| Description |
1 online resource (x, 344 pages) : illustrations (chiefly color) |
|
illustration |
| Contents |
Inside metamaterials. Theory for thermal wave control : transformation complex thermotics. Theory for thermoelectric effect control : transformation nonlinear thermoelectricity. Theory for zero-index conductive cloaks : constant-temperature scheme. Theory for Hele-Shaw convective cloaks : bilayer scheme. Theory for coupled thermoelectric metamaterials : bilayer scheme. Theory for enhanced thermal concentrators : thermal conductivity coupling. Theory for chameleonlike thermal rotators : extremely antisotropic conductivity. Theory for invisible thermal sensors : bilayer scheme. Theory for invisible thermal sensors : monolayer scheme. Theory for invisible thermal sensors : optimization scheme. Theory for omnithermal illusion metasurfaces : cavity effect. Theory for effective advection effect : spaiotemporal modulation. Theory for diffusive Fizeau drag : Willis coupling. Theory for thermal wave refraction : advection regulation -- Outside metamaterials. Theory for active thermal control : thermal dipole effect. Theory for thermal bi/multistability : nonlinear thermal conductivity. Theory for negative thermal transport : complex thermal conductivity. Theory for thermal wave nonreciprocity : angular momentum bias. Theory for thermal geometric phases : exceptional point encirclement. Theory for thermal edge states : graphene-like convective lattice |
| Summary |
This open access book describes the theory of transformation thermotics and its extended theories for the active control of macroscopic thermal phenomena of artificial systems, which is in sharp contrast to classical thermodynamics comprising the four thermodynamic laws for the passive description of macroscopic thermal phenomena of natural systems. This monograph consists of two parts, i.e., inside and outside metamaterials, and covers the basic concepts and mathematical methods, which are necessary to understand the thermal problems extensively investigated in physics, but also in other disciplines of engineering and materials. The analyses rely on models solved by analytical techniques accompanied by computer simulations and laboratory experiments. This monograph can not only be a bridge linking three first-class disciplines, i.e., physics, thermophysics, and materials science, but also contribute to interdisciplinary development |
| Analysis |
Theoretical Thermotics |
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Transformation Thermotics |
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Thermal Metamaterial |
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Thermal Wave |
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Thermal Cloak |
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Thermal Concentrator |
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Thermal Rotator |
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Thermal Sensor |
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Spatiotemporal Modulation |
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Diffusive Fizeau Drag |
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Thermal Willis Coupling |
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Thermal Refraction |
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Thermal Dipole |
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Thermal Nonreciprocity |
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Thermal Conductivity |
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Complex Thermal Conductivity |
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Thermal Geometric Phase |
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Thermal Edge State |
| Bibliography |
Includes bibliographical references |
| Notes |
English |
|
Online resource; title from PDF title page (SpringerLink, viewed October 19, 2022) |
| Subject |
Thermodynamics.
|
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Metamaterials -- Thermal properties
|
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Thermoelectric materials.
|
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thermodynamics.
|
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Thermodynamics
|
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Thermoelectric materials
|
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Electronic devices & materials.
|
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Materials / States of matter.
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Materials science.
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Mathematical physics.
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Optical physics.
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Thermodynamics & heat.
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| Form |
Electronic book
|
| Author |
Huang, Ji-Ping, author.
|
| ISBN |
9789811959080 |
|
9811959080 |
|
