STATIC AND DYNAMIC PROPERTIES OF MOLECULAR NANOMAGNETS INVESTIGATED
![Phonon trapping in Ni 10 [1]. The superparamagnetic slowing down of the magnetization in](https://slidetodoc.com/presentation_image_h/33ac1808edce9aa7808f22acaa1bba20/image-3.jpg "Phonon trapping in Ni 10 [1]. The superparamagnetic slowing down of the magnetization in")
![Heterometallic rings Static effects [2] The redistribution of the local spin 53 density can](https://slidetodoc.com/presentation_image_h/33ac1808edce9aa7808f22acaa1bba20/image-4.jpg "Heterometallic rings Static effects [2] The redistribution of the local spin 53 density can")
![Heterometallic rings Dynamic effects [3, 4] The shift in the NMR relaxation rate between](https://slidetodoc.com/presentation_image_h/33ac1808edce9aa7808f22acaa1bba20/image-5.jpg "Heterometallic rings Dynamic effects [3, 4] The shift in the NMR relaxation rate between")
![Single molecule paramagnets [5] The susceptibility is Curie- like down to very low temperature](https://slidetodoc.com/presentation_image_h/33ac1808edce9aa7808f22acaa1bba20/image-6.jpg "Single molecule paramagnets [5] The susceptibility is Curie- like down to very low temperature")
![Single molecule paramagnets [5] The proton NMR spin-lattice relaxation rate is weakly T dependent](https://slidetodoc.com/presentation_image_h/33ac1808edce9aa7808f22acaa1bba20/image-7.jpg "Single molecule paramagnets [5] The proton NMR spin-lattice relaxation rate is weakly T dependent")
![References [1] Belesi et. al, PRL 102, 177201(2009) [2] Micoti et al. , PRL](https://slidetodoc.com/presentation_image_h/33ac1808edce9aa7808f22acaa1bba20/image-8.jpg "References [1] Belesi et. al, PRL 102, 177201(2009) [2] Micoti et al. , PRL")
- Slides: 8
STATIC AND DYNAMIC PROPERTIES OF MOLECULAR NANOMAGNETS INVESTIGATED BY NMR M. Mariani 1, 2, M. Belesi 1, H. Amiri 1, A. Lascialfari 1, 2, 3, F. Borsa 1, P. Khuntia 1, F. Orsini 2, 3, P. Arosio 3, A. Cornia 4, R. Winpenny 5, E. Mc Innes 5, M. Andruh 6, P. Santini 2, 7, S. Carretta 2, 7, G. Amoretti 2, 7 1 Dipartimento di Fisica “A. Volta” e Unita’ CNISM , Universita’ di Pavia, Italy 2 S 3 -CNR-INFM, Modena, Italy 3 DISMAB, Universita` degli studi di Milano, Italy 4 Dipartimento di Chimica e INSTM, Università di Modena, Italy 5 Department of Chemistry, University of Manchester, UK 6 Inorg. Chemistry Laboratory, University of Bucharest, Romania 7 Dipartimento di Fisica, Università degli studi di Parma, Italy
The subject Molecular nanomagnets are organic molecules with a limited number of magnetic ions where the intramolecular magnetic interactions are dominant over the intermolecular interaction. IDEAL MODEL SYSTEMS TO INVESTIGATE NANOMAGNETISM We show here three broad classes of nanomagnets showing interesting properties and where NMR has given relevant information
Phonon trapping in Ni 10 [1]. The superparamagnetic slowing down of the magnetization in Ni 10 nanomagnet is not due to an anisotropy barrier ( as e. g. in Fe 8) but rather to a novel phonon trapping phenomenon as demonstrated by the persistence of a narrow proton NMR line even at low T
Heterometallic rings Static effects [2] The redistribution of the local spin 53 density can be probed by Cr NMR in a Cr 8 ring where one Cr ion is replaced by a diamagnetic Cd ion
Heterometallic rings Dynamic effects [3, 4] The shift in the NMR relaxation rate between the Cr 7 Fe and Cr 7 Ni is related to the different perturbation effects of the Fe and Ni ions on the spin dynamics
Single molecule paramagnets [5] The susceptibility is Curie- like down to very low temperature with J =+0. 14 K in Cu 6 Fe and J = -1. 12 K in Cu 6 Co
Single molecule paramagnets [5] The proton NMR spin-lattice relaxation rate is weakly T dependent down to 4 K as in bulk paramagnets
References [1] Belesi et. al, PRL 102, 177201(2009) [2] Micoti et al. , PRL 97, 267204 (2006) [3] H. Amiri et al. , umpublished [4] S. Carretta et al, . umpublished [5] P. Khuntia et al, . PRB 80, 094413 (2009)