English

Quantum Physics, Relativity, and Complex Spacetime: Towards a New Synthesis

Mathematical Physics 2009-10-14 v2 High Energy Physics - Theory math.MP Quantum Physics

Abstract

The positivity of the energy in relativistic quantum mechanics implies that wave functions can be continued analytically to the forward tube T in complex spacetime. For Klein-Gordon particles, we interpret T as an extended (8D) classical phase space containing all 6D classical phase spaces as symplectic submanifolds. The evaluation maps ez:ff(z)e_z: f\to f(z) of wave functions on T are relativistic coherent states reducing to the Gaussian coherent states in the nonrelativistic limit. It is known that no covariant probability interpretation exists for Klein-Gordon particles in real spacetime because the time component of the conserved "probability current" can attain negative values even for positive-energy solutions. We show that this problem is solved very naturally in complex spacetime, where f(xiy)2|f(x-iy)|^2 is interpreted as a probability density on all 6D phase spaces in T which, when integrated over the "momentum" variables y, gives a conserved spacetime probability current whose time component is a positive regularization of the usual one. Similar results are obtained for Dirac particles, where the evaluation maps eze_z are spinor-valued relativistic coherent states. For free quantized Klein-Gordon and Dirac fields, the above formalism extends to n-particle/antiparticle coherent states whose scalar products are Wightman functions. The 2-point function plays the role of a reproducing kernel for the one-particle and antiparticle subspaces.

Keywords

Cite

@article{arxiv.0910.0352,
  title  = {Quantum Physics, Relativity, and Complex Spacetime: Towards a New Synthesis},
  author = {Gerald Kaiser},
  journal= {arXiv preprint arXiv:0910.0352},
  year   = {2009}
}

Comments

252 pages, no figures. Originally published as a book by North-Holland, 1990. Reviewed by Robert Hermann in Bulletin of the AMS Vol. 28 #1, January 1993, pp. 130-132; see http://wavelets.com

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