Fermion-bag inspired Hamiltonian lattice field theory for fermionic quantum criticality

Abstract

Motivated by the fermion bag approach we construct a new class of Hamiltonian lattice field theories that can help us to study fermionic quantum critical points, particularly those with four-fermion interactions. Although these theories are constructed in discrete-time with a finite temporal lattice spacing , when → 0, conventional continuous-time Hamiltonian lattice field theories are recovered. The fermion bag algorithms run relatively faster when =1 as compared to → 0, but still allow us to compute universal quantities near the quantum critical point even at such a large value of . As an example of this new approach, here we study the Nf=1 Gross-Neveu chiral Ising universality class in 2+1 dimensions by calculating the critical scaling of the staggered mass order parameter. We show that we are able to study lattice sizes up to 1002 sites when =1, while with comparable resources we can only reach lattice sizes of up to 642 when → 0. The critical exponents obtained in both these studies match within errors.