Field theory of monitored, interacting fermion dynamics with charge conservation
- URL: http://arxiv.org/abs/2410.07317v1
- Date: Wed, 9 Oct 2024 18:00:01 GMT
- Title: Field theory of monitored, interacting fermion dynamics with charge conservation
- Authors: Haoyu Guo, Matthew S. Foster, Chao-Ming Jian, Andreas W. W. Ludwig,
- Abstract summary: We focus on the charge-conserving monitored dynamics of interacting fermions in 1D.
Using a unifying replica Keldysh field theory, we show that more dynamical phases and transitions emerge.
- Score: 0.5356944479760104
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Charge-conserving dynamics of non-interacting fermions monitored by local charge measurements have been shown to possess in 1D space only an area-law-entangled phase, with no measurement-induced phase transition (MIPT). This phenomenon was elegantly explained by an effective replica field theory given by a non-linear sigma model featuring large replica symmetries. In this work, we focus on the charge-conserving monitored dynamics of interacting fermions in 1D. Using a unifying replica Keldysh field theory, we show that more dynamical phases and transitions emerge owing to the reduction of replica symmetry when interactions are introduced. The reduced symmetry combines a discrete replica permutation symmetry and the charge-conservation within each replica. The former and its spontaneous breaking govern the MIPT between area-law and volume-law entanglement scalings, which can be described by a separatrix in the weak-coupling renormalization group flow. The replica-resolved charge conservation dictates the Kosterlitz-Thouless type ``charge-sharpening" transition between the two kinds of dynamics where the global charge information is either hidden or reconstructible from the local measurements. All the relevant phases and transitions can be understood within the same unifying field theory. Additionally, this field theory provides insight into why the charge-sharpening transition should only happen in the presence of volume-law entanglement scaling. Moreover, we show that our field theory, despite being constructed using the Keldysh formalism, is equivalent to a statistical mechanics model that describes the (replicated) time-evolution of the system's density matrix mapped to a doubled Hilbert space under the Choi-Jamiolkowski isomorphism. This equivalence is the result of the trivialization of the fermion distribution function by measurement-induced heating effects.
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