English

Cocommutative vertex bialgebras

Quantum Algebra 2021-07-16 v1

Abstract

In this paper, the structure of cocommutative vertex bialgebras is investigated. For a general vertex bialgebra VV, it is proved that the set G(V)G(V) of group-like elements is naturally an abelian semigroup, whereas the set P(V)P(V) of primitive elements is a vertex Lie algebra. For gG(V)g\in G(V), denote by VgV_g the connected component containing gg. Among the main results, it is proved that if VV is a cocommutative vertex bialgebra, then V=gG(V)VgV=\oplus_{g\in G(V)}V_g, where V1V_{\bf 1} is a vertex subbialgebra which is isomorphic to the vertex bialgebra VP(V){\mathcal{V}}_{P(V)} associated to the vertex Lie algebra P(V)P(V), and VgV_g is a V1V_{\bf 1}-module for gG(V)g\in G(V). In particular, this shows that every cocommutative connected vertex bialgebra VV is isomorphic to VP(V){\mathcal{V}}_{P(V)} and hence establishes the equivalence between the category of cocommutative connected vertex bialgebras and the category of vertex Lie algebras. Furthermore, under the condition that G(V)G(V) is a group and lies in the center of VV, it is proved that V=VP(V)\C[G(V)]V={\mathcal{V}}_{P(V)}\otimes \C[G(V)] as a coalgebra where the vertex algebra structure is explicitly determined.

Keywords

Cite

@article{arxiv.2107.07290,
  title  = {Cocommutative vertex bialgebras},
  author = {Jianzhi Han and Haisheng Li and Yukun Xiao},
  journal= {arXiv preprint arXiv:2107.07290},
  year   = {2021}
}

Comments

36 pages

R2 v1 2026-06-24T04:13:38.924Z