We present muon spin relaxation and H1 NMR results on the magnetically frustrated keplerate molecule { Mo72 Fe30 }, aimed at studying the local spin dynamics as a function of temperature. We find that, in common with other molecular magnets, the relaxation spectrum of this material is characterized by a single dominating electronic correlation time τ. Experiments and theory show that τ has a thermally activated behavior with an activation gap of the order of the energy difference between the lowest-lying rotational bands in this material. This shows that, in the intermediate temperature range just above 1 K, the relaxation of the electronic spin system occurs via Orbach processes involving energy levels belonging to the two lowest-lying rotational bands. Our data thus provide an experimental estimate of the first interband gap.
Low-energy spin dynamics in the giant keplerate molecule {Mo72Fe30} : a muon spin relaxation and H-1 NMR investigation / J. Lago, E. Micotti, M. Corti, A. Lascialfari, A. Bianchi, S. Carretta, P. Santini, D. Procissi, S.H. Baek, P. Kögerler, C. Baines, A. Amato. - In: PHYSICAL REVIEW. B, CONDENSED MATTER AND MATERIALS PHYSICS. - ISSN 1098-0121. - 76:6(2007), p. 064432.064432.
Low-energy spin dynamics in the giant keplerate molecule {Mo72Fe30} : a muon spin relaxation and H-1 NMR investigation
A. Lascialfari;
2007
Abstract
We present muon spin relaxation and H1 NMR results on the magnetically frustrated keplerate molecule { Mo72 Fe30 }, aimed at studying the local spin dynamics as a function of temperature. We find that, in common with other molecular magnets, the relaxation spectrum of this material is characterized by a single dominating electronic correlation time τ. Experiments and theory show that τ has a thermally activated behavior with an activation gap of the order of the energy difference between the lowest-lying rotational bands in this material. This shows that, in the intermediate temperature range just above 1 K, the relaxation of the electronic spin system occurs via Orbach processes involving energy levels belonging to the two lowest-lying rotational bands. Our data thus provide an experimental estimate of the first interband gap.
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