Listing 1 - 8 of 8 |
Sort by
|
Choose an application
Antimatter, already conjectured by A. Schuster in 1898, was actually predicted by P.A.M. Dirac in the late 19-twenties in the negative-energy solutions of the Dirac equation. Its existence was subsequently confirmed via the Wilson chamber and became an established part of theoretical physics. Dirac soon discovered that particles with negative energy do not behave in a physically conventional manner, and he therefore developed his "hole theory". This restricted the study of antimatter to the sole level of second quantization. As a result antimatter created a scientific imbalance, because matter was treated at all levels of study, while antimatter was treated only at the level of second quantization. In search of a new mathematics for the resolution of this imbalance the author conceived what we know today as Santilli’s isodual mathematics, which permitted the construction of isodual classical mechanics, isodual quantization and isodual quantum mechanics. The scope of this monograph is to show that our classical, quantum and cosmological knowledge of antimatter is at its beginning with much yet to be discovered, and that a commitment to antimatter by experimentalists will be invaluable to antimatter science.
Antimatter. --- Antigravity. --- Grand unified theories (Nuclear physics) --- Cosmology. --- Astronomy --- Deism --- Metaphysics --- Grand unification theories (Nuclear physics) --- GUT (Nuclear physics) --- Unification of fundamental particle interactions (Nuclear physics) --- Unified theories --- Gauge fields (Physics) --- Nuclear reactions --- Supergravity --- Supersymmetry --- Unified field theories --- Gravitation --- Matter --- Properties --- Quantum theory. --- Nuclear physics. --- Astronomy. --- Quantum Physics. --- Theoretical, Mathematical and Computational Physics. --- Nuclear Physics, Heavy Ions, Hadrons. --- Astronomy, Astrophysics and Cosmology. --- Elementary Particles, Quantum Field Theory. --- Atomic nuclei --- Atoms, Nuclei of --- Nucleus of the atom --- Physics --- Quantum dynamics --- Quantum mechanics --- Quantum physics --- Mechanics --- Thermodynamics --- Quantum physics. --- Mathematical physics. --- Heavy ions. --- Astrophysics. --- Elementary particles (Physics). --- Quantum field theory. --- Relativistic quantum field theory --- Field theory (Physics) --- Quantum theory --- Relativity (Physics) --- Elementary particles (Physics) --- High energy physics --- Nuclear particles --- Nucleons --- Nuclear physics --- Astronomical physics --- Cosmic physics --- Ions --- Physical mathematics --- Mathematics
Choose an application
531 --- 531 General mechanics. Mechanics of solid and rigid bodies --- General mechanics. Mechanics of solid and rigid bodies --- Mechanics --- Classical mechanics --- Newtonian mechanics --- Physics --- Dynamics --- Quantum theory --- Differential geometry. Global analysis --- Mechanics. --- Inverse problems (differential equations)
Choose an application
Choose an application
Choose an application
Cosmology --- Astrophysics --- Mathematical physics --- Quantum mechanics. Quantumfield theory --- Elementary particles --- Nuclear physics --- cosmology --- elementaire deeltjes --- quarks --- quantumfysica --- astrofysica --- deeltjesfysica --- kwantumleer --- kernenergie --- wiskunde --- fysica --- kosmologie
Choose an application
Product Realization: A Comprehensive Approach is based on selected papers presented at the International Conference on Comprehensive Product Realization 2007 (ICCPR2007). The extended papers will provide the opportunity for scholars from all around the world to discuss their academic programs, identify research opportunities, and initiate joint research programs in the area of comprehensive product realization. Engineering design has evolved from an isolated semi-empirical activity to a highly interconnected, multidisciplinary product realization collaborative process. Written by experts in the field of engineering design, Product Realization: A Comprehensive Approach is a must have book for engineering professionals interested in the latest developments in product life cycle management. Covering such topics as: Product life cycle and assessment parameters Measuring the impact of product lifecycle management Social issues of product lifecycle management Product design optimization Product lifecycle Management and the virtualization of product information About the Editors: Mileta M. Tomovic is the W.C. Furnas Professor of Enterprise Excellence in the Department of Mechanical Engineering Technology at Purdue University. His research interests are in the area of system dynamics and controls, manufacturing processes, design optimization, collaborative design, product lifecycle management, modeling of rapid prototyping and fast free form fabrication methods, and web-based multi-user platform development for industrial tooling customer-supplier resource management. Shaoping Wang is a Professor of Mechatronics and Dean of Mechatronics at the School of Automation Science and Electrical Engineering at Beijing University of Aeronautics and Astronautics.
Engineering design -- Congresses. --- New products -- Congresses. --- Product management -- Congresses. --- Production engineering -- Congresses. --- Industrial & Management Engineering --- Mechanical Engineering --- Engineering & Applied Sciences --- Engineering. --- Production management. --- Engineering design. --- Industrial engineering. --- Production engineering. --- Industrial and Production Engineering. --- Engineering Design. --- Operations Management. --- Manufacturing engineering --- Process engineering --- Industrial engineering --- Mechanical engineering --- Management engineering --- Simplification in industry --- Engineering --- Value analysis (Cost control) --- Design, Engineering --- Industrial design --- Strains and stresses --- Manufacturing management --- Industrial management --- Construction --- Industrial arts --- Technology --- Design
Choose an application
Antimatter, already conjectured by A. Schuster in 1898, was actually predicted by P.A.M. Dirac in the late 19-twenties in the negative-energy solutions of the Dirac equation. Its existence was subsequently confirmed via the Wilson chamber and became an established part of theoretical physics. Dirac soon discovered that particles with negative energy do not behave in a physically conventional manner, and he therefore developed his "hole theory". This restricted the study of antimatter to the sole level of second quantization. As a result antimatter created a scientific imbalance, because matter was treated at all levels of study, while antimatter was treated only at the level of second quantization. In search of a new mathematics for the resolution of this imbalance the author conceived what we know today as Santilli's isodual mathematics, which permitted the construction of isodual classical mechanics, isodual quantization and isodual quantum mechanics. The scope of this monograph is to show that our classical, quantum and cosmological knowledge of antimatter is at its beginning with much yet to be discovered, and that a commitment to antimatter by experimentalists will be invaluable to antimatter science.
Cosmology --- Astrophysics --- Mathematical physics --- Quantum mechanics. Quantumfield theory --- Elementary particles --- Nuclear physics --- cosmology --- elementaire deeltjes --- quarks --- quantumfysica --- astrofysica --- deeltjesfysica --- kwantumleer --- kernenergie --- wiskunde --- fysica --- kosmologie
Choose an application
Listing 1 - 8 of 8 |
Sort by
|