Dyadic Steenrod algebra and its applications

Abstract

First, by inspiration of the results of Wood differential,problems, but with the methods of non-commutative geometry and different approach, we extend the coefficients of the Steenrod squaring operations from the filed F2 to the dyadic integers Z2 and call the resulted operations the dyadic Steenrod squares, denoted by Jqk. The derivation-like operations Jqk generate a graded algebra, called the dyadic Steenrod algebra, denoted by J2 acting on the polynomials Z2[1, …, n]. Being J2 an Ore domain, enable us to localize J2 which leads to the appearance of the integration-like operations Jq-k satisfying the Jq-kJqk=1=JqkJq-k. These operations are enough to exhibit a kind of differential equation, the dyadic Steenrod ordinary differential equation. Then we prove that the completion of Z2[1, …, n] in the linear transformation norm coincides with a certain Tate algebra. Therefore, the rigid analytic geometry is closely related to the dyadic Steenrod algebra. Finally, we define the Adem norm \| \ \|A in which the completion of Z2[1, …, n] is Z21,…,n, the n-variable formal power series. We surprisingly prove that an element f ∈ Z2 1,…,n is hit if and only if \|f\|A<1. This suggests new techniques for the traditional Peterson hit problem in finding the bases for the cohit modules.