Abstract
We introduce a statistical system on random networks of trivalent vertices for the purpose of studying the canonical tensor model, which is a rank-three tensor model in the canonical formalism. The partition function of the statistical system has a concise expression in terms of integrals, and has the same symmetries as the kinematical ones of the canonical tensor model. We consider the simplest non-trivial case of the statistical system corresponding to the Ising model on random networks, and find that its phase diagram agrees with what is implied by regrading the Hamiltonian vector field of the canonical tensor model with N = 2 as a renormalization group flow. Along the way, we obtain an explicit exact expression of the free energy of the Ising model on random networks in the thermodynamic limit by the Laplace method. This paper provides a new example connecting a model of quantum gravity and a random statistical system.
Highlights
The difficulty of combining quantum mechanics and general relativity indicates our serious lack of a consistent description of nature
We especially consider the case of the Ising model on random networks, and have found that the phase structure is in remarkable agreement with the prediction of the canonical tensor model with N = 2, if the Hamiltonian vector field of the canonical tensor model is regarded as the renormalization group flow of the Ising model
We have shown the close relationship between the canonical tensor model and a statistical system on random networks of trivalent vertices
Summary
The difficulty of combining quantum mechanics and general relativity indicates our serious lack of a consistent description of nature. We especially consider the case of the Ising model on random networks, and have found that the phase structure is in remarkable agreement with the prediction of the canonical tensor model with N = 2, if the Hamiltonian vector field of the canonical tensor model is regarded as the renormalization group flow of the Ising model. We see that the phase diagram agrees with the prediction made by regarding the Hamiltonian vector field of the canonical tensor model with N = 2 as the renormalization group flow of the Ising model. The final section is devoted to a summary and consideration of future prospects
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