Recent Advances in Magnetic Insulators : from Spintronics to Microwave Applications /
This volume of Solid State Physics provides a broad review on recent advances in the field of magnetic insulators, ranging from new spin effects to thin film growth and high-frequency applications. It covers both theoretical and experimental progress. The topics include the use of magnetic insulator...
Clasificación: | Libro Electrónico |
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Otros Autores: | , |
Formato: | Electrónico eBook |
Idioma: | Inglés |
Publicado: |
Amsterdam ; Boston :
Elsevier/Academic Press,
2013.
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Edición: | First edition. |
Colección: | Solid-state physics ;
v. 64. |
Temas: | |
Acceso en línea: | Texto completo Texto completo |
Tabla de Contenidos:
- Front Cover; Recent Advances in MagneticInsulators
- From Spintronicsto Microwave Applications; Copyright; Contents; Contributors; Preface; Chapter One: Spin-Wave Spin Current in Magnetic Insulators; 1. Introduction: Concept of Spin-Wave Spin Current; 2. Electric and Magnetic Signals Interconversion in Magnetic Insulators; 2.1. Experiment; 2.1.1. Spin Pumping at Ferrimagnetic Insulator/Paramagnetic Metal Interface; 2.1.2. Spin Transfer Torque at Ferrimagnetic Insulator/Paramagnetic Metal Interface; 2.1.3. Electric Signal Transmission in Ferrimagnetic Insulator via Spin-Wave Spin Current.
- 2.2. Theory3. Spin Seebeck Effect in Magnetic Insulators; 3.1. Experiment; 3.1.1. Sample Configuration and Measurement Mechanism; 3.1.2. Longitudinal SSE in Ferrimagnetic Insulator/Paramagnetic Metal Systems; 3.1.3. Transverse SSE in Ferrimagnetic Insulator/Paramagnetic Metal Systems; 3.1.4. Thermoelectric Coating Based on SSE; 3.2. Theory; 4. Summary and Perspectives; References; Chapter Two: Spin-Wave Excitation in Magnetic Insulator Thin Films by Spin-Transfer Torque; 1. Introduction and Background; 2. Spin-Current-Induced Magnetization Dynamics.
- 3. Dispersion, Amplification, and Dissipation of Spin Waves in Magnetic Insulators3.1. Without Surface Anisotropy; 3.2. With Easy-Axis Surface Anisotropy; 3.3. With Hard-Axis Surface Anisotropy; 3.4. Excitation Power Spectrum; 3.5. Spin Pumping; 4. Discussion; Acknowledgments; References; Chapter Three: Charge, Spin, and Heat Transport in the Proximity of Metal/Ferromagnet Interface; 1. Introduction; 2. Transverse Spin Seebeck Effect; 2.1. Thermal Spin Transport in Magnetic Thin Film on Substrate; 2.2. Entanglement of Spin Seebeck Effect and Anomalous Nernst Effect.
- 2.3. Intrinsic Thermal Spin-Dependent Transport3. Longitudinal Spin Seebeck Effect; 3.1. Transport Magnetic Proximity Effect in Pt/YIG; 3.2. Entanglement of Spin Seebeck Effect and Magnetic Proximity Effect; 3.3. Intrinsic Longitudinal Spin Seebeck Effect in Au/YIG; 4. Concluding Remarks; Acknowledgments; References; Chapter Four: Control of Pure Spin Current by Magnon Tunneling and Three-Magnon Splitting in Insulating Yttrium Iron Garn ... ; 1. Introduction; 2. Tunneling of Magnons in Yttrium Iron Garnet (YIG); 2.1. Theoretical Model; 2.2. Experimental Results.
- 2.3. Tunneling and Reflection: Single Barrier2.4. Resonant Tunneling: Double Barrier; 2.5. Soliton Tunneling; 3. Amplification of Spin Currents Due to Magnon-Magnon Interaction; 3.1. Conservation of Angular Momentum in Magnetic Systems; 3.2. Spin Pumping and Spin Currents; 3.3. Spin Pumping and Spin Current Amplification in YIG/Pt Bilayers; 3.3.1. Spin Pumping Using Linearly Excited Magnons; 3.3.2. Spin Pumping Using Nonlinearly Excited Magnons; 3.3.3. Spin Current Amplification by Magnon-Magnon Interactions; 4. Conclusion; Acknowledgments; References.