This paper is comprised of two related parts. First we discuss which k-graph algebras have faithful traces. We characterise the existence of a faithful semifinite lowersemicontinuous gauge-invariant trace on C * (Λ) in terms of the existence of a faithful graph trace on Λ.Second, for k-graphs with faithful gauge invariant trace, we construct a smooth (k, ∞)summable semifinite spectral triple. We use the semifinite local index theorem to compute the pairing with K-theory. This numerical pairing can be obtained by applying the trace to a KK-pairing with values in the K-theory of the fixed point algebra of the T k action. As with graph algebras, the index pairing is an invariant for a finer structure than the isomorphism class of the algebra.2. k-Graph C * -Algebras 2.1. Higher-rank graphs and their C * -algebras. In this subsection we outline the basic notation and definitions of k-graphs and their C * -algebras. We refer the reader to [RSY] for a more thorough account.Higher-rank graphs. Throughout this paper, we regard N k as a monoid under pointwise addition. We denote the usual generators of N k by e 1 , . . . , e k , and for n ∈ N k and 1 ≤ i ≤ k, we denote the i th coordinate of n by n i ∈ N; so n = n i e i . For m, n ∈ N k , we write m ≤ n if m i ≤ n i for all i. By m < n, we mean m ≤ n and m = n. We use m ∨ n and m ∧ n to denote, respectively, the coordinate-wise maximum and coordinate-wise minimum of m and n; so that m ∧ n ≤ m, n ≤ m ∨ n and these are respectively the greatest lower bound and least upper bound of m, n in N k . Definition 2.1 (Kumjian-Pask [KP]). A graph of rank k or k-graph is a pair (Λ, d) consisting of a countable category Λ and a degree functor d : Λ → N k which satisfy the following factorisation property: if λ ∈ Mor(Λ) satisfies d(λ) = m + n, then there are unique morphisms µ, ν ∈ Mor(Λ) such that d(µ) = m, d(ν) = n, and λ = µ • ν.The factorisation property ensures (see [KP]) that the identity morphisms of Λ are precisely the morphisms of degree 0; that is {id o : o ∈ Obj(Λ)} = d −1 (0). This means that we may identify each object with its identity morphism, and we do this henceforth. This done, we can regard Λ as consisting only of its morphisms, and we write λ ∈ Λ to mean λ ∈ Mor(Λ).Since we are thinking of Λ as a kind of graph, we write r and s for the codomain and domain maps of Λ respectively. We refer to elements of Λ as paths, and to the paths of degree 0 (which correspond to the objects of Λ as above) as vertices. Extending these conventions, we refer to the elements of Λ with minimal nonzero degree (that is d −1 ({e 1 , . . . , e k }) as edges.
