Generalization of superconnection in noncommutative ... - CiteSeerX

Proc. Estonian Acad. Sci. Phys. Math., 2006, 55, 1, 3–15

Generalization of superconnection in noncommutative geometry Viktor Abramov Institute of Pure Mathematics, University of Tartu, J. Liivi 2, 51004 Tartu, Estonia; [email protected] Received 21 November 2005, in revised form 22 December 2005 Abstract. We propose the notion of a ZN -connection, where N ≥ 2, which can be viewed as a generalization of the notion of a Z2 -connection or superconnection. We use the algebraic approach to the theory of connections to give the definition of a ZN -connection and to explore its structure. It is well known that one of the basic structures of the algebraic approach to the theory of connections is a graded differential algebra with differential d satisfying d2 = 0. In order to construct a ZN -generalization of a superconnection for any N > 2, we make use of a ZN -graded q -differential algebra, where q is a primitive N th root of unity, with N -differential d satisfying dN = 0. The concept of a graded q -differential algebra arises naturally within the framework of noncommutative geometry and the use of this algebra in our construction involves the appearance of q -deformed structures such as graded q -commutator, graded q -Leibniz rule, and q -binomial coefficients. Particularly, if N = 2, q = −1, then the notion of a ZN -connection coincides with the notion of a superconnection. We define the curvature of a ZN -connection and prove that it satisfies the Bianchi identity. Key words: superconnection, covariant derivative, graded differential algebra, graded q -differential algebra.

1. INTRODUCTION The concept of a superconnection was proposed by Mathai and Quillen [1 ] (see also [2 ]) in the 1980s to represent the Thom class of a vector bundle by a differential form having a Gaussian shape. Later, Atiyah and Jeffrey [3 ] proposed the geometric approach to a topological quantum field theory on a four-dimensional manifold [4 ] based on the superconnection formalism. Assuming that a vector bundle π : E → M has a Z2 -graded structure, i.e. it is a superbundle, the total grading of an E-valued differential form can be defined as the sum of two 3

gradings, one of which comes from the Z2 -graded structure of the algebra of differential forms on a base manifold M and the other from a Z2 -graded structure of a superbundle E. A superconnection is a linear mapping of odd degree with respect to this total grading, behaving like a graded differentiation with respect to the multiplication by differential forms. Consequently, if we wish to generalize the notion of a superconnection to any integer N > 2, we must have a ZN -graded analogue of an algebra of differential forms, and assuming that a vector bundle has also a ZN -graded structure, we can elaborate a generalization of a superconnection following the scheme proposed by Mathai and Quillen. In the present paper we introduce the notion of a ZN -connection, where N is any integer satisfying N ≥ 2, within the framework of an algebraic approach to the theory of connections. The first component of our construction is a ZN -graded q-differential algebra [5−8 ], where q is a primitive N th root of unity, denoted by B. This algebra plays the role of an analogue of an algebra of differential forms. It should be mentioned that a differential d of B satisfies dN = 0. The second component is a ZN -graded left module E over the subalgebra A ⊂ B of the elements of grading zero of B. From a geometric point of view, a module E can be considered as an analogue of the space of sections of a ZN -graded vector bundle. Taking the tensor product EB = B ⊗A E, which can be viewed as an analogue of a space of ZN -graded vector bundle valued differential forms, and defining the ZN -graded structure on this product, we give the definition of a ZN -connection D in the spirit of Mathai and Quillen. We show that the N th power of a ZN -connection is the grading zero endomorphism of the left B-module EB , and we define the curvature FD of a ZN connection by FD = DN . It is proved that the curvature of a ZN -connection satisfies the Bianchi identity.

2. GRADED q-DIFFERENTIAL ALGEBRAS In this section we describe a generalization of a graded differential algebra, which naturally arises in the framework of q-deformed structures. This generalization is called a graded q-differential algebra, where q is a primitive N th root of unity. We show that given a graded unital associative algebra over C with element v satisfying v N = e, where e is the identity element of this algebra, one can construct the graded q-differential algebra by means of a q-commutator. Let B = ⊕k∈Z B k be an associative unital Z-graded algebra over C. We shall denote the identity element of B by e and the grading of a homogeneous element ω ∈ B by |ω|, i.e. if ω ∈ Bk , then |ω| = k. An algebra B is said to be a graded q-differential algebra ([5,6 ]), where q is a primitive N th root of unity (N ≥ 2), if it is endowed with a linear mapping d : B k → B k+1 of degree 1 satisfying the graded q-Leibniz rule d(ω ω 0 ) = d(ω) ω 0 + q |ω| ω d(ω 0 ), where ω, ω 0 ∈ B, and dN (ω) = 0 for any ω ∈ B. A mapping d is called an N -differential of a graded q-differential algebra. It is easy to see that a graded q-differential algebra is a generalization of 4

the notion of a graded differential algebra, since a graded differential algebra is a particular case of a graded q-differential algebra if N = 2 and q = −1. From the graded structure of an algebra B it follows that the subspace B 0 ⊂ B of elements of grading zero is the subalgebra of an algebra B. The pair (B, d) is said to be an N -differential calculus on a unital associative algebra A if B is a graded q-differential algebra with N -differential d and A = B 0 . For any k ∈ Z the subspace B k of elements of grading k has the structure of a bimodule over the subalgebra B 0 and a graded q-differential algebra can be viewed as an N -differential complex ([6 ]) d k−1 d k d k+1 d ... → B →B →B →. . . ,

with differential d satisfying the graded q-Leibniz rule. If B is a Z-graded q-differential algebra, then we can define the ZN -graded structure on an algebra B by putting B p¯ = ⊕i∈Z B N i+p , where p = 0, 1, 2, . . . , N − 1, and p¯ is the residue class of an integer p modulo N . Then B = ⊕p∈ZN B p . In what follows, if a graded structure of an algebra B is concerned, we shall always mean the above-described ZN -graded structure of B. Since all graded structures considered in this paper are ZN -graded structures, we always assume that the values of each index related to a graded structure are elements of ZN . If there is no confusion, we shall denote the values of indices by 0, 1, 2, . . . , N − 1 meaning the residue classes modulo N . Let us now show that if a graded unital associative algebra contains an element v satisfying v N = e, where e is the identity element of this algebra, then one equips this algebra with the N -differential satisfying the graded q-Leibniz rule, turning this algebra into a graded q-differential algebra. Let A be an associative unital ZN -graded algebra over the complex numbers C and Ak ⊂ A be the subspace of homogeneous elements of a grading k. Given a complex number q 6= 1, one defines a q-commutator of two homogeneous elements w, w0 ∈ A by the formula 0

[w, w0 ]q = ww0 − q |w||w | w0 w. Using the associativity of an algebra A and the property |ww0 | = |w| + |w0 | of its graded structure, it is easy to show that for any homogeneous elements w, w0 , w00 ∈ A it holds that 0

[w, w0 w00 ]q = [w, w0 ]q w00 + q |w||w | w0 [w, w00 ]q .

(1)

Given an element v of grading 1, i.e. v ∈ A1 , one can define the mapping dv : Ak → Ak+1 by the formula dv w = [v, w]q , w ∈ Ak . It follows from the property of q-commutator (1) that dv is the linear mapping of degree 1 satisfying the graded q-Leibniz rule dv (ww0 ) = dv (w)w0 + q |w| wdv (w0 ), where w, w0 are homogeneous elements of A. Let [k]q = 1 + q + q 2 + . . . + q k−1 and [k]q ! = [1]q [2]q . . . [k]q . 5

Lemma 1. For any integer k ≥ 2 the kth power of the mapping dv can be written as follows: k X (k) dkv w = pi v k−i wv i , i=0

where w is a homogeneous element of A and (k) pi

i |w|i

= (−1) q

[k]q ! = (−1)i q |w|i [i]q ![k − i]q !

|w|i = i|w| +



k i



,

q

i(i − 1) . 2

The proof of this lemma is based on the following identities: (k)

(k+1)

p0 = p0 (k+1)

pi

= 1,

(k)

= pi

(k+1)

(k)

pk+1 = −q |w|+k pk , (k)

− q |w|+k pi−1 , 1 ≤ i ≤ k.

Theorem 1. If N is an integer such that N ≥ 2, q is a primitive N th root of unity, A is a ZN -graded algebra containing an element v satisfying v N = e, where e is the identity element of an algebra A, then A equipped with the linear mapping dv = [v, ]q is a graded q-differential algebra with N -differential dv , i.e. dv satisfies the graded q-Leibniz rule and dN v w = 0 for any w ∈ A. Proof. It follows from Lemma 1 that if q is a primitive N th root of unity, then (N ) for any integer l = 1, 2, . . . , N − 1 the coefficient pl contains the factor [N ]q which vanishes in the case of q being a primitive N th root of unity. This implies (N ) N N |w|N wv N . Taking into account that pl = 0. Thus dN v (w) = v w + (−1) q N |w|N )w = λ w. The coefficient v N = e, we obtain dN v (w) = (1 + (−1) q N |w| λ = 1 + (−1) q N vanishes if q is a primitive N th root of unity. Indeed, if N is an odd number, then 1 − (q N )(N −1)/2 = 0. In the case of an even integer N we have 1 + (q N/2 )N −1 = 1 + (−1)N −1 = 0, and this ends the proof of the theorem. For applications in differential geometry it is important to have a realization of a graded q-differential algebra as an algebra of analogues of differential forms on a geometric space. The proved theorem allows us to construct a graded q-differential algebra taking as a starting point a generalized Clifford algebra. The structure of a generalized Clifford algebra suggests that we shall get an analogue of an algebra of differential forms with an N -differential on a noncommutative space. Indeed, let us remind that a generalized Clifford algebra Cp,N is a unital associative algebra over C generated by γ1 , γ2 , . . . , γp which are subjected to the relations γi γj = q sg(j−i) γj γi , 6

γiN = 1,

i, j = 1, 2, . . . , p,

(2)

where q is a primitive N th root of unity and sg(x) is the usual sign function. The structure of a graded q-differential algebra in the case of the generalized Clifford algebra with two generators is studied in [9 ]. In this case the corresponding generalized Clifford algebra C2,N can be interpreted as an algebra of polynomial functions on a reduced quantum plane. Let us denote by x, y the generators of the algebra in this case. The relations (2) take on the form xy = q yx, xN = y N = 1. The algebra C2,N becomes a ZN -graded algebra if we assign the grading zero to the generator x, the grading 1 to the generator y and define the grading of any monomial made up of generators x, y as the sum of gradings of its factors. The differential d is defined by dw = [y, w]q , w ∈ C2,N . Since y N = 1, it follows from Theorem 1 that the algebra C2,N is a graded q-differential algebra and d is its N -differential. We give this graded q-differential algebra and its N -differential d the following geometric interpretation: the subalgebra of polynomials of grading zero is the algebra of functions on a one-dimensional space with “coordinate” x, and the elements of higher gradings expressed in terms of “coordinate” x and its “differential” dx are the analogues of differential forms with exterior differential d. We have dx = y∆q x = y(x − qx). Since dk 6= 0 for k < N , a differential k-form w may be expressed either by means of (dx)k or by means of dk x, where dk x =

[k]q (dx)k k(k−1)/2 q

x1−k .

If w = (dx)k f (x), where f (x) is a polynomial of grading zero, and dw = (k) (dx)k+1 δx (f ), then δx(k) (f ) = (∆q x)−1 (q −k f − q k A(f )), where A is the homomorphism of the algebra of polynomials of grading zero (k) determined by A(x) = qx. The higher-order derivatives δx have the property δx(k) (f g) = δx(k) (f ) g + q k A(f ) δx(0) (g), (0)

∂g ∂x (k) δx

k = 0, 1, 2, . . . , N − 1,

where δx (g) =

= (∆q x)−1 (g − A(g)) is the A-twisted derivative. A higher-

order derivative

can be expressed in terms of the derivative δx(k) = q k

∂ ∂x

as follows:

q −k − q k −1 ∂ + x . ∂x 1−q

The realization of a graded q-differential algebra as an algebra of analogues of differential forms on an ordinary (commutative) space is constructed in [10 ]. Let x1 , x2 , . . . , xn be the coordinates of an n-dimensional space Rn , C ∞ (Rn ) be the algebra of smooth C-valued functions, and dx1 , dx2 , . . . , dxn be the differentials of the coordinates. Let N = {1, 2, . . . , n} be the set of integers, I be a subset of N , and |I| be the number of elements in I. Given any subset I of N , i.e. 7

I = {i1 , i2 , . . . , ik } ⊂ N , 1 ≤ i1 < i2 < . . . ik ≤ n, we associate to I the formal monomial dxI , where dxI = dxi1 dxi2 . . . dxin and dx∅ = 1. Let Ω(Rn ) be the free left C ∞ (Rn )-module generated by all formal monomials dxI . It is evident that Ω(Rn ) has a natural Z-graded structure Ω(Rn ) = ⊕k Ωk (Rn ), where Ωk (Rn ) is the left C ∞ (Rn )-module freely generated by all dxI , where I contains k elements. An element of the module Ωk (Rn ) has the form ω=

X

fI dxI =

I,|I|=k

X

fi1 i2 ...ik dxi1 dxi2 . . . dxik ,

(3)

1≤i1