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Spin Excitations and Spin Damping in Ultrathin Ferromagnets D. L. Mills Department of Physics and Astronomy University of California Irvine, California. Collaborators: R. B.Muniz and A. T. Costa Instituto de Fisica
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Spin Excitations and Spin Damping in Ultrathin Ferromagnets D. L. Mills Department of Physics and Astronomy University of California Irvine, California Collaborators: R. B.Muniz and A. T. Costa Instituto de Fisica Universidade Federal de Fluminense Niteroi, Brazil
Experimental methods for probing spin dynamics • In ultrathin magnetic films: • Ferromagnetic resonance (FMR): Examines • only spin motions. 2. Brillouin light scattering (BLS): (Inelastic scattering of photons): Examines , small on the scale of the Brillouin zone. 3. Inelastic Neutron Scattering : Problems! (i). Not surface sensitive. (ii). Neutrons can’t excite spin excitations in materials of interest; Neutron kinetic energy ~ 30 meV, spin wave energy scale ~ 300 meV. 4. Spin Polarized Electron Energy Loss Spectroscopy: (SPEELS) (i). High surface sensitivity (ii). Lots of beam energy (several eV) (iii). Cross section small.
Expectations for Spin Wave Spectrum of an N Layer Ferromagnetic Film: The Heisenberg Model: Spin Wave Excitations: 1. Write down equation of motion for 2. Seek solutions of the form where lies in the 2D Brillouin zone. Conclusion: For each value of one has N spin wave eigenmodes, each with infinite lifetime.
Heisenberg Model Description of the Spin Wave Spectrum of a Five Layer Ferromagnet: For the materials of interest currently, this picture is qualitatively wrong!
Our Approach: • Place ultrathin, few layer film on a semi infinite • substrate. • 2. Use empirical tight binding description of electronic • structure, with nine bands for each material. • Parameters obtained from fits to electronic • structure calculations. • 3. Ferromagnetism driven by intra atomic Coulomb • interactions, with strength taken from • photoemission data on exchange splitting • (F. Himpsel, J. Magn. & Mag. Mat. 102, 261 (1991)) ) • 4. Mean field, self consistent calculation of ground • state, with moments allowed to vary on a layer • by layer basis. • 5. Random Phase Approximation applied to • description of spin dynamics.
The Fe Monolayer on W(110); Comparison • Between Local Density of States in GGA Based • Density Functional Calculation (black) and • Tight Binding Description. • T. Costa, R. B. Muniz, J. X. Cao, R. Wu and • D.L. Mills (to be published)
Spin Excitations In Ultrathin 3d Ferromagnetic Films: The Case of Fe (5 layers) on W(110): A. T. Costa, R. B. Muniz, and D. L. Mills, Phys. Rev. B66, 224435 (2001). Qx=0.05 Qx=0.20
Farther out in the Brillouin Zone: Qx=0.4 Qx=0.6
Another Example : Eight Layers of Co on Cu(100) • T.Costa, R. B. Muniz and D. L. Mills, • Phys. Rev. B70, 54406 (2004) Q=0.3 Q=0.6
An Experiment : Spin Polarized Electron Loss Spectroscopy (SPEELS) Specular Direction Spin Wave Excitation: Angular Momentum Conservation Requires a Spin Flip
An Example of Electron Loss Spectroscopy: Surface Phonons on the Ni (100) Surface Experiment: M. L. Xu, B. M. Hall, S. Y. Tong, M. Rocca. H. Ibach and J. E. Black, Phys. Rev. Letters 54, 1171 (1985). Theory: B. M. Hall and D. L. Mills, Phys. Rev. B54, 1171 (1985). What do we expect for spin waves? Theory says sSW/sPh ~ 10-3 . (M. P. Gokhale, A. Ormeci and D. L. Mills, Phys. Rev. B46, 8978 (1992))
SPEELS Studies of Spin Waves in Ultrathin Ferromagnets; Co on Cu(100): R. Vollmer, M. Etzkorn, P. S. Anil Kumar, H. Ibach, and J. Kirschner, Phys. Rev. Letters 91, 147201 (2003) Spin Dependence of the Excitation Process:
Comparison Between Theory and Experiment: A. Dispersion Relation of Single Loss Feature: B. Linewidth and Lineshape:
The Limit of Zero Wave Vector: • It is crucial to understand the spin damping in • ultrathin films at long wavelengths; this controls • realizable switching speeds in devices. • A measure of spin damping: Ferromagnetic • resonance linewidths. • The Question: Are damping mechanisms the same • In ultrathin ferromagnets as in bulk materials? • Bulk Ferromagnets: Damping at Q = 0 is a spin • orbit based mechanism (Goldstone theorem). • Ultrathin Ferromagnets: Two mechanisms not • operative in the bulk: • “Spin pumping”: Intrinsic. • Two magnon scattering: Extrinsic. • R. Arias and D. L. Mills, Phys. Rev. B60, 7395 • (1999), D. L. Mills and S. M. Rezende, p. 27 • of Spin Dynamics in Confined Structures II, • (Springer Verlag, Heidelberg, 2002).
Calculations of FMR Spectra and Linewidths: • T. Costa, R. B. Muniz and D. L. Mills (to be • Published) 1. Co2 on Cu(100): 2. Co2Cu2Co2 on Cu(100):
Comparison Between Theory and Experiment: The Case of Fe on Au(100) Data: R. Urban, G.Woltersdorf and B. Heinrich, Phys. Rev. Letters 87,217204 (2001).
Data on Trilayers; Quantum Interference Effects The Data: (K. Lenz, T. Tolinski, J. Lindner, E. Kosubek, and K. Baberschke, Phys. Rev. B69, 14422 (2004). Theory:
Concluding Remarks: • For large wave vector spin wave excitations • in ultrathin ferromagnets, the Heisenberg model • description fails qualitatively. The reason is a • breakdown of the adiabatic approximation. • An effective Heisenberg Hamiltonian can be used • to describe static phenomenon (domain walls) but • not spin excitations at large wave vectors. • 2. Our approach provides a quantitative description of • spin excitations and their (intrinsic) damping • throughout the two dimensional Brillouin zone, • from the FMR regime to the large wave vectors • explored in the electron energy loss studies.