9) Institute of Inorganic Chemistry; RWTH Aachen University; Aachen,; Germany; (10) Department of Physics; Friedrich-Alexander University; Erlangen-N\"urnberg; Erlangen; Germany; (11) Fachbereich Physik,; Universit\"at Osnabr\"uck; Osnabr\"uck; Germany)

arXiv:2107.07723·cond-mat.mes-hall·June 22, 2023

Independent and coherent transitions between antiferromagnetic states of few-molecule systems

Claire Besson (1, 2), Philipp Stegmann (3, 4), Michael Schnee, (2), Zeila Zanolli (5, 6), Simona Achilli (6, 7), Nils Wittemeier (6),, Asmus Vierck (8), Robert Frielinghaus (2), Paul K\"ogerler (9, 2), Janina, Maultzsch (10, 8), Pablo Ordej\'on (6), Claus M. Schneider (2)

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TL;DR

This study demonstrates the ability to control and detect antiferromagnetic states in individual molecules using quantum transport in nanotube devices, revealing independent and coherent switching behaviors.

Contribution

It introduces a novel detection scheme for molecular spin states that does not depend on magnetic moments, enabling the study of antiferromagnetic molecules at the single-molecule level.

Findings

01

Cobalt complexes switch independently, showing stochastic behavior.

02

Manganese complexes exhibit coherent superposition of spin states.

03

Long coherence times of several seconds at 100 mK achieved in manganese complexes.

Abstract

Spin-electronic devices are poised to become part of mainstream microelectronic technology .Downsizing them, however, faces the intrinsic difficulty that as ferromagnets become smaller, it becomes more difficult to stabilize their magnetic moment. Antiferromagnets are much more stable, and thus research on antiferromagnetic spintronics has developed into a fast-growing field. Here, we provide proof of concept data that allows us to expand the area of antiferromagnetic spintronics to the hitherto elusive level of individual molecules. In contrast to all previous work on molecular spintronics, our detection scheme of the molecule's spin state does not rely on a magnetic moment. Instead, we use field-effect transistor devices constituting of an isolated, contacted single-wall carbon nanotube covalently bound to a limited number of molecular antiferromagnets incorporating four Mn(II) or…

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Taxonomy

TopicsMolecular Junctions and Nanostructures · Quantum and electron transport phenomena · Force Microscopy Techniques and Applications