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LEADER: 04310cam a2200337 a 4500
001 013110879-4
005 20120719021336.0
008 080319s2011 si a b 001 0 eng c
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050 4 $aQC174.12$b.S345 2011
082 04 $a530.12$222
084 $aUH 8300$2rvk
084 $aUK 2000$2rvk
100 1 $aSchommers, W.$q(Wolfram),$d1941-
245 10 $aQuantum processes /$cWolfram Schommers.
260 $aSingapore ;$aHackensack, NJ :$bWorld Scientific,$cc2011.
300 $axx, 399 p. :$bill. (some col.) ;$c24 cm.
504 $aIncludes bibliographical references (p. 393-394) and index.
520 $a"Space and time are probably the most important elements in physics. Within the memory of man, all essential things are represented within the frame of space-time pictures. This is obviously the most basic information. What can we say about space and time? It is normally assumed that the space is a container filled with matter and that the time is just that which we measure with our clocks. However, there are some reasons to take another standpoint and to consider this container-conception as unrealistic, as prejudice so to say. Already the philosopher Immanuel Kant pointed on this serious problem. In this monograph, the author discusses the so-called projection theory. In contrast to the container-conception (reality is embedded in space and time), within projection theory the physical reality is projected onto space and time and quantum processes are of particular relevance. Like Whitehead and Bergson, the author argues for the primacy of process. One of the most interesting results is that projection theory automatically leads to a new aspect for the notion 'time'. Here we have not only the time of conventional physics, which is exclusively treated as an external parameter, but we obtain within projection theory a system-specific time. Just this system-specific time might be of fundamental importance in the future description of physical systems. For example, the self-assembly of nano-systems could lead to predictions that are even not thinkable within usual physics. Also in connection with cosmology the projection principle must inevitably lead to fundamentally new statements"--Back cover.
505 0 $a1. Conventional quantum theory. 1.1. Classical description. 1.2. Schrodinger's equations. 1.3. Uncertainty relations. 1.4. Individuals. 1.5. Conclusion. 1.6. Aspect. 1.7. Remarks on the superposition principle. 1.8. Basic new experiments -- 2. Projection theory. 2.1. Preliminary remarks. 2.2. The projection principle. 2.3. Projections. 2.4. Summary -- 3. Free, non-interacting systems (particles). 3.1. General remarks. 3.2. The behaviour of the basic equations. 3.3. Classical and quantum-theoretical elements. 3.4. Behaviour of the wave function in (r, t)-space and (p, E)-space. 3.5. Probability considerations in connection with [symbol]. 3.6. Normalization condition. 3.7. Mean values for the momentum and the energy. 3.8. The p, E-pool. 3.9. Free, elementary systems do not exist. 3.10. No equation for the determination of the wave function [symbol]. 3.11. Principle of usefulness. 3.12. Further general remarks. 3.13. Rest mass effect. 3.14. Summary -- 4. Interactions. 4.1. Interactions with projection theory. 4.2. What does interaction mean within projection theory? 4.3. How basic is the notion "interaction"? 4.4. Description of interactions with projection theory : principal remarks. 4.5. Pair distributions. 4.6. Basic equations. 4.7. Energy levels. 4.8. Distance-independent interactions. 4.9. The meaning of the potential functions. 4.10. Further basic features. 4.11. Absolute space-time conceptions. 4.12. Relativistic effects. 4.13. Hierarchy of the parts in a part. 4.14. Granular space-time structures. 4.15. Summary and final remarks -- 5. Some basic questions. 5.1. The particle-wave question. 5.2. The role of the observer. 5.3. Summary -- 6. Summary.
650 0 $aQuantum theory.
650 0 $aSpace and time.
988 $a20120302
906 $0OCLC