English

Linear hyperbolic PDEs with non-commutative time

Mathematical Physics 2021-09-15 v2 High Energy Physics - Theory Analysis of PDEs math.MP

Abstract

Motivated by wave or Dirac equations on noncommutative deformations of Minkowski space, linear integro-differential equations of the form (D+λW)f=0(D+\lambda W)f=0 are studied, where DD is a normal or prenormal hyperbolic differential operator on Rn{\mathbb R}^n, λC\lambda\in\mathbb C is a coupling constant, and WW is a regular integral operator with compactly supported kernel. In particular, WW can be non-local in time, so that a Hamiltonian formulation is not possible. It is shown that for sufficiently small λ|\lambda|, the hyperbolic character of DD is essentially preserved. Unique advanced/retarded fundamental solutions are constructed by means of a convergent expansion in λ\lambda, and the solution spaces are analyzed. It is shown that the acausal behavior of the solutions is well-controlled, but the Cauchy problem is ill-posed in general. Nonetheless, a scattering operator can be calculated which describes the effect of WW on the space of solutions of DD. It is also described how these structures occur in the context of noncommutative Minkowski space, and how the results obtained here can be used for the analysis of classical and quantum field theories on such spaces.

Keywords

Cite

@article{arxiv.1307.1780,
  title  = {Linear hyperbolic PDEs with non-commutative time},
  author = {Gandalf Lechner and Rainer Verch},
  journal= {arXiv preprint arXiv:1307.1780},
  year   = {2021}
}

Comments

33 pages, 5 figures. V2: Slight reformulations

R2 v1 2026-06-22T00:46:37.729Z