2023
DOI: 10.1088/1742-5468/acd2c5
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Complexity and quenches in models with three and four spin interactions

Abstract: We study information theoretic quantities in models with three and four spin interactions. These models show distinctive characteristics compared to their nearest neighbour (NN) counterparts. Here, we quantify these in terms of the Nielsen complexity (NC) in static and quench scenarios, the Fubini–Study complexity (FSC), and the entanglement entropy (EE). The models that we study have a rich phase structure, and we show how the difference in the nature of phase transitions in these, compared to ones with NN in… Show more

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Cited by 4 publications
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“…On the other hand, the time evolution of CC under a quantum quench and its comparison with entanglement measures of a system can reveal a great deal of information about the underlying dynamics, depending on the integrability property of the Hamiltonian. Works in these directions include CC evolution under smooth mass quench in free field theory [25], the scaling of complexity in different quench regions [26], and distinctions between different proposals for complexity following a quench [27] and multiple quenches [28,29]. The time evolution of CC involving a classically chaotic Hamiltonian can be used as an effective probe for the still elusive quantum signatures of chaos as demonstrated in [30,31].…”
Section: Introductionmentioning
confidence: 99%
“…On the other hand, the time evolution of CC under a quantum quench and its comparison with entanglement measures of a system can reveal a great deal of information about the underlying dynamics, depending on the integrability property of the Hamiltonian. Works in these directions include CC evolution under smooth mass quench in free field theory [25], the scaling of complexity in different quench regions [26], and distinctions between different proposals for complexity following a quench [27] and multiple quenches [28,29]. The time evolution of CC involving a classically chaotic Hamiltonian can be used as an effective probe for the still elusive quantum signatures of chaos as demonstrated in [30,31].…”
Section: Introductionmentioning
confidence: 99%