Multiplicative Invariant Fields of Dimension 6

Abstract

The finite subgroups of GL4(Z) are classified up to conjugation in BBNWZ; in particular, there exist 710 non-conjugate finite groups in GL4(Z). Each finite group G of GL4(Z) acts naturally on Z 4; thus we get a faithful G-lattice M with rankZ M=4. In this way, there are exactly 710 such lattices. Given a G-lattice M with rankZ M=4, the group G acts on the rational function field C(M):=C(x1,x2,x3,x4) by multiplicative actions, i.e. purely monomial automorphisms over C. We are concerned with the rationality problem of the fixed field C(M)G. A tool of our investigation is the unramified Brauer group of the field C(M)G over C. A formula of the unramified Brauer group Bru(C(M)G) for the multiplicative invariant field was found by Saltman in 1990. However, to calculate Bru(C(M)G) for a specific multiplicatively invariant field requires additional efforts, even when the lattice M is of rank equal to 4. Theorem 1. Among the 710 finite groups G, let M be the associated faithful G-lattice with rankZ M=4, there exist precisely 5 lattices M with Bru(C(M)G)≠ 0. In these situations, B0(G)=0 and thus Bru(C(M)G)⊂ H2(G,M). The GAP IDs of the five groups G are (4,12,4,12), (4,32,1,2), (4,32,3,2), (4,33,3,1), (4,33,6,1) in BBNWZ and in GAP. Theorem 2. There exist 6079 finite subgroups G in GL5(Z). Let M be the lattice with rank 5 associated to each group G. Among these lattices precisely 46 of them satisfy the condition Bru(C(M)G)≠ 0. A similar result for lattices of rank 6 is found also.