Wavelet field decomposition and UV `opaqueness'
Abstract
A large body of work over several decades indicates that, in the presence of gravitational interactions, there is loss of localization resolution within a fundamental ( Planck) length scale . We develop a general formalism based on wavelet decomposition of fields that takes this UV `opaqueness' into account in a natural and mathematically well-defined manner. This is done by requiring fields in a local Lagrangian to be expandable in only the scaling parts of a (complete or, in a more general version, partial) wavelet Multi-Resolution Analysis. This delocalizes the interactions, now mediated through the opaque regions, inside which they are rapidly decaying. The opaque regions themselves are capable of discrete excitations of spacing. The resulting effective Feynman rules, which give UV regulated and (perturbatively) unitary physical amplitudes, resemble those of string field theory.
Cite
@article{arxiv.2104.04098,
title = {Wavelet field decomposition and UV `opaqueness'},
author = {E. T. Tomboulis},
journal= {arXiv preprint arXiv:2104.04098},
year = {2021}
}
Comments
22 pages, 2 figures, minor comments added, typos corrected, published version