Hopf algebra

In mathematics, a Hopf algebra, named after Heinz Hopf, is a structure that is simultaneously an (unital associative) algebra and a (counital coassociative) coalgebra, with these structures' compatibility making it a bialgebra, and that moreover is equipped with an antiautomorphism satisfying a certain property. The representation theory of a Hopf algebra is particularly nice, since the existence of compatible comultiplication, counit, and antipode allows for the construction of tensor products of representations, trivial representations, and dual representations.

Hopf algebras occur naturally in algebraic topology, where they originated and are related to the H-space concept, in group scheme theory, in group theory (via the concept of a group ring), and in numerous other places, making them probably the most familiar type of bialgebra. Hopf algebras are also studied in their own right, with much work on specific classes of examples on the one hand and classification problems on the other. They have diverse applications ranging from Condensed-matter physics and quantum field theory[1] to string theory.[2]

Theorem (Hopf)[3] Let A be a finite-dimensional, graded commutative, graded cocommutative Hopf algebra over a field of characteristic 0. Then A (as an algebra) is a free exterior algebra with generators of odd degree.

Formal definition

Formally, a Hopf algebra is a (associative and coassociative) bialgebra H over a field K together with a K-linear map S: HH (called the antipode) such that the following diagram commutes:

Here Δ is the comultiplication of the bialgebra, ∇ its multiplication, η its unit and ε its counit. In the sumless Sweedler notation, this property can also be expressed as

S(c_{(1)})c_{(2)}=c_{(1)}S(c_{(2)})=\epsilon(c)1\qquad\mbox{ for all }c\in H.

As for algebras, one can replace the underlying field K with a commutative ring R in the above definition.[4]

The definition of Hopf algebra is self-dual (as reflected in the symmetry of the above diagram), so if one can define a dual of H (which is always possible if H is finite-dimensional), then it is automatically a Hopf algebra.[5]

Properties of the antipode

The antipode S is sometimes required to have a K-linear inverse, which is automatic in the finite-dimensional case, or if H is commutative or cocommutative (or more generally quasitriangular).

In general, S is an antihomomorphism,[6] so S2 is a homomorphism, which is therefore an automorphism if S was invertible (as may be required).

If S2 = idH, then the Hopf algebra is said to be involutive (and the underlying algebra with involution is a *-algebra). If H is finite-dimensional semisimple over a field of characteristic zero, commutative, or cocommutative, then it is involutive.

If a bialgebra B admits an antipode S, then S is unique ("a bialgebra admits at most 1 Hopf algebra structure").[7]

The antipode is an analog to the inversion map on a group that sends g to g−1.[8]

Hopf subalgebras

A subalgebra A of a Hopf algebra H is a Hopf subalgebra if it is a subcoalgebra of H and the antipode S maps A into A. In other words, a Hopf subalgebra A is a Hopf algebra in its own right when the multiplication, comultiplication, counit and antipode of H is restricted to A (and additionally the identity 1 of H is required to be in A). The Nichols–Zoeller freeness theorem established (in 1989) that the natural A-module H is free of finite rank if H is finite-dimensional: a generalization of Lagrange's theorem for subgroups. As a corollary of this and integral theory, a Hopf subalgebra of a semisimple finite-dimensional Hopf algebra is automatically semisimple.

A Hopf subalgebra A is said to be right normal in a Hopf algebra H if it satisfies the condition of stability, adr(h)(A) ⊆ A for all h in H, where the right adjoint mapping adr is defined by adr(h)(a) = S(h(1))ah(2) for all a in A, h in H. Similarly, a Hopf subalgebra A is left normal in H if it is stable under the left adjoint mapping defined by adl(h)(a) = h(1)aS(h(2)). The two conditions of normality are equivalent if the antipode S is bijective, in which case A is said to be a normal Hopf subalgebra.

A normal Hopf subalgebra A in H satisfies the condition (of equality of subsets of H): HA+ = A+H where A+ denotes the kernel of the counit on K. This normality condition implies that HA+ is a Hopf ideal of H (i.e. an algebra ideal in the kernel of the counit, a coalgebra coideal and stable under the antipode). As a consequence one has a quotient Hopf algebra H/HA+ and epimorphism HH/A+H, a theory analogous to that of normal subgroups and quotient groups in group theory.[9]

Hopf orders

A Hopf order O over an integral domain R with field of fractions K is an order in a Hopf algebra H over K which is closed under the algebra and coalgebra operations: in particular, the comultiplication Δ maps O to OO.[10]

Group-like elements

A group-like element is an element x such that Δ(x) = xx. The group-like elements form a group with inverse given by the antipode.[11] A primitive element x satisfies Δ(x) = x⊗1 + 1⊗x.[12][13]

Representation theory

Let A be a Hopf algebra, and let M and N be A-modules. Then, MN is also an A-module, with

a(m\otimes n):=\Delta(a)(m \otimes n)=(a_1\otimes a_2)(m\otimes n)=(a_1 m \otimes a_2 n)

for mM, nN and Δ(a) = (a1, a2). Furthermore, we can define the trivial representation as the base field K with

a(m):=\epsilon(a)m

for mK. Finally, the dual representation of A can be defined: if M is an A-module and M* is its dual space, then

(af)(m):=f(S(a)m)

where fM* and mM.

The relationship between Δ, ε, and S ensure that certain natural homomorphisms of vector spaces are indeed homomorphisms of A-modules. For instance, the natural isomorphisms of vector spaces MMK and MKM are also isomorphisms of A-modules. Also, the map of vector spaces M*MK with fmf(m) is also a homomorphism of A-modules. However, the map MM*K is not necessarily a homomorphism of A-modules.

Examples

Depending on Comultiplication Counit Antipode Commutative Cocommutative Remarks
group algebra KG group G Δ(g) = gg for all g in G ε(g) = 1 for all g in G S(g) = g−1 for all g in G if and only if G is abelian yes
functions f from a finite[14] group to K, KG (with pointwise addition and multiplication) finite group G Δ(f)(x,y) = f(xy) ε(f) = f(1G) S(f)(x) = f(x−1) yes if and only if G is commutative
Representative functions on a compact groupcompact group G Δ(f)(x,y) = f(xy) ε(f) = f(1G) S(f)(x) = f(x−1) yes if and only if G is commutative Conversely, every commutative involutive reduced Hopf algebra over C with a finite Haar integral arises in this way, giving one formulation of Tannaka–Krein duality.[15]
Regular functions on an algebraic group Δ(f)(x,y) = f(xy) ε(f) = f(1G) S(f)(x) = f(x−1) yes if and only if G is commutative Conversely, every commutative Hopf algebra over a field arises from a group scheme in this way, giving an antiequivalence of categories.[16]
Tensor algebra T(V) vector space V Δ(x) = x ⊗ 1 + 1 ⊗ x, x in V, Δ(1) = 1 ⊗ 1 ε(x) = 0 S(x) = −x for all x in 'T1(V) (and extended to higher tensor powers) If and only if dim(V)=0,1 yes symmetric algebra and exterior algebra (which are quotients of the tensor algebra) are also Hopf algebras with this definition of the comultiplication, counit and antipode
Universal enveloping algebra U(g) Lie algebra g Δ(x) = x ⊗ 1 + 1 ⊗ x for every x in g (this rule is compatible with commutators and can therefore be uniquely extended to all of U) ε(x) = 0 for all x in g (again, extended to U) S(x) = −x if and only if g is abelian yes
Sweedler's Hopf algebra H=K[c, x]/c2 = 1, x2 = 0 and xc = −cx. K is a field with characteristic different from 2 Δ(c) = cc, Δ(x) = cx + x ⊗ 1, Δ(1) = 1 ⊗ 1 ε(c) = 1 and ε(x) = 0 S(c) = c−1 = c and S(x) = −cx no no The underlying vector space is generated by {1, c, x, cx} and thus has dimension 4. This is the smallest example of a Hopf algebra that is both non-commutative and non-cocommutative.
ring of symmetric functions[17] in terms of complete homogeneous symmetric functions hk (k 1):

Δ(hk) = 1 ⊗ hk + h1hk−1 + ... + hk−1h1 + hk ⊗ 1.

ε(hk) = 0 S(hk) = (−1)k ek yes yes

Note that functions on a finite group can be identified with the group ring, though these are more naturally thought of as dual – the group ring consists of finite sums of elements, and thus pairs with functions on the group by evaluating the function on the summed elements.

Cohomology of Lie groups

The cohomology algebra of a Lie group is a Hopf algebra: the multiplication is provided by the cup-product, and the comultiplication

H^*(G) \rightarrow H^*(G\times G) \cong H^*(G)\otimes H^*(G)

by the group multiplication G × GG. This observation was actually a source of the notion of Hopf algebra. Using this structure, Hopf proved a structure theorem for the cohomology algebra of Lie groups.

Theorem (Hopf)[3] Let A be a finite-dimensional, graded commutative, graded cocommutative Hopf algebra over a field of characteristic 0. Then A (as an algebra) is a free exterior algebra with generators of odd degree.

Quantum groups and non-commutative geometry

Main article: quantum group

All examples above are either commutative (i.e. the multiplication is commutative) or co-commutative (i.e.[18] Δ = T ∘ Δ where the twist map[19] T: HHHH is defined by T(xy) = yx). Other interesting Hopf algebras are certain "deformations" or "quantizations" of those from example 3 which are neither commutative nor co-commutative. These Hopf algebras are often called quantum groups, a term that is so far only loosely defined. They are important in noncommutative geometry, the idea being the following: a standard algebraic group is well described by its standard Hopf algebra of regular functions; we can then think of the deformed version of this Hopf algebra as describing a certain "non-standard" or "quantized" algebraic group (which is not an algebraic group at all). While there does not seem to be a direct way to define or manipulate these non-standard objects, one can still work with their Hopf algebras, and indeed one identifies them with their Hopf algebras. Hence the name "quantum group".

Related concepts

Graded Hopf algebras are often used in algebraic topology: they are the natural algebraic structure on the direct sum of all homology or cohomology groups of an H-space.

Locally compact quantum groups generalize Hopf algebras and carry a topology. The algebra of all continuous functions on a Lie group is a locally compact quantum group.

Quasi-Hopf algebras are generalizations of Hopf algebras, where coassociativity only holds up to a twist. They have been used in the study of the Knizhnik–Zamolodchikov equations.[20]

Multiplier Hopf algebras introduced by Alfons Van Daele in 1994[21] are generalizations of Hopf algebras where comultiplication from an algebra (with or without unit) to the multiplier algebra of tensor product algebra of the algebra with itself.

Hopf group-(co)algebras introduced by V. G. Turaev in 2000 are also generalizations of Hopf algebras.

Weak Hopf algebras

Weak Hopf algebras, or quantum groupoids, are generalizations of Hopf algebras. Like Hopf algebras, weak Hopf algebras form a self-dual class of algebras; i.e., if H is a (weak) Hopf algebra, so is H*, the dual space of linear forms on H (with respect to the algebra-coalgebra structure obtained from the natural pairing with H and its coalgebra-algebra structure). A weak Hopf algebra H is usually taken to be a

 (\Delta(1) \otimes 1)(1 \otimes \Delta(1)) = (1 \otimes \Delta(1))(\Delta(1) \otimes 1) = (\Delta \otimes \mbox{Id})\Delta(1)
 \epsilon(abc) = \sum \epsilon(ab_{(1)})\epsilon(b_{(2)}c) = \sum \epsilon(ab_{(2)})\epsilon(b_{(1)}c)
for all a, b, and c in H.
  1. S(a_{(1)})a_{(2)} = 1_{(1)} \epsilon(a 1_{(2)}) for all a in H (the right-hand side is the interesting projection usually denoted by ΠR(a) or εs(a) with image a separable subalgebra denoted by HR or Hs);
  2. a_{(1)}S(a_{(2)}) =  \epsilon(1_{(1)}a)1_{(2)} for all a in H (another interesting projection usually denoted by ΠR(a) or εt(a) with image a separable algebra HL or Ht, anti-isomorphic to HL via S);
  3. S(a_{(1)})a_{(2)}S(a_{(3)}) = S(a) for all a in H.
Note that if Δ(1) = 1 ⊗ 1, these conditions reduce to the two usual conditions on the antipode of a Hopf algebra.

The axioms are partly chosen so that the category of H-modules is a rigid monoidal category. The unit H-module is the separable algebra HL mentioned above.

For example, a finite groupoid algebra is a weak Hopf algebra. In particular, the groupoid algebra on [n] with one pair of invertible arrows eij and eji between i and j in [n] is isomorphic to the algebra H of n x n matrices. The weak Hopf algebra structure on this particular H is given by coproduct Δ(eij) = eijeij, counit ε(eij) = 1 and antipode S(eij) = eji. The separable subalgebras HL and HR coincide and are non-central commutative algebras in this particular case (the subalgebra of diagonal matrices).

Early theoretical contributions to weak Hopf algebras are to be found in[22] as well as[23]

Hopf algebroids

See Hopf algebroid

Analogy with groups

Groups can be axiomatized by the same diagrams (equivalently, operations) as a Hopf algebra, where G is taken to be a set instead of a module. In this case:

In this philosophy, a group can be thought of as a Hopf algebra over the "field with one element".[24]

See also

Notes and references

Notes

  1. Haldane, F. D. M., Ha, Z. N. C., Talstra, J. C., Bernard, D., & Pasquier, V. (1992). Yangian symmetry of integrable quantum chains with long-range interactions and a new description of states in conformal field theory. Physical review letters, 69(14), 2021.
  2. Plefka, J., Spill, F., & Torrielli, A. (2006). Hopf algebra structure of the AdS/CFT S-matrix. Physical Review D, 74(6), 066008.http://dx.doi.org/10.1103/PhysRevD.74.066008, http://arxiv.org/abs/hep-th/0608038
  3. 1 2 Hopf, Heinz (1941). "Über die Topologie der Gruppen–Mannigfaltigkeiten und ihre Verallgemeinerungen". Ann. of Math. (2) (in German) 42: 22–52. doi:10.2307/1968985.
  4. Underwood (2011) p.55
  5. Underwood (2011) p.62
  6. Dăscălescu, Năstăsescu & Raianu (2001). Prop. 4.2.6. p. 153.
  7. Dăscălescu, Năstăsescu & Raianu (2001). Remarks 4.2.3. p. 151.
  8. Quantum groups lecture notes
  9. Montgomery (1993) p.36
  10. Underwood (2011) p.82
  11. Hazewinkel, Michiel; Gubareni, Nadezhda Mikhaĭlovna; Kirichenko, Vladimir V. (2010). Algebras, Rings, and Modules: Lie Algebras and Hopf Algebras. Mathematical surveys and monographs 168. American Mathematical Society. p. 149. ISBN 0-8218-7549-3.
  12. Mikhalev, Aleksandr Vasilʹevich; Pilz, Günter, eds. (2002). The Concise Handbook of Algebra. Springer-Verlag. p. 307, C.42. ISBN 0792370724.
  13. Abe, Eiichi (2004). Hopf Algebras. Cambridge Tracts in Mathematics 74. Cambridge University Press. p. 59. ISBN 0-521-60489-3.
  14. The finiteness of G implies that KGKG is naturally isomorphic to KGxG. This is used in the above formula for the comultiplication. For infinite groups G, KGKG is a proper subset of KGxG. In this case the space of functions with finite support can be endowed with a Hopf algebra structure.
  15. Hochschild, G (1965), Structure of Lie groups, Holden-Day, pp. 14–32
  16. Jantzen, Jens Carsten (2003), Representations of algebraic groups, Mathematical Surveys and Monographs 107 (2nd ed.), Providence, R.I.: American Mathematical Society, ISBN 978-0-8218-3527-2, section 2.3
  17. See Michiel Hazewinkel, Symmetric Functions, Noncommutative Symmetric Functions, and Quasisymmetric Functions, Acta Applicandae Mathematica, January 2003, Volume 75, Issue 1-3, pp 55–83
  18. Underwood (2011) p.57
  19. Underwood (2011) p.36
  20. Montgomery (1993) p. 203
  21. Alfons Van Daele. Multiplier Hopf algebras, Transactions of the American Mathematical Society 342(2) (1994) 917–932
  22. Gabriella Böhm, Florian Nill, Kornel Szlachanyi. J. Algebra 221 (1999), 385–438
  23. Dmitri Nikshych, Leonid Vainerman, in: New direction in Hopf algebras, S. Montgomery and H.-J. Schneider, eds., M.S.R.I. Publications, vol. 43, Cambridge, 2002, 211–262.
  24. Group = Hopf algebra « Secret Blogging Seminar, Group objects and Hopf algebras, video of Simon Willerton.

References

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