Wiley. 2010. 491 p.
Written by an outstanding group of applied theoreticians with comprehensive expertise and a wide spectrum of inteational contacts headed by Prof. A. M. Gusak, this monograph coherently presents the approaches and results hitherto only available in various joual papers.
A must-have for all those involved with the public or corporate science of nano systems, thin films and electrical engineering.
Contents
Introduction
Nonequilibrium Vacancies and Diffusion-Controlled Processes at Nanolevel
Diffusive Phase Competition: Fundamentals
Nucleation in a Concentration Gradient
Modeling of the Initial Stages of Reactive Diffusion
Flux-Driven Morphology Evolution
Nanovoid Evolution
Phase Formation via Electromigration
Diffusion Phase Competition in Teary Systems
Interdiffusion with Formation and Growth of Two-Phase Zones
The Problem of Choice of Reaction Path and Extremum Principles
Choice of Optimal Regimes in Cellular Decomposition, Diffusion-Induced Grain Boundary Migration, and the Inverse Diffusion Problem
Nucleation and Phase Separation in Nanovolumes
Written by an outstanding group of applied theoreticians with comprehensive expertise and a wide spectrum of inteational contacts headed by Prof. A. M. Gusak, this monograph coherently presents the approaches and results hitherto only available in various joual papers.
A must-have for all those involved with the public or corporate science of nano systems, thin films and electrical engineering.
Contents
Introduction
Nonequilibrium Vacancies and Diffusion-Controlled Processes at Nanolevel
Diffusive Phase Competition: Fundamentals
Nucleation in a Concentration Gradient
Modeling of the Initial Stages of Reactive Diffusion
Flux-Driven Morphology Evolution
Nanovoid Evolution
Phase Formation via Electromigration
Diffusion Phase Competition in Teary Systems
Interdiffusion with Formation and Growth of Two-Phase Zones
The Problem of Choice of Reaction Path and Extremum Principles
Choice of Optimal Regimes in Cellular Decomposition, Diffusion-Induced Grain Boundary Migration, and the Inverse Diffusion Problem
Nucleation and Phase Separation in Nanovolumes