Shuffle relations for Hodge and motivic correlators

Abstract

The Hodge correlators Cor H(z0,z1,…,zn) are functions of several complex variables, defined by Goncharov (arXiv:0803.0297) by an explicit integral formula. They satisfy some linear relations: dihedral symmetry relations, distribution relations, and shuffle relations. We found new second shuffle relations. When zi∈0μN, where μN are the N-th roots of unity, they are expected to give almost all relations. When zi run through a finite subset S of C, the Hodge correlators describe the real mixed Hodge-Tate structure on the pronilpotent completion of the fundamental group π1 nil(CP1-(S∞),v∞), a Lie algebra in the category of mixed Q-Hodge-Tate structures. The Hodge correlators are lifted to canonical elements CorHod(z0,…,zn) in the Tannakian Lie coalgebra of this category. We prove that these elements satisfy the second shuffle relations. Let S⊂ Q. The pronilpotent fundamental group is the Betti realization of the motivic fundamental group, a Lie algebra in the category of mixed Tate motives over Q. The Hodge correlators are lifted to elements CorMot(z0,…,zn) in its Tannakian Lie coalgebra LieMT. We prove the second shuffle relations for these motivic elements. The universal enveloping algebra of LieMT was described by Goncharov via motivic multiple polylogarithms, which obey a similar yet different set of double shuffle relations. Motivic correlators have several advantages: they obey dihedral symmetry relations at all points, not only at roots of unity; they are defined for any curve, and the double shuffle relations admit a generalization to elliptic curves; and they describe elements of the motivic Lie coalgebra rather than its universal enveloping algebra.