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Full Description
During energy utilization and conversion, thermal energy is either an intermediate product or a byproduct; that is, thermal transport plays a critical role on efficiency, reliability, and safety of the energy systems. Recent development in nanotechnologies enabled significant improvement of the thermal energy storage performance, fuel cell, battery and thermoelectric devices. To meet the ever increasing challenges posed by energy systems, innovative and transformative measures must be taken to significantly improve the performance of these devices. Such measures will not be possible without a thorough understanding of thermal transport at molecular, nano-and microscale levels because physical phenomena occurring at the molecular, nano- and microscale will have profound effects on the performance at the system level. Understanding of multiscale thermal transport in the energy system is essential to improve their performance.
Contents
Preface; Boiling & Evaporation on Micro/Nano-Engineered Surfaces; Multiscale Modeling of Nanostructure-enhanced Thin Film Evaporation; Multi-Length Scale Thermal Simulations of GaN-on-SiC High Electron Mobility Transistors; Coupling Scheme of Lattice Boltzmann Method & Finite Volume Method for Multiscale Numerical Simulation; A Unified Diffusive-Nondiffusive Two Parameter Heat Conduction Model; Multiscale Thermal Diode & Switch for Advanced Thermal Management Systems; Molecular dynamics-continuum hybrid simulation method & applications; Coupling Finite Type Method & the lattice Boltzmann method for multiple physicochemical processes; Hybrid LBM-FVM & LBM-MCM Methods for Fluid Flow & Heat Transfer Simulation; Micro-scale Thermal Transport in Gas Turbine Ceramic Coatings; Index.NER(01): GB IE
