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Recent Advances in Magnetic Insulators : from Spintronics to Microwave Applications / edited by Mingzhog Wu, Axel Hoffmann.

Contributor(s): Series: Solid-state physics ; v. 64.Publisher: Amsterdam ; Boston : Elsevier/Academic Press, 2013Edition: First editionDescription: 1 online resource (431 pages : illustrationsContent type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9780124080713
  • 0124080715
  • 1306087279
  • 9781306087278
Subject(s): Genre/Form: Additional physical formats: Print version:: Recent Advances in Magnetic Insulators - From Spintronics to Microwave Applications.LOC classification:
  • QC176.8.M34 R43 2013eb
Online resources:
Contents:
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.
Summary: 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 insulators to produce and transfer spin currents, the excitation of spin waves in magnetic insulators by spin transfer torque, interplay between the spin and heat transports in magnetic insulator/normal metal heterostructures, nonlinear spin waves in thin films, development of high-quality nanometer thick f.
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Text in English.

Includes bibliographical references and index.

Online resource; title from PDF title page (ebrary, viewed December 10, 2013).

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.

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 insulators to produce and transfer spin currents, the excitation of spin waves in magnetic insulators by spin transfer torque, interplay between the spin and heat transports in magnetic insulator/normal metal heterostructures, nonlinear spin waves in thin films, development of high-quality nanometer thick f.

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