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Time-energy uncertainty and relativistic canonical commutation relations in quantum spacetime

Eduard Prugovečki

Foundations of Physics 12 (6):555-564 (1982)

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A self-consistent approach to quantum field theory for extended particles.Eduard Prugovečki - 1981 - Foundations of Physics 11 (5-6):355-382.details A notion of quantum space-time is introduced, physically defined as the totality of all flows of quantum test particles in free fall. In quantum space-time the classical notion of deterministic inertial frames is replaced by that of stochastic frames marked by extended particles. The same particles are used both as markers of quantum space-time points as well as natural clocks, each species of quantum test particle thus providing a standard for space-time measurements. In the considered flat-space case, the fluctuations in (...) Download Export citation Bookmark 6 citations
An intriguing legacy of Einstein, Fermi, Jordan, and others: The possible invalidation of quark conjectures. [REVIEW]Ruggero Maria Santilli - 1981 - Foundations of Physics 11 (5-6):383-472.details The objective of this paper is to present an outline of a number of criticisms of the quark models of hadron structure which have been present in the community of basic research for some time. The hope is that quark supporters will consider these criticisms and present possible counterarguments for a scientifically effective resolution of the issues. In particular, it is submitted that the problem of whether quarks exist as physical particles necessarily calls for the prior theoretical and experimental resolution (...) Download Export citation Bookmark 4 citations
Physical basis for minimal time-energy uncertainty relation.Y. S. Kim & Marilyn E. Noz - 1979 - Foundations of Physics 9 (5-6):375-387.details A physical basis for the minimal time-energy uncertainty relation is formulated from basic high-energy hadronic properties such as the resonance mass spectrum, the form factor behavior, and the peculiarities of Feynman's parton picture. It is shown that the covariant oscillator formalism combines covariantly this time-energy uncertainty relation with Heisenberg's space-momentum uncertainty relation. A pictorial method is developed to describe the spacetime distribution of the localized probability density. Download Export citation Bookmark 7 citations
On a quantum algebraic approach to a generalized phase space.D. Bohm & B. J. Hiley - 1981 - Foundations of Physics 11 (3-4):179-203.details We approach the relationship between classical and quantum theories in a new way, which allows both to be expressed in the same mathematical language, in terms of a matrix algebra in a phase space. This makes clear not only the similarities of the two theories, but also certain essential differences, and lays a foundation for understanding their relationship. We use the Wigner-Moyal transformation as a change of representation in phase space, and we avoid the problem of “negative probabilities” by regarding (...) Download Export citation Bookmark 5 citations

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