Conserved charges for rational electromagnetic knots
Abstract
We revisit a newfound construction of rational electromagnetic knots based on the conformal correspondence between Minkowski space and a finite -cylinder. We present here a more direct approach for this conformal correspondence based on Carter-Penrose transformation that avoids a detour to de Sitter space. The Maxwell equations can be analytically solved on the cylinder in terms of harmonics , which can then be transformed into Minkowski coordinates using the conformal map. The resultant "knot basis" electromagnetic field configurations have non-trivial topology in that their field lines form closed knots. We consider finite, complex linear combinations of these knot-basis solutions for a fixed spin and compute all the conserved Noether charges associated with the conformal group. We find that the scalar charges either vanish or are proportional to the energy. For the non-vanishing vector charges, we find a nice geometric structure that facilitates computation of their spherical components as well. We present analytic results for all charges for up to . We demonstrate possible applications of our findings through some known previous results.
Cite
@article{arxiv.2106.05952,
title = {Conserved charges for rational electromagnetic knots},
author = {Lukas Hantzko and Kaushlendra Kumar and Gabriel Picanço Costa},
journal= {arXiv preprint arXiv:2106.05952},
year = {2022}
}
Comments
15+1 pages, 6 figures; v2: some minor grammar/typo errors corrected; v3: Section 1 modified and a new Section 4 added apart from some grammar/typo corrections to match the published version