Abstract
We explore in detail the properties of two melonic quantum mechanical theories which can be formulated either as fermionic matrix quantum mechanics in the new large $D$ limit, or as disordered models. Both models have a mass parameter $m$ and the transition from the perturbative large $m$ region to the strongly coupled "black-hole" small $m$ region is associated with several interesting phenomena. One model, with ${\rm U}(n)^2$ symmetry and equivalent to complex SYK, has a line of first-order phase transitions terminating, for a strictly positive temperature, at a critical point having non-trivial, non-mean-field critical exponents for standard thermodynamical quantities. Quasi-normal frequencies, as well as Lyapunov exponents associated with out-of-time-ordered four-point functions, are also singular at the critical point, leading to interesting new critical exponents. The other model, with reduced ${\rm U}(n)$ symmetry, has a quantum critical point at strictly zero temperature and positive critical mass $m_*$. For $0<m<m_*$, it flows to a new gapless IR fixed point, for which the standard scale invariance is spontaneously broken by the appearance of distinct scaling dimensions $\Delta_+$ and $\Delta_-$ for the Euclidean two-point function when $t\rightarrow +\infty$ and $t\rightarrow -\infty$ respectively. We provide several detailed and pedagogical derivations, including rigorous proofs or simplified arguments for some results that were already known in the literature.
Highlights
AND DISCUSSIONMelonic theories are models for which the perturbative expansion is dominated, in some well-defined limit, by a special class of Feynman graphs called melonic
We explore in detail properties of two melonic quantum mechanical theories which can be formulated either as fermionic matrix quantum mechanics in the new large D limit, or as disordered models
After recalling and extending the main results already obtained in [29], we study the q-generalizations of the model
Summary
Melonic theories are models for which the perturbative expansion is dominated, in some well-defined limit, by a special class of Feynman graphs called melonic. They were discovered for tensor models in the context of the discretized approach to quantum gravity [1] and appeared implicitly in the study of disordered condensed matter systems [2] They dominate a suitably defined large d limit of planar graphs [3,4,5] and provide an interesting nonperturbative approximation to the large n limit of matrix models. We find that the chaos bound of [34] is saturated in the zero-temperature limit for all values of the mass in the black-hole, SYK-like phase This is true for both the particular four-point function studied in [34], and for the physical OTOC, for. This singular behavior leads to a new set of critical exponents, tied to the real time physics of dissipation and chaos and characterizing the critical point
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