Adding remnant magnetization and anisotropic exchange to propeller-like single-molecule magnets through chemical design

Kátia Cristina M Westrup; Marie-Emmanuelle Boulon; Pasquale Totaro; Giovana G Nunes; Davi F Back; Andersson Barison; Martin Jackson; Carley Paulsen; Dante Gatteschi; Lorenzo Sorace; Andrea Cornia; Jaísa F Soares; Roberta Sessoli

doi:10.1002/chem.201403361

Adding remnant magnetization and anisotropic exchange to propeller-like single-molecule magnets through chemical design

Chemistry. 2014 Oct 13;20(42):13681-91. doi: 10.1002/chem.201403361. Epub 2014 Sep 8.

Authors

Kátia Cristina M Westrup¹, Marie-Emmanuelle Boulon, Pasquale Totaro, Giovana G Nunes, Davi F Back, Andersson Barison, Martin Jackson, Carley Paulsen, Dante Gatteschi, Lorenzo Sorace, Andrea Cornia, Jaísa F Soares, Roberta Sessoli

Affiliation

¹ Departamento de Química, Universidade Federal do Paraná, Centro Politécnico, 81530-900, Curitiba-PR (Brazil).

PMID: 25200792
DOI: 10.1002/chem.201403361

Abstract

The selective replacement of the central iron(III) ion with vanadium(III) in a tetrairon(III) propeller-shaped single-molecule magnet has allowed us to increase the ground spin state from S=5 to S=13/2. As a consequence of the pronounced anisotropy of vanadium(III), the blocking temperature for the magnetization has doubled. Moreover, a significant remnant magnetization, practically absent in the parent homometallic molecule, has been achieved owing to the suppression of zero-field tunneling of the magnetization for the half-integer molecular spin. Interestingly, the contribution of vanadium(III) to the magnetic anisotropy barrier occurs through the anisotropic exchange interaction with iron(III) spins and not through single ion anisotropy as in most single-molecule magnets.

Keywords: iron; magnetic anisotropy; molecular magnetism; single-molecule magnets; vanadium.