Description |
1 online resource |
Physical Medium |
polychrome |
Description |
text file |
Bibliography |
Includes bibliographical references. |
Contents |
Cover; Half-title page; Title page; Copyright page; Contents; 1 Introduction; 1.1 The History of Laser Minimization; 1.2 Active Materials for Nanolasers; 1.3 Fundamental Scale Limits of Lasers; 1.4 Efficiency in Nanolasers; 1.5 Laser Rate Equations; 1.6 Nanolaser Types and Their Characteristics; 1.6.1 Vertical Cavity Surface-emitting Lasers (VCSELs); 1.6.2 Photonic Crystal Defect Cavity Lasers; 1.6.3 Nanowire Lasers; 1.6.4 Cavity-free Nanolasers; 1.6.5 Metal-dielectric-metal Waveguide-based Nanolasers; 1.6.6 SPASERs; 2 Photonic Mode Metal-dielectric-metal-based Nanolasers. |
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4.3 MDM Lasers with 2D Confinement4.4 Motivation for 3D Confined Coaxial Nanolasers; 4.5 Design and Fabrication of Optically Pumped Coaxial Nanolasers; 4.6 Emission Characterization of High β-factor Coaxial Nanolasers; 4.7 Emission Characterization of Unity β-factor Coaxial Nanolasers; 4.8 Rate Equation Analysis of Unity β-factor Coaxial Nanolasers; 4.9 Perspective on Plasmonic Mode Nanolasers; 5 Antenna-inspired Nano-patch Lasers; 5.1 Optical Mode and Radiation Pattern of Nanopatch Lasers; 5.2 Experimental Demonstration of Optically Pumped Nanopatch Laser. |
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2.1 Metallo-dielectric Cavity Design2.2 Invariance of Optimal Metallo-dielectric Waveguide Geometry with Respect to Metal-cladding Permittivity; 2.3 Metallo-dielectric Nanolaser Fabrication; 2.4 Optical Pump Penetration Analysis; 2.5 Metallo-dielectric Nanolasers on Silicon; 2.6 Micro-photoluminescence Characterization of Nanolasers; 3 Purcell Effect and the Evaluation of Purcell and Spontaneous Emission Factors; 3.1 Gain Medium and Its Excitation; 3.2 Formulation of Purcell Effect in Semiconductor Nanolasers at Room Temperature; 3.3 Applicability of the Formulation. |
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5.3 Toward Low-threshold, Engineerable Radiation Pattern, and Electrical Pumping6 Active Medium for Semiconductor Nanolasers: MQW vs. Bulk Gain; 6.1 Current Injection in Semiconductor Nanolasers; 6.2 Optical Cavity and Material Gain Optimization; 6.3 Reservoir Model for Semiconductor Lasers; 6.4 Laser Rate-equation Analysis with the Reservoir Model; 6.5 Discussion; 7 Electrically Pumped Nanolasers; 7.1 Optical Mode Design with Realistic Geometrical Parameters; 7.2 Cylindrical Nanolasers with InP Undercut; 7.3 Cylindrical Nanolasers without InP Undercut. |
Summary |
A unique and comprehensive resource covering the fundamentals of nanolasers, with details of design, fabrication, and applications. |
Local Note |
eBooks on EBSCOhost EBSCO eBook Subscription Academic Collection - North America |
Subject |
Semiconductor lasers.
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Semiconductor lasers. |
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Lasers.
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Lasers. |
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Miniature electronic equipment.
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Miniature electronic equipment. |
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Semiconductors.
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Nanostructured materials.
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Semiconductors. |
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semiconductor. |
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Nanostructured materials. |
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TECHNOLOGY & ENGINEERING -- Mechanical. |
Genre/Form |
Electronic books.
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Added Author |
Fainman, Yeshaiahu.
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Other Form: |
Print version: Gu, Qing, 1985- Semiconductor nanolasers. Cambridge : Cambridge University Press, 2017 9781107110489 (DLC) 2016045371 (OCoLC)956750813 |
ISBN |
9781316986028 (electronic book) |
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1316986020 (electronic book) |
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9781316275122 |
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1316275124 |
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9781107110489 |
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1107110483 |
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9781316984918 |
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1316984915 |
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