Quasitriangular Hopf algebra

In mathematics, a Hopf algebra, H, is quasitriangular[1] if there exists an invertible element, R, of H H {\displaystyle H\otimes H} such that

  • R   Δ ( x ) R 1 = ( T Δ ) ( x ) {\displaystyle R\ \Delta (x)R^{-1}=(T\circ \Delta )(x)} for all x H {\displaystyle x\in H} , where Δ {\displaystyle \Delta } is the coproduct on H, and the linear map T : H H H H {\displaystyle T:H\otimes H\to H\otimes H} is given by T ( x y ) = y x {\displaystyle T(x\otimes y)=y\otimes x} ,
  • ( Δ 1 ) ( R ) = R 13   R 23 {\displaystyle (\Delta \otimes 1)(R)=R_{13}\ R_{23}} ,
  • ( 1 Δ ) ( R ) = R 13   R 12 {\displaystyle (1\otimes \Delta )(R)=R_{13}\ R_{12}} ,

where R 12 = ϕ 12 ( R ) {\displaystyle R_{12}=\phi _{12}(R)} , R 13 = ϕ 13 ( R ) {\displaystyle R_{13}=\phi _{13}(R)} , and R 23 = ϕ 23 ( R ) {\displaystyle R_{23}=\phi _{23}(R)} , where ϕ 12 : H H H H H {\displaystyle \phi _{12}:H\otimes H\to H\otimes H\otimes H} , ϕ 13 : H H H H H {\displaystyle \phi _{13}:H\otimes H\to H\otimes H\otimes H} , and ϕ 23 : H H H H H {\displaystyle \phi _{23}:H\otimes H\to H\otimes H\otimes H} , are algebra morphisms determined by

ϕ 12 ( a b ) = a b 1 , {\displaystyle \phi _{12}(a\otimes b)=a\otimes b\otimes 1,}
ϕ 13 ( a b ) = a 1 b , {\displaystyle \phi _{13}(a\otimes b)=a\otimes 1\otimes b,}
ϕ 23 ( a b ) = 1 a b . {\displaystyle \phi _{23}(a\otimes b)=1\otimes a\otimes b.}

R is called the R-matrix.

As a consequence of the properties of quasitriangularity, the R-matrix, R, is a solution of the Yang–Baxter equation (and so a module V of H can be used to determine quasi-invariants of braids, knots and links). Also as a consequence of the properties of quasitriangularity, ( ϵ 1 ) R = ( 1 ϵ ) R = 1 H {\displaystyle (\epsilon \otimes 1)R=(1\otimes \epsilon )R=1\in H} ; moreover R 1 = ( S 1 ) ( R ) {\displaystyle R^{-1}=(S\otimes 1)(R)} , R = ( 1 S ) ( R 1 ) {\displaystyle R=(1\otimes S)(R^{-1})} , and ( S S ) ( R ) = R {\displaystyle (S\otimes S)(R)=R} . One may further show that the antipode S must be a linear isomorphism, and thus S2 is an automorphism. In fact, S2 is given by conjugating by an invertible element: S 2 ( x ) = u x u 1 {\displaystyle S^{2}(x)=uxu^{-1}} where u := m ( S 1 ) R 21 {\displaystyle u:=m(S\otimes 1)R^{21}} (cf. Ribbon Hopf algebras).

It is possible to construct a quasitriangular Hopf algebra from a Hopf algebra and its dual, using the Drinfeld quantum double construction.

If the Hopf algebra H is quasitriangular, then the category of modules over H is braided with braiding

c U , V ( u v ) = T ( R ( u v ) ) = T ( R 1 u R 2 v ) {\displaystyle c_{U,V}(u\otimes v)=T\left(R\cdot (u\otimes v)\right)=T\left(R_{1}u\otimes R_{2}v\right)} .

Twisting

The property of being a quasi-triangular Hopf algebra is preserved by twisting via an invertible element F = i f i f i A A {\displaystyle F=\sum _{i}f^{i}\otimes f_{i}\in {\mathcal {A\otimes A}}} such that ( ε i d ) F = ( i d ε ) F = 1 {\displaystyle (\varepsilon \otimes id)F=(id\otimes \varepsilon )F=1} and satisfying the cocycle condition

( F 1 ) ( Δ i d ) ( F ) = ( 1 F ) ( i d Δ ) ( F ) {\displaystyle (F\otimes 1)\cdot (\Delta \otimes id)(F)=(1\otimes F)\cdot (id\otimes \Delta )(F)}

Furthermore, u = i f i S ( f i ) {\displaystyle u=\sum _{i}f^{i}S(f_{i})} is invertible and the twisted antipode is given by S ( a ) = u S ( a ) u 1 {\displaystyle S'(a)=uS(a)u^{-1}} , with the twisted comultiplication, R-matrix and co-unit change according to those defined for the quasi-triangular quasi-Hopf algebra. Such a twist is known as an admissible (or Drinfeld) twist.

See also

  • Quasi-triangular quasi-Hopf algebra
  • Ribbon Hopf algebra

Notes

  1. ^ Montgomery & Schneider (2002), p. 72.

References

  • Montgomery, Susan (1993). Hopf algebras and their actions on rings. Regional Conference Series in Mathematics. Vol. 82. Providence, RI: American Mathematical Society. ISBN 0-8218-0738-2. Zbl 0793.16029.
  • Montgomery, Susan; Schneider, Hans-Jürgen (2002). New directions in Hopf algebras. Mathematical Sciences Research Institute Publications. Vol. 43. Cambridge University Press. ISBN 978-0-521-81512-3. Zbl 0990.00022.