Open Quantum Physics and Environmental Heat Conversion into Usable Energy
A quantum system can be viewed as a larger closed system comprising of two components: an open quantum system and its surrounding environment. These two components interact with each other, and in the realm of theoretical physics, this interaction cannot be neglected. This eBook series explains mathematical and statistical concepts essential for describing a realistic quantum system by presenting recent contributions in this field.
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Open Quantum Physics and Environmental Heat Conversion into Usable Energy: Volume 4
Open Quantum Physics and Environmental Heat Conversion into Usable Energy - Vol. 4 explores the intricate relationship between quantum mechanics relativity gravitation and electromagnetism offering insights into the dynamics of quantum particles in various fields. The book covers key phenomena such as spin graviton spin black holes and quantum states in extreme conditions including black hole formation. It explains how quantum particles behave as distributions of matter using wave functions to describe their propagation. Further it examines electromagnetic and gravitational field interactions quantum particle transitions Dirac's formalism of general relativity and their applications in quantum electrodynamics and unified field theory.
Key Features:
- Detailed explanation of quantum particle dynamics and wave function theory.
- Discussion of quantum particle transitions and spinor fields.
- Exploration of black hole dynamics and gravitational wave interactions.
- Comprehensive coverage of unified field theory integrating electromagnetism and gravity.
- Applications to quantum electrodynamics and particle collisions.
Open Quantum Physics and Environmental Heat Conversion into Usable Energy: Volume 2
The second volume of this book series presents a foundation for describing electron-field interactions the basic elements involved in open quantum theory the dissipative couplings of the active elements the quantum injection dot electrons and coherent electromagnetic fields produced by crystal lattice vibrations. A microscopic description of the systems of interest is used to explain a number of structural models that describe electron arrangement and mechanics in such systems. The explanation of these models depends on a number of numerical parameters and calculations which have been explicitly discussed in detail. Readers will gain a better understanding of open quantum systems and energy conversion in semiconductor devices. Theoretical calculations presented in this book can also be compared with experimental data from prior experiments. The volume is also supplemented by an adequate bibliography which provides useful references.
This book is a handy text on advanced quantum theory for advanced physics and electronics students and researchers.