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Engineering the magnetic coupling and anisotropy at the molecule–magnetic surface interface in molecular spintronic devices

Controlling the magnetic response of a molecular device is important for spintronic applications. Here the authors report the self-assembly, magnetic coupling, and anisotropy of two transition metal complexes bound to a ferrimagnetic surface, and probe the role of the nature of the transition metal ion.

Victoria E. Campbell
Monica Tonelli
Talal Mallah
ResearchOpen Access08 Dec 2016
Nature Communications

Volume: 7, P: 1-10
Enhancing the magnetic anisotropy of maghemite nanoparticles via the surface coordination of molecular complexes

The enhancement of the magnetic anisotropy of superparamagnetic nanoparticles may increase their functionality. Here, the authors report that the functionalization of maghemite nanoparticles with cobalt(II) complexes enhances their magnetic anisotropy, and subsequently blocking temperature and coercive field.

Yoann Prado
Niéli Daffé
Jérôme Fresnais
ResearchOpen Access04 Dec 2015
Nature Communications

Volume: 6, P: 1-8
Magnetic behaviour of TbPc₂ single-molecule magnets chemically grafted on silicon surface

Single-molecule magnets exhibit magnetic hysteresis below a certain temperature. Mannini et al. now show that grafting such molecules onto a silicon substrate can enhance their magnetic bistability.

Matteo Mannini
Federico Bertani
Roberta Sessoli
Research11 Aug 2014
Nature Communications

Volume: 5, P: 1-8
Magnetic memory of a single-molecule quantum magnet wired to a gold surface

Molecular magnets are promising for their use as high-density memory devices. However, maintaining the molecules’ magnetic state when bonded to a substrate has been impossible. The discovery, in sophisticated experiments, that single magnetic molecules can indeed show magnetic hysteresis when wired to a gold surface opens the door to individually address magnetic molecules.

Matteo Mannini
Francesco Pineider
Roberta Sessoli
Research01 Feb 2009
Nature Materials

Volume: 8, P: 194-197
Magnetic molecules as local sensors of topological hysteresis of superconductors

Magnetic molecules have long been seen to hold promise in magnetic sensing applications. In this paper, Serrano et al show that a single layer of a magnetic molecule, a terbium based complex, is sensitive to the local magnetic field variation of a superconducting surface on which it is deposited.

Giulia Serrano
Lorenzo Poggini
Roberta Sessoli
ResearchOpen Access04 Jul 2022
Nature Communications

Volume: 13, P: 1-7
Quantum dynamics of a single molecule magnet on superconducting Pb(111)

A superconducting transition is used to switch a single molecule magnet from a blocked magnetization state to a resonant quantum tunnelling regime

Giulia Serrano
Lorenzo Poggini
Roberta Sessoli
Research17 Feb 2020
Nature Materials

Volume: 19, P: 546-551

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Engineering the magnetic coupling and anisotropy at the molecule–magnetic surface interface in molecular spintronic devices

Enhancing the magnetic anisotropy of maghemite nanoparticles via the surface coordination of molecular complexes

Magnetic behaviour of TbPc2 single-molecule magnets chemically grafted on silicon surface

Magnetic memory of a single-molecule quantum magnet wired to a gold surface

Magnetic molecules as local sensors of topological hysteresis of superconductors

Quantum dynamics of a single molecule magnet on superconducting Pb(111)

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Magnetic behaviour of TbPc₂ single-molecule magnets chemically grafted on silicon surface