Counting totally real units and eigenvalue patterns in SLn( Z) and Sp2n( Z) in thin tubes

Abstract

For a vector v=(v1,… ,vn) with v1>·s>vn and Σ vi=0, we study the "directional entropy" of two arithmetic objects: (1) the logarithmic embeddings of degree-n totally real units, and (2) the logarithmic eigenvalue data of SLn( Z). In each case, the entropy in the direction of v is En(v)= SLn(v)=Σi=1n-1(n-i)\,vi, the value of the half-sum of positive roots of SLn( R) evaluated at v. More precisely, the number of objects lying in a thin tube around the ray R+v and of norm at most T grows on the order of \!(SLn(v)\,T) as T ∞. Because each eigenvalue data determines an SLn( R)-conjugacy class, this implies a lower bound of order \!(SLn(v)T) for the number of SLn( Z)-conjugacy classes with a prescribed eigenvalue data; we also obtain an upper bound of order \!(2SLn(v)T). A parallel argument for the symplectic lattice Sp2n( Z), taken in the symmetric direction v=(v1,… ,vn,-vn,… ,-v1), v1>·s>vn>0, shows that E2nSp(v)=Sp2n(v)=Σi=1n(n+1-i)vi, the half-sum of positive roots of Sp2n( R).