Metamaterials for Manipulation of Thermal Radiation and Photoluminescence in Near and Far Fields (Springer Theses)
معرفی کتاب «Metamaterials for Manipulation of Thermal Radiation and Photoluminescence in Near and Far Fields (Springer Theses)» نوشتهٔ Yinhui Kan، منتشرشده توسط نشر Springer Nature Singapore Pte Ltd Fka Springer Science + Business Media Singapore Pte Ltd در سال 2022. این کتاب در فرمت pdf، زبان انگلیسی ارائه شده است.
translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed. The use of general descriptive names, registered names, trademarks, service marks, etc. in this publication does not imply, even in the absence of a specific statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. The publisher, the authors, and the editors are safe to assume that the advice and information in this book are believed to be true and accurate at the date of publication. Neither the publisher nor the authors or the editors give a warranty, expressed or implied, with respect to the material contained herein or for any errors or omissions that may have been made. The publisher remains neutral with regard to jurisdictional claims in published maps and institutional affiliations. Supervisor’s Foreword Abstract Acknowledgements Contents Symbols Variables Greek Symbols Subscripts/Superscripts Abbreviations 1 Introduction 1.1 Metamaterials: Light-Matter Interaction at Subwavelength Scales 1.2 Tailoring Thermal Radiative Properties by Metamaterials 1.3 Near-Field Radiative Heat Transfer Between Nanostructures 1.4 On-Chip Manipulation of Spontaneous Emission 1.5 Research Outline References 2 Theoretical and Experimental Methods 2.1 Calculation Methods 2.1.1 Layer Structures: Transfer Matrix Method 2.1.2 Grating Structures: Rigorous-Coupled Wave Analysis 2.1.3 NFRHT in Three-Body Systems 2.2 Physical Effects or Phenomena for Designing Nanodevices 2.2.1 Surface Plasmons 2.2.2 Spontaneous Emission Near Nano Antennas 2.2.3 Spin–Orbit Interactions of Light 2.3 Sample Fabrications 2.4 Experimental Characterization 2.5 Summary References 3 Design of Broadband Metamaterial Absorbers in Visible and Infrared Frequencies 3.1 Active Designing Method for One-Dimensional Periodic Structures 3.2 Near-Perfect Broadband Absorption 3.3 Two-Dimensional Gratings with Anisotropic Materials 3.4 Resonance Absorption by Hyperbolic Polaritons 3.5 Summary References 4 Enhancement and Modulation of Near-Field Thermal Radiation 4.1 Near-Field Radiative Heat Transfer in Three-Body Systems with Periodic Structures 4.2 Enhancement of Near-Field Thermal Radiation 4.3 Near Field Radiative Heat Transfer with Graphene/hBN Heterostructures 4.4 Active Modulation of Heat Transfer by a Modulator 4.5 Summary References 5 Metasurfaces-Enabled Manipulation of Spontaneous Photon Emission 5.1 Scattering Light from QEs and Nano Bricks Interacting Systems 5.2 Spinning Single Photons 5.3 Directional Off-Normal Photon Streaming 5.4 Summary References 6 On-Chip Control Excitations of Quantum Emitters in Hybrid Nanocircuits 6.1 Spin–Orbit Coupler in Visible Frequency 6.2 Selective Excitations of Quantum Emitters 6.3 Summary References 7 Summary and Outlook Appendix A Characterizations of Hybrid QE-Coupled Metasurfaces A.1 Measurement of Stokes Parameters A.2 Lifetime Measurement This book provides a series of methods for flexibly and actively manipulating thermal emission and photoluminance by advanced nanostructures—metamaterials. Nanostructures in subwavelength scales can be designed to precisely modulate light-matter interactions and thereby tailoring both thermal radiations and photon emissions. This book explores approaches for designing different kinds of nanostructures, including multilayers, gratings, nanoridges, and waveguides, to improve the flexibility and functionality of micro/nanodevices. With the help of these subwavelength nanostructures, thermal radiation and photoluminescence have been fully manipulated in near and far fields regarding to the intensity, spectrum, polarization, and direction. The proposed methods together with designed metamaterials open new avenues for designing novel micro-/nanodevices or systems for promising applications like thermal energy harvesting, detecting, sensing, and on-chip quantum-optical networks.
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