Quantum group
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In mathematics and theoretical physics, quantum groups are examples of quasitriangular Hopf algebras. There are various structures referred to as quantum groups.
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[edit] Drinfel'd type quantum groups
One common structure, which is called a "quantum group", after the work of Vladimir Drinfel'd, Nicolai Reshetikhin, Michio Jimbo, and others, is a deformation of the universal enveloping algebra of a semisimple Lie algebra or, more generally, a Kac-Moody algebra.
Let A = (aij) be the Cartan matrix of the Kac-Moody algebra, and let q be a nonzero complex number distinct from 1, then the quantum group, Uq(G), where G is the Lie algebra whose Cartan matrix is A, is defined as the unital associative algebra with generators kλ (where λ is an element of the weight lattice, i.e. for all i), and ei and fi (for simple roots, αi), subject to
- k0 = 1,
- kλkμ = kλ + μ,
- ,
- ,
- ,
- , for ,
- , for ,
where , , , for all positive integers n, and . These are the q-factorial and q-series, respectively, the q-analogs of the ordinary factorial. The last two relations above are the q-Serre relations, the deformations of the Serre relations.
In the limit as , these relations approach the relations for the universal enveloping algebra Uq(G), where and as , where the element, tλ, of the Cartan subalgebra satisfies (tλ,h) = λ(h) for all h in the Cartan subalgebra.
There are various coassociative coproducts under which the quantum groups are Hopf algebras, for example,
-
- , , ,
-
- , , ,
-
- , , , where the set of generators has been extended, if required, to include kλ for λ which is expressible as the sum of an element of the weight lattice and half an element of the root lattice,
along with the reverse coproducts , where is given by , i.e.
-
- , , , where ,
-
- , , , where ,
-
- , , , where .
The counit on Uq(A) is the same for all these coproducts: ε(kλ) = 1, ε(ei) = 0, ε(fi) = 0, and the respective antipodes for the above coproducts are given by
-
- ,
-
- ,
-
- ,
-
- ,
-
- ,
-
- .
Alternatively, the quantum group Uq(G) can be regarded as an algebra over the field , the field of all rational functions of an indeterminate q over .
Similarly, the quantum group Uq(G) can be regarded as an algebra over the field , the field of all rational functions of an indeterminate q over (see below in the section on quantum groups at q = 0).
[edit] Representation Theory
Just as there are many different types of representation for Kac-Moody algebras and their universal enveloping algebras, so there are many different types of representation for quantum groups.
As is the case for all Hopf algebras, Uq(G) has an adjoint representation on itself as a module, with the action being given by
Adx.y = | ∑ | x(1)yS(x(2)) |
(x) |
[edit] Case 1: q is not a root of unity
One important type of representation is a weight representation, and the corresponding module is called a weight module. A weight module is a module with a basis of weight vectors. A weight vector is a nonzero vector v such that kλ.v = dλv for all λ, where dλ are complex numbers for all weights λ such that
-
- d0 = 1,
-
- dλdμ = dλ + μ, for all weights λ and μ.
A weight module is called integrable if the actions of ei and fi are locally nilpotent (i.e. for any vector v in the module, there exists a positive integer k, possibly dependent on v, such that for all i). In the case of integrable modules, the complex numbers dλ associated with a weight vector satisfy dλ = cλq(λ,ν), where ν is an element of the weight lattice, and cλ are complex numbers such that
-
- c0 = 1,
-
- cλcμ = cλ + μ, for all weights λ and μ,
-
- for all i.
Of special interest are highest weight representations, and the corresponding highest weight modules. A highest weight module is a module generated by a weight vector v, subject to kλ.v = dλv for all weights λ, and ei.v = 0 for all i. Similarly, a quantum group can have a lowest weight representation and lowest weight module, i.e. a module generated by a weight vector v, subject to kλ.v = dλv for all weights λ, and fi.v = 0 for all i.
Define a vector v to have weight ν if kλ.v = q(λ,ν)v for all λ in the weight lattice.
If G is a Kac-Moody algebra, then in any irreducible highest weight representation of Uq(G), with highest weight ν, the multiplicities of the weights are equal to their multiplicities in an irreducible representation of U(G) with equal highest weight. If the highest weight is dominant and integral (a weight μ is dominant and integral if μ satisfies the condition that 2(μ,αi) / (αi,αi) is a non-negative integer for all i), then the weight spectrum of the irreducible representation is invariant under the Weyl group for G, and the representation is integrable.
Conversely, if a highest weight module is integrable, then its highest weight vector v satisfies kλ.v = cλq(λ,ν)v, where cλ are complex numbers such that
-
- c0 = 1,
-
- cλcμ = cλ + μ, for all weights λ and μ,
-
- for all i,
and ν is dominant and integral.
As is the case for all Hopf algebras, the tensor product of two modules is another module. For an element x of Uq(G), and for vectors v and w in the respective modules, , so that , and in the case of coproduct Δ1, and .
The integrable highest weight module described above is a tensor product of a one-dimensional module (on which kλ = cλ for all λ, and ei = fi = 0 for all i) and a highest weight module generated by a nonzero vector v0, subject to kλ.v0 = q(λ,ν)v0 for all weights λ, and ei.v0 = 0 for all i.
In the specific case where G is a finite-dimensional Lie algebra (as a special case of a Kac-Moody algebra), then the irreducible representations with dominant integral highest weights are also finite-dimensional.
In the case of a tensor product of highest weight modules, its decomposition into submodules is the same as for the tensor product of the corresponding modules of the Kac-Moody algebra (the highest weights are the same, as are their multiplicities).
[edit] Case 2: q is a root of unity
[edit] Quasitriangulaity
[edit] Case 1: q is not a root of unity
Strictly, the quantum group Uq(G) is not quasitriangular, but it can be thought of as being "nearly quasitriangular" in that there exists an infinite formal sum which plays the role of an R-matrix. This infinite formal sum is expressible in terms of generators ei and fi, and Cartan generators tλ, where kλ is formally identified with . The infinite formal sum is the product of two factors, , and an infinite formal sum, where {λj} is a basis for the dual space to the Cartan subalgebra, and {μj} is the dual basis, and η is a sign (+1 or -1).
The formal infinite sum which plays the part of the R-matrix has a well-defined action on the tensor product of two irreducible highest weight modules, and also on the tensor product if two lowest weight modules. Specifically, if v has weight α and w has weight β, then , and the fact that the modules are both highest weight modules or both lowest weight modules reduces the action of the other factor on to a finite sum.
Specifically, if V is a highest weight module, then the formal infinite sum, R, has a well-defined, and invertible, action on , and this value of R (as an element of ) satisfies the Yang-Baxter equation, and therefore allows us to determine a representation of the braid group, and to define quasi-invariants for knots, links and braids.
[edit] Case 2: q is a root of unity
[edit] Quantum groups at q = 0
Masaki Kashiwara has researched the limiting behaviour of quantum groups as .
As a consequence of the defining relations for the quantum group Uq(G), Uq(G) can be regarded as a Hopf algebra over , the field of all rational functions of an indeterminate q over .
For simple root αi and non-negative integer n, define and (specifically, ). In an integrable module M, and for weight λ, a vector (i.e. a vector u in M with weight λ) can be uniquely decomposed into the sums
- ,
where , , only if , and only if . Linear mappings and can be defined on Mλ by
- ,
- .
Let A be the integral domain of all rational functions in which are regular at q = 0 (i.e. a rational function f(q) is an element of A if and only if there exist polynomials g(q) and h(q) in the polynomial ring such that , and f(q) = g(q) / h(q)). A crystal base for M is an ordered pair (L,B), such that
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- L is a free A-submodule of M such that ;
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- B is a -basis of the vector space L / qL over ,
-
- and , where and ,
-
- and for all i,
-
- and for all i,
-
- for all and , and for all i, if and only if .
To put this into a more informal setting, the actions of eifi and fiei are generally singular at q = 0 on an integrable module M. The linear mappings and on the module are introduced so that the actions of and are regular at q = 0 on the module. There exists a -basis of weight vectors for M, with respect to which the actions of and are regular at q = 0 for all i. The module is then restricted to the free A-module generated by the basis, and the basis vectors, the A-submodule and the actions of and are evaluated at q = 0. Furthermore, the basis can be chosen such that at q = 0, for all i, and are represented by mutual transposes, and map basis vectors to basis vectors or 0.
A crystal base can be represented by a directed graph with labelled edges. Each vertex of the graph represents an element of the -basis B of L / qL, and a directed edge, labelled by i, and directed from vertex v1 to vertex v2, represents that (and, equivalently, that ), where b1 is the basis element represented by v1, and b2 is the basis element represented by v2. The graph completely determines the actions of and at q = 0. If an integrable module has a crystal base, then the module is irreducible if and only if the graph representing the crystal base is connected (a graph is called "connected" if the set of vertices cannot be partitioned into the union of nontrivial disjoint subsets V1 and V2 such that there are no edges joining any vertex in V1 to any vertex in V2).
For any integrable module with a crystal base, the weight spectrum for the crystal base is the same as the weight spectrum for the module, and therefore the weight spectrum for the crystal base is the same as the weight spectrum for the corresponding module of the appropriate Kac-Moody algebra. The multiplicities of the weights in the crystal base are also the same as their multiplicities in the corresponding module of the appropriate Kac-Moody algebra.
It is a theorem of Kashiwara that every integrable highest weight module has a crystal base. Similarly, every integrable lowest weight module has a crystal base.
[edit] Tensor products of crystal bases
Let M be an integrable module with crystal base (L,B) and M' be an integrable module with crystal base (L',B'). For crystal bases, the coproduct Δ, given by , is adopted. The integrable module has crystal base , where . For a basis vector , define and . The actions of and on are given by
The decomposition of the product two integrable highest weight modules into irreducible submodules is determined by the decomposition of the graph of the crystal base into its connected components (i.e. the highest weights of the submodules are determined, and the multiplicity of each highest weight is determined).
[edit] Compact matrix quantum groups
S.L. Woronowicz introduced compact matrix quantum groups. Compact matrix quantum groups are abstract structures on which the "continuous functions" on the structure are given by elements of a C*-algebra. The geometry of a compact matrix quantum group is a special case of a noncommutative geometry.
The continuous complex-valued functions on a compact Hausdorff topological space form a commutative C*-algebra. By the Gelfand theorem, a commutative C*-algebra is isomorphic to the C*-algebra of continuous complex-valued functions on a compact Hausdorff topological space, and the topological space is uniquely determined by the C*-algebra up to homeomorphism.
For a compact topological group, G, there exists a C*-algebra homomorphism (where is the C*-algebra tensor product - the completion of the algebraic tensor product of C(G) and C(G)), such that Δ(f)(x,y) = f(xy) for all , and for all (where for all and all ). There also exists a linear multiplicative mapping , such that κ(f)(x) = f(x − 1) for all and all . Strictly, this does not make C(G) a Hopf algebra, unless G is finite. On the other hand, a finite-dimensional representation of G can be used to generate a *-subalgebra of C(G) which is also a Hopf *-algebra. Specifically, if is an n-dimensional representation of G, then for all i,j, and for all i,j. It follows that the *-algebra generated by uij for all i,j and κ(uij) for all i,j is a Hopf *-algebra: the counit is determined by ε(uij) = δij for all i,j (where δij is the Kronecker delta), the antipode is κ, and the unit is given by
1 = | ∑ | u1kκ(uk1) = | ∑ | κ(u1k)uk1. |
k | k |
As a generalization, a compact matrix quantum group is defined as a pair (C,u), where C is a C*-algebra and is a matrix with entries in C such that
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- The *-subalgebra, C0, of C, which is generated by the matrix elements of u, is dense in C;
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- There exists a C*-algebra homomorphism (where is the C*-algebra tensor product - the completion of the algebraic tensor product of C and C) such that for all i,j (Δ is called the comultiplication);
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- There exists a linear antimultiplicative map (the coinverse) such that κ(κ(v * ) * ) = v for all and
∑ κ(uik)ukj = ∑ uikκ(ukj) = δijI, k k
- There exists a linear antimultiplicative map (the coinverse) such that κ(κ(v * ) * ) = v for all and
As a consequence of continuity, the comultiplication on C is coassociative.
In general, C is not a bialgebra, and C0 is a Hopf *-algebra.
Informally, C can be regarded as the *-algebra of continuous complex-valued functions over the compact matrix quantum group, and u can be regarded as a finite-dimensional representation of the compact matrix quantum group.
A representation of the compact matrix quantum group is given by a corepresentation of the Hopf *-algebra (a corepresentation of a counital coassiative coalgebra A is a square matrix with entries in A (so ) such that for all i,j and ε(vij) = δij for all i,j). Furthermore, a representation, v, is called unitary if the matrix for v is unitary (or equivalently, if for all i, j).
An example of a compact matrix quantum group is SUμ(2), where the parameter μ is a positive real number. So SUμ(2) = (C(SUμ(2),u), where C(SUμ(2)) is the C*-algebra generated by α and γ,subject to
and so that the comultiplication is determined by , , and the coinverse is determined by κ(α) = α * , κ(γ) = − μ − 1γ, κ(γ * ) = − μγ * , κ(α * ) = α. Note that u is a representation, but not a unitary representation. u is equivalent to the unitary representation
Equivalently, SUμ(2) = (C(SUμ(2),w), where C(SUμ(2)) is the C*-algebra generated by α and β,subject to
and so that the comultiplication is determined by , , and the coinverse is determined by κ(α) = α * , κ(β) = − μ − 1β, κ(β * ) = − μβ * , κ(α * ) = α. Note that w is a unitary representation. The realizations can be identified by equating .
When μ = 1, then SUμ(2) is equal to the concrete compact group SU(2).
[edit] See also
[edit] Readings
- Elementary introduction to quantum groups
- Christian Kassel. Quantum Groups (Springer: 1994). ISBN 0-387-94370-6.
- Shahn Majid, N. J. Hitchin (series editor). A Quantum Groups Primer (Cambridge University Press: 2002). ISBN 0-521-01041-1.