The Smallest Interacting Universe

Abstract

The co-emergence of locality between the Hamiltonian and initial state of the universe is studied in a simple toy model. We hypothesize a fundamental loss functional for the combined Hamiltonian and quantum state and minimize it by gradient descent. This minimization yields a tensor product structure simultaneously respected by both the Hamiltonian and the state, suggesting that locality can emerge by a process analogous to spontaneous symmetry breaking. We discuss the relevance of this program to the arrow of time problem. In our toy model, we interpret the emergence of a tensor factorization as the appearance of individual degrees of freedom within a previously undifferentiated (raw) Hilbert space. Earlier work [5, 6] looked at the emergence of locality in Hamiltonians only, and found strong numerical confirmation of that raw Hilbert spaces of = n are unstable and prefer to settle on tensor factorization when n=pq is not prime, and in [6] even primes were seen to "factor" after first shedding a small summand, e.g. 7=1+2· 3. This was found in the context of a rather general potential functional F on the space of metrics \gij\ on su(n), the Lie algebra of symmetries. This emergence of qunits through operator-level spontaneous symmetry breaking (SSB) may help us understand why the world seems to consist of myriad interacting degrees of freedom. But understanding why the universe has an initial Hamiltonian H0 with a many-body structure is of limited conceptual value unless the initial state, |0, is also structured by this tensor decomposition. Here we adapt F to become a functional on \g,|0\=(metrics)× (initial states), and find SSB now produces a conspiracy between g and |0, where they simultaneously attain low entropy by settling on the same qubit decomposition.