C-P-T Fractionalization
Abstract
Discrete spacetime symmetries of parity P or reflection R, and time-reversal T, act naively as -involutions in the passive transformation on the spacetime coordinates; but together with a charge conjugation C, the total C-P-R-T symmetries have enriched active transformations on fields in representations of the spacetime-internal symmetry groups of quantum field theories (QFTs). In this work, we derive that these symmetries can be further fractionalized, especially in the presence of the fermion parity . We elaborate on examples including relativistic Lorentz invariant QFTs (e.g., spin-1/2 Dirac or Majorana spinor fermion theories) and nonrelativistic quantum many-body systems (involving Majorana zero modes), and comment on applications to spin-1 Maxwell electromagnetism (QED) or interacting Yang-Mills (QCD) gauge theories. We discover various C-P-R-T- group structures, e.g., Dirac spinor is in a projective representation of but in an (anti)linear representation of an order-16 nonabelian finite group, as the central product between an order-8 dihedral (generated by C and P) or quaternion group and an order-4 group generated by T with T. The general theme may be coined as C-P-T or C-R-T fractionalization.
Cite
@article{arxiv.2109.15320,
title = {C-P-T Fractionalization},
author = {Juven Wang},
journal= {arXiv preprint arXiv:2109.15320},
year = {2022}
}
Comments
8 pages. Heredity of setups: Spinor theories follow any standard QFT textbook. The 0+1d Majorana zero modes analysis follows arXiv:2011.13921, arXiv:2011.12320. Special thanks to Shing-Tung Yau on "Can C-P-T symmetries be fractionalized more than involutions?" v4: refinement