Bianchi groups and automorphisms of rank-four K3 surfaces

Abstract

We relate the arithmetic of Bianchi groups to automorphism groups of Picard-rank-four K3 surfaces. Let K be an imaginary quadratic field with ring of integers OK, and let SK=Herm2( OK) be the rank-four lattice of 2×2 Hermitian matrices over OK, equipped with the quadratic form 2. For an odd integer N≥1, we consider a very general SK(2N)-polarized K3 surface XK,2N. We prove that its automorphism group is commensurable with a level-2N congruence subgroup of the Bianchi group. Furthermore, we also obtain exact realizations of congruence subgroups as full automorphism groups. Namely, if K= Q(i) or K= Q(-p), where p is prime, then \[ Aut(XK,2) PΓK(2). \] Thus, for every prime p, the projective principal congruence subgroup of level 2 over O Q(-p) occurs as the full automorphism group of a Picard-rank-four K3 surface. At higher levels, the full automorphism group may be either the projective principal congruence subgroup or the strictly larger projective level subgroup BiK(2N), depending on the arithmetic of the primes dividing the level. We further explain these arithmetic groups geometrically. The surfaces XK,2 arise as deformations of the Kummer surfaces Km(EK× EK), yielding explicit double-cover models and genus-one fibrations. For K= Q(-2) and K= Q(-7), the automorphism group is generated by Mordell--Weil translations associated with genus-one fibrations coming from cusps, together with the covering involution. For K= Q(i) and K= Q(-3), we construct complete-intersection models in products of projective spaces and show that their automorphism groups are generated by deck involutions.