Abstract
A gapped many-body system is described by path integral on a space-time lattice $C^{d+1}$, which gives rise to a partition function $Z(C^{d+1})$ if $\partial C^{d+1} =\emptyset$, and gives rise to a vector $|\Psi\rangle$ on the boundary of space-time if $\partial C^{d+1} \neq\emptyset$. We show that $V = \text{log} \sqrt{\langle\Psi|\Psi\rangle}$ satisfies the inclusion-exclusion property $\frac{V(A\cup B)+V(A\cap B)}{V(A)+V(B)}=1$ and behaves like a volume of the space-time lattice $C^{d+1}$ in large lattice limit (i.e. thermodynamics limit). This leads to a proposal that the vector $|\Psi\rangle$ is the quantum-volume of the space-time lattice $C^{d+1}$. The inclusion-exclusion property does not apply to quantum-volume since it is a vector. But quantum-volume satisfies a quantum additive property. The violation of the inclusion-exclusion property by $V = \text{log} \sqrt{\langle\Psi|\Psi\rangle}$ in the subleading term of thermodynamics limit gives rise to topological invariants that characterize the topological order in the system. This is a systematic way to construct and compute topological invariants from a generic path integral. For example, we show how to use non-universal partition functions $Z(C^{2+1})$ on several related space-time lattices $C^{2+1}$ to extract $(M_f)_{11}$ and $\text{Tr}(M_f)$, where $M_f$ is a representation of the modular group $SL(2,\mathbb{Z})$ -- a topological invariant that almost fully characterizes the 2+1D topological orders.
Highlights
It was proposed that all force particles and matter particles may arise from entangled quantum information if we assume the space to be an ocean of qubits [1,2,3,4,5]
At the moment, we still do not know how the metrics of a manifold and an Einstein equation that governs the dynamics of metrics can emerge from discrete and entangled qubits if we require that the fluctuations of the metrics are the only low-energy excitations. (For the emergence of nonEinstein quantum gravity as the only low-energy dynamics, see Refs. [8,9,10].) In this paper, we will address a much simpler question: how the volume emerges from discrete and entangled qubits
Those finite subleading terms are topological invariants that characterize the underlying topological order. Extracting those topological invariants from the nonuniversal quantum volume of a manybody system in the N → ∞ limit is the main topic of this paper. This is very similar to entanglement entropy: the leading term of entanglement entropy can be used to define the total area of the interface, while the finite subleading term—the topological entanglement entropy—is a topological invariant that characterizes the underlying topological order [21,22]
Summary
It was proposed that all force particles (the gauge bosons) and matter particles (the fermions) may arise from entangled quantum information if we assume the space to be an ocean of qubits [1,2,3,4,5]. Those finite subleading terms are topological invariants that characterize the underlying topological order Extracting those topological invariants (i.e., the subleading terms) from the nonuniversal quantum volume of a manybody system in the N → ∞ limit is the main topic of this paper. This is very similar to entanglement entropy: the leading term of entanglement entropy can be used to define the total area of the interface, while the finite subleading term—the topological entanglement entropy—is a topological invariant that characterizes the underlying topological order [21,22]. This observation may have important implications: the theories for topological phases of matter based on TQFT topological invariants may need to be reevaluated
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