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Lui, M., Ramos, C. A., King, A. R., Jaccarino, V. (1990) Antiferromagnetic standing‐spin‐wave resonance in epitaxial films of MnF2. Journal of Applied Physics, 67 (9). 5518-5520 doi:10.1063/1.345870

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Reference TypeJournal (article/letter/editorial)
TitleAntiferromagnetic standing‐spin‐wave resonance in epitaxial films of MnF2
JournalJournal of Applied Physics
AuthorsLui, M.Author
Ramos, C. A.Author
King, A. R.Author
Jaccarino, V.Author
Year1990 (May)Volume67
Issue9
PublisherAIP Publishing
DOIdoi:10.1063/1.345870Search in ResearchGate
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Mindat Ref. ID5046467Long-form Identifiermindat:1:5:5046467:8
GUID0
Full ReferenceLui, M., Ramos, C. A., King, A. R., Jaccarino, V. (1990) Antiferromagnetic standing‐spin‐wave resonance in epitaxial films of MnF2. Journal of Applied Physics, 67 (9). 5518-5520 doi:10.1063/1.345870
Plain TextLui, M., Ramos, C. A., King, A. R., Jaccarino, V. (1990) Antiferromagnetic standing‐spin‐wave resonance in epitaxial films of MnF2. Journal of Applied Physics, 67 (9). 5518-5520 doi:10.1063/1.345870
In(1990, May) Journal of Applied Physics Vol. 67 (9) AIP Publishing

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Lui, M., Drucker, J., King, A. R., Kotthaus, J. P., Hansma, P. K., Jaccarino, V. (1986) Observation of antiferromagnetic resonance in epitaxial films ofMnF2. Physical Review B, 33 (11) 7720-7723 doi:10.1103/physrevb.33.7720
Felcher, G. P., Kleb, R., Jaccarino, V. (1997) Antiferromagnetic domains and the spin–flop transition in MnF2 (abstract). Journal of Applied Physics, 81 (8). 4075 doi:10.1063/1.365082
Kaplan, N., Pincus, P., Jaccarino, V. (1966) 19F NMR Spin Echo in Antiferromagnetic MnF2. Journal of Applied Physics, 37 (3). 1239-1241 doi:10.1063/1.1708414
Lui, M., King, A. R., Jaccarino, V., Snider, G. L. (1989) Critical behavior of epitaxial antiferromagnetic insulators: Interdigital capacitance measurement of magnetic specific heat ofFeF2thin films. Physical Review B, 40 (7) 4898-4903 doi:10.1103/physrevb.40.4898
Paquette, D., King, A. R., Jaccarino, V. (1975) Field dependence of theF19andMn55nuclear spin-lattice relaxation in antiferromagnetic MnF2. Physical Review B, 11 (3) 1193-1216 doi:10.1103/physrevb.11.1193
Vittoria, C., Barker, R. C., Yelon, A. (1971) Calculation of Standing Spin‐Wave Resonance Modes in Ferromagnetic Metal Films. Journal of Applied Physics, 42 (4). 1734-1736 doi:10.1063/1.1660417
Ramos, C. A., Lederman, D., King, A. R., Jaccarino, V. (1990) New antiferromagnetic insulator superlattices: Structural and magnetic characterization of (FeF2)m(CoF2)n. Physical Review Letters, 65 (23). 2913-2915 doi:10.1103/physrevlett.65.2913
Kotthaus, J.P., Jaccarino, V. (1973) Temperature dependence of the antiferromagnetic resonance linewidth in MnF2. Physics Letters A, 42. 361-362 doi:10.1016/0375-9601(73)90372-1
Suran, G., Naili, M., Rivoire, M., Levy, J. C. S. (1990) Effect of local magnetic anisotropy on the spin‐wave resonance in amorphous thin films. Journal of Applied Physics, 67 (9). 5649-5651 doi:10.1063/1.345915
Waksmann, B., Massenet, O., Escudier, P., Kooi, C. F. (1968) Spin‐Wave Resonance in Epitaxial Fe–Ni Films and in Coupled Double Layers of Epitaxial Fe–Ni (Ferromagnetic)—Fe–Ni–Mn (Antiferromagnetic). Journal of Applied Physics, 39 (2). 1389-1390 doi:10.1063/1.1656317
King, A. R., Toussaint, R. M., Jaccarino, V., Motokawa, M., Sakakibara, T., Date, M. (1984) Novel spin‐flop effects in FexMn1−xF2. Journal of Applied Physics, 55 (6). 2324-2326 doi:10.1063/1.333650
 
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