The rank evolution of block bidiagonal matrices over finite fields

Abstract

We investigate uniform random block lower bidiagonal matrices over the finite field Fq, and prove that their rank undergoes a phase transition. First, we consider block lower bidiagonal matrices with (kn+1)× kn blocks where each block is of size n× n. We prove that if kn qn/2, then these matrices have full rank with high probability, and if kn qn/2, then the rank has Gaussian fluctuations. Second, we consider block lower bidiagonal matrices with kn× kn blocks where each block is of size n× n. We prove that if kn qn/2, then the rank exhibits the same constant order fluctuations as the rank of the matrix products considered by Nguyen and Van Peski, and if kn qn/2, then the rank has Gaussian fluctuations. Finally, we also consider a truncated version of the first model, where we prove that at kn≈ qn/2, we have a phase transition between a Cohen-Lenstra and a Gaussian limiting behavior of the rank. We also show that there is a localization/delocalization phase transition for the vectors in the kernels of these matrices at the same critical point. In all three cases, we also provide a precise description of the behavior of the rank at criticality. These results are proved by analyzing the limiting behavior of a Markov chain obtained from the increments of the ranks of these matrices.

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