|
Showing 1 - 2 of
2 matches in All Departments
This is the first book to systematically review and summarize the
recent rapid advances and varied results of multiphysics in
nanoscale materials including elastic strain engineering. This book
comprises topics on remarkable properties of multiphysics in
low-dimensional nanoscale components from first-principles
density-functional theory (or tight binding) calculations, which
are essential for the nonlinear multiphysics couplings due to
quantum mechanical effects. This volume provides a clear point of
view and insight into the varied work done in diverse fields and
disciplines and promotes a fundamental to state-of-the-art
understanding of properties of multiphysics. Because the novelty
and complexity of mechanical and multiphysical properties of
low-dimensional nanostructures originate from combinations of outer
shapes (e.g., films, wires, tubes, and dots) and inner
understructures (e.g., grain boundaries, domain walls, vacancies,
and impurities), the nanostructures are classified into fundamental
elements, and the properties of each element and their interplay
are reviewed for systematic, in-depth understanding. This book
points out a new direction for multiphysics in nanostructures,
which opens the door both to exploiting and to designing novel
functionalities at the nanoscale. Readers will be interested in
this rapidly expanding multidisciplinary work and will be motivated
to enter this promising research area.
This is the first book to systematically review and summarize the
recent rapid advances and varied results of multiphysics in
nanoscale materials including elastic strain engineering. This book
comprises topics on remarkable properties of multiphysics in
low-dimensional nanoscale components from first-principles
density-functional theory (or tight binding) calculations, which
are essential for the nonlinear multiphysics couplings due to
quantum mechanical effects. This volume provides a clear point of
view and insight into the varied work done in diverse fields and
disciplines and promotes a fundamental to state-of-the-art
understanding of properties of multiphysics. Because the novelty
and complexity of mechanical and multiphysical properties of
low-dimensional nanostructures originate from combinations of outer
shapes (e.g., films, wires, tubes, and dots) and inner
understructures (e.g., grain boundaries, domain walls, vacancies,
and impurities), the nanostructures are classified into fundamental
elements, and the properties of each element and their interplay
are reviewed for systematic, in-depth understanding. This book
points out a new direction for multiphysics in nanostructures,
which opens the door both to exploiting and to designing novel
functionalities at the nanoscale. Readers will be interested in
this rapidly expanding multidisciplinary work and will be motivated
to enter this promising research area.
|
|