A scaling hypothesis for projected entangled-pair states

Abstract

We introduce a new paradigm for scaling simulations with projected entangled-pair states (PEPS) for critical strongly-correlated systems, allowing for reliable extrapolations of PEPS data with relatively small bond dimensions D. The key ingredient consists of using the effective correlation length for inducing a collapse of data points, f(D,)=f((D,)), for arbitrary values of D and the environment bond dimension . As such we circumvent the need for extrapolations in and can use many distinct data points for a fixed value of D. Here, we need that the PEPS has been optimized using a fixed- gradient method, which can be achieved using a novel tensor-network algorithm for finding fixed points of 2-D transfer matrices, or by using the formalism of backwards differentiation. We test our hypothesis on the critical 3-D dimer model, the 3-D classical Ising model, and the 2-D quantum Heisenberg model.