Higher Berry phase from projected entangled pair states in (2+1) dimensions

We consider families of invertible many-body quantum states in d spatial dimensions that are parameterized over some parameter space X. The space of such families is expected to have topologically distinct sectors classified by the cohomology group Hd+2(X;Z). These topological sectors are distinguished by a topological invariant built from a generalization of the Berry phase, called the higher Berry phase. In the previous work [Phys. Rev. B 109, 115152 (2024)2469-995010.1103/PhysRevB.109.115152], we introduced a generalized inner product for three one-dimensional many-body quantum states ("triple inner product"). The higher Berry phase for one-dimensional invertible states can be introduced through the triple inner product and furthermore the topological invariant, which takes its value in H3(X;Z), can be extracted. In this paper, we introduce an inner product of four two-dimensional invertible quantum many-body states. We use it to measure the topological nontriviality of parameterized families of 2d invertible states. In particular, we define a topological invariant of such families that takes values in H4(X;Z). Our formalism uses projected entangled pair states (PEPS). We also construct a specific example of nontrivial parameterized families of 2d invertible states parameterized over RP4 and demonstrate the use of our formula. Applications for symmetry-protected topological phases are also discussed.