Chiral algebra

In mathematics, a chiral algebra is an algebraic structure introduced by Beilinson & Drinfeld (2004) as a rigorous version of the rather vague concept of a chiral algebra in physics. In Chiral Algebras, Beilinson and Drinfeld introduced the notion of chiral algebra, which based on the pseudo-tensor category of D-modules. They give a 'coordinate independent' notion of vertex algebras, which are based on formal power series. Chiral algebras on curves are essentially conformal vertex algebras.

Definition[edit]

A chiral algebra^[1] on a smooth algebraic curve $X$ is a right D-module ${\mathcal {A}}$ , equipped with a D-module homomorphism

\mu :{\mathcal {A}}\boxtimes {\mathcal {A}}(\infty \Delta )\rightarrow \Delta _{!}{\mathcal {A}}

on

X^{2}

and with an embedding

\Omega \hookrightarrow {\mathcal {A}}

, satisfying the following conditions

$\mu =-\sigma _{12}\circ \mu \circ \sigma _{12}$ (Skew-symmetry)
$\mu _{1\{23\}}=\mu _{\{12\}3}+\mu _{2\{13\}}$ (Jacobi identity)
The unit map is compatible with the homomorphism $\mu _{\Omega }:\Omega \boxtimes \Omega (\infty \Delta )\rightarrow \Delta _{!}\Omega$ ; that is, the following diagram commutes

{\begin{array}{lcl}&\Omega \boxtimes {\mathcal {A}}(\infty \Delta )&\rightarrow &{\mathcal {A}}\boxtimes {\mathcal {A}}(\infty \Delta )&\\&\downarrow &&\downarrow \\&\Delta _{!}{\mathcal {A}}&\rightarrow &\Delta _{!}{\mathcal {A}}&\\\end{array}}

Where, for sheaves

{\mathcal {M}},{\mathcal {N}}

on

X

, the sheaf

{\mathcal {M}}\boxtimes {\mathcal {N}}(\infty \Delta )

is the sheaf on

X^{2}

whose sections are sections of the external tensor product

{\mathcal {M}}\boxtimes {\mathcal {N}}

with arbitrary poles on the diagonal:

{\mathcal {M}}\boxtimes {\mathcal {N}}(\infty \Delta )=\varinjlim {\mathcal {M}}\boxtimes {\mathcal {N}}(n\Delta ),

\Omega

is the canonical bundle, and the 'diagonal extension by delta-functions'

\Delta _{!}

is

\Delta _{!}{\mathcal {M}}={\frac {\Omega \boxtimes {\mathcal {M}}(\infty \Delta )}{\Omega \boxtimes {\mathcal {M}}}}.

Relation to other algebras[edit]

Vertex algebra[edit]

The category of vertex algebras as defined by Borcherds or Kac is equivalent to the category of chiral algebras on $X=\mathbb {A} ^{1}$ equivariant with respect to the group $T$ of translations.

Factorization algebra[edit]

Chiral algebras can also be reformulated as factorization algebras.

References[edit]

Beilinson, Alexander; Drinfeld, Vladimir (2004), Chiral algebras, American Mathematical Society Colloquium Publications, vol. 51, Providence, R.I.: American Mathematical Society, ISBN 978-0-8218-3528-9, MR 2058353

^ Ben-Zvi, David; Frenkel, Edward (2004). Vertex algebras and algebraic curves (Second ed.). Providence, Rhode Island: American Mathematical Society. p. 339. ISBN 9781470413156.