Physics, Combinatorics and Hopf Algebras

Abstract

A number of problems in theoretical physics share a common nucleus of combinatoric nature. It is argued here that Hopf algebraic concepts and techiques can be particularly efficient in dealing with such problems. As a first example, a brief review is given of the recent work of Connes, Kreimer and collaborators on the algebraic structure of the process of renormalization in quantum field theory. Then the concept of k-primitive elements is introduced -- these are particular linear combinations of products of Feynman diagrams -- and it is shown, in the context of a toy-model, that they significantly reduce the computational cost of renormalization. As a second example, Sorkin's proposal for a family of generalizations of quantum mechanics, indexed by an integer k>2, is reviewed (classical mechanics corresponds to k=1, while quantum mechanics to k=2). It is then shown that the quantum measures of order k proposed by Sorkin can also be described as k-primitive elements of the Hopf algebra of functions on an appropriate infinite dimensional abelian group.

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