Overview

The phase-locking of multiple spin-torque nano oscillators(STNOs) is considered the primary vehicle to achieve sufficient signal quality for applications. This book highlights the resonator's design and its need for feedback for phase locking of STNOs. STNOs can act as sources of tunable microwaves after being phase-locked together. External feedback from a coplanar waveguide placed above an STNO helps ensures coherent single domain oscillations. STNOs placed within magnonic crystal cavities also demonstrate coherent oscillations. Arrays of such cavities provide a route to scale power levels from such nano-oscillators. The book presents numerical and micromagnetics to validate the design.  

Full Product Details

Author:   C. S. Nikhil Kumar
Publisher:   Springer Verlag, Singapore
Imprint:   Springer Verlag, Singapore
Edition:   1st ed. 2022
Weight:   0.219kg
ISBN:  

9789811961755

ISBN 10:   9811961751
Pages:   92
Publication Date:   07 October 2022
Audience:   Professional and scholarly ,  Professional & Vocational
Format:   Paperback
Publisher's Status:   Active
Availability:   Manufactured on demand  
We will order this item for you from a manufactured on demand supplier.

Table of Contents

1 - Introduction 1 1.1 Magnonic devices 1 1.1.1 Unconventional Computing 3 1.1.2 Hybrid magnonics and Magnon spintronics 4 1.1.3 STNO configurations 6 1.1.4 STNO device principle 8 1.1.5 Mutual synchronization of STNOs 8 1.2 Landau - Lifshitz - Gilbert - Slonczewski equation 94 1.2.1 Numerical Methods 10 1.2.2 Finite Difference and Finite Element method 14 Summary 2- Analytical model for a magnonic ring resonator 2.1 Geometry and analysis 2.2 Dispersion relation of curved magnonic waveguide 2.3 Validations 2.4 Modes in a magnonic ring 3 - Magnonic spectra in 2D antidot magnonic crystals with ring 3.1 Plane wave method 3.1.1 Convergence 3.2 Eigenmodes 3.3 Micromagnetic simulations 3.3.1 Magnonic spectra 3.3.2 Antidot magnonic crystal waveguide with linear defect 4 - Magnetic resonators with magnetic field feedback 4. 1 Introduction 4. 1 Problem statement 4. 2 Micromagnetic simulation without magnetic field feedback 4.3 Free layer model 4.4 Free layer Hysteresis loops 4.5 Ferromagnetic resonance frequency versus applied field 4.6 FMR versus applied field for different in plane and out of plane anisotropy FMR versus applied field for different out of plane anisotropy 4.7 Current dependence on resonance frequency 4.8 Spintronic oscillators with magnetic field feedback 4.9 Spin wave dynamics with magnetic field feedback 4.10 Spin wave dynamics at 300 K 4.11 Linewidth (Without magnetic field feedback) 4.4 Linewidth (with magnetic field feedback) 4.5 Spin wave spectra with different delay 5 - Magnetic resonators magnetic cavity feedback 5.1- I. Introduction 5.1.2. Micromagnetic Simulations 5.1.3 Method of Calculation 5.1.4 Band structure of antidot MC 5.1.5 Spin wave injection on Py film using an array of nano contacts 5.1.6 Fabry Perot model 5.1.7 Quality Factor Calculation

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Author Information

Dr. Nikhil Kumar C S received his B.Tech in Electronics and Communication Engineering from the IES College of Engineering, University of Calicut, Kerala in 2007 and was awarded his Master of Science by Research in Electrical Engineering, IIT Madras in 2014 with a thesis titled Analytical models for magnonic devices and with his Doctor of Philosophy in Electrical Engineering, IIT Madras in 2020 with a thesis titled Magnonic Devices with Feedback Stabilization. His research interests are in the areas of Magnonic Devices, Spin Torque Devices, Magnon Spintronic Devices.

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