Multitime Schrödinger equations cannot contain interaction potentials
Multitime wave functions are wave functions that have a time variable for every particle, such as ϕ(t{sub 1},x{sub 1},...,t{sub N},x{sub N}). They arise as a relativistic analog of the wave functions of quantum mechanics but can be applied also in quantum field theory. The evolution of a wave function with N time variables is governed by N Schrödinger equations, one for each time variable. These Schrödinger equations can be inconsistent with each other, i.e., they can fail to possess a joint solution for every initial condition; in fact, the N Hamiltonians need to satisfy a certain commutator condition in order to be consistent. While this condition is automatically satisfied for noninteracting particles, it is a challenge to set up consistent multitime equations with interaction. We prove for a wide class of multitime Schrödinger equations that the presence of interaction potentials (given by multiplication operators) leads to inconsistency. We conclude that interaction has to be implemented instead by creation and annihilation of particles, which, in fact, can be done consistently [S. Petrat and R. Tumulka, “Multitime wave functions for quantum field theory,” Ann. Physics (to be published)]. We also prove the following result: When a cutoff length δ > 0 ismore »
 Authors:

^{[1]};
^{[2]}
 Mathematisches Institut, LudwigMaximiliansUniversität, Theresienstr. 39, 80333 München (Germany)
 Department of Mathematics, Rutgers University, 110 Frelinghuysen Road, Piscataway, New Jersey 088548019 (United States)
 Publication Date:
 OSTI Identifier:
 22251097
 Resource Type:
 Journal Article
 Resource Relation:
 Journal Name: Journal of Mathematical Physics; Journal Volume: 55; Journal Issue: 3; Other Information: (c) 2014 AIP Publishing LLC; Country of input: International Atomic Energy Agency (IAEA)
 Country of Publication:
 United States
 Language:
 English
 Subject:
 71 CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS; 72 PHYSICS OF ELEMENTARY PARTICLES AND FIELDS; ANNIHILATION; COMMUTATORS; EQUATIONS; HAMILTONIANS; LORENTZ INVARIANCE; MATHEMATICAL SOLUTIONS; POTENTIALS; QUANTUM FIELD THEORY; QUANTUM MECHANICS; RELATIVISTIC RANGE; WAVE FUNCTIONS