Finding and characterising physical states of Euclidean Abelianized loop quantum gravity using neural quantum states

Abstract

We study physical (near-kernel of constraints) states of 4-d Euclidean loop quantum gravity in Smolin's weak coupling limit on the complete graph K5 using variational Monte Carlo with neural network quantum states. We investigate the Hamilton constraint H in the ordering proposed by Thiemann, as well as H and H+H. We find that the variational optimisation selects distinct solution families for H and H across several considered cutoffs on the kinematical degrees of freedom. The solution family of H is flat on all minimal loops and has non-vanishing volume expectation values. Its edge-charge marginals delocalise with increasing cutoff, which indicates they are approximations to solutions that are non-normalisable in the kinematical inner product. The solution family for H is normalisable, shows non-trivial charge correlations, lies in the kernel of volume and is not flat. H+H turns out to be much harder to solve and yields quasi-solutions combining features of both previous families. We characterise all solutions using chromaticity 1- and 2-point functions, minimal loop holonomies, geometric area and volume observables and show that the two families can be interpreted as, on the one hand, a family of states close to the Ashtekar-Lewandowski vacuum and the Dittrich-Geiller vacuum with some numerical noise on the other hand. We also present some results that link solutions of the truncated theory to solutions of the continuum theory.