Periodic continued fractions over S-integers in number fields and Skolem's p-adic method

Abstract

We generalize the classical theory of periodic continued fractions (PCFs) over Z to rings O of S-integers in a number field. Let B=\β, β*\ be the multi-set of roots of a quadratic polynomial in O[x]. We show that PCFs P=[b1,…,bN,a1… ,ak] of type (N,k) potentially converging to a limit in B are given by O-points on an affine variety V:=V( B)N,k generically of dimension N+k-2. We give the equations of V in terms of the continuant polynomials of Wallis and Euler. The integral points V( O) are related to writing matrices in SL2( O) as products of elementary matrices. We give an algorithm to determine if a PCF converges and, if so, to compute its limit. Our standard example generalizes the PCF 2=[1,2] to the Z2-extension of Q: Fn= Q(αn), αn:=2(2π/2n+2), with integers On= Z[αn]. We want to find the PCFs of αn+1 over On of type (N,k) by finding the On-points on V( Bn+1)N,k for Bn+1:=\αn+1, -αn+1\. There are three types (N,k)=(0,3), (1,2), (2,1) such that the associated PCF variety V( B)N,k is a curve; we analyze these curves. For generic B, Siegel's theorem implies that each of these three V( B)N,k( O) is finite. We find all the On-points on these PCF curves V( Bn+1)N,k for n=0,1. When n=1 we make extensive use of Skolem's p-adic method for p=2, including its application to Ljunggren's equation x2 + 1 =2y4.