About: The concept of out-of-time-ordered correlation (OTOC) function is treated as a very strong theoretical probe of quantum randomness, using which one can study both chaotic and non-chaotic phenomena in the context of quantum statistical mechanics. In this paper, we define a general class of OTOC, which can perfectly capture quantum randomness phenomena in a better way. Further we demonstrate an equivalent formalism of computation using a general time independent Hamiltonian having well defined eigenstate representation for integrable supersymmetric quantum systems. We found that one needs to consider two new correlators apart from the usual one to have a complete quantum description. To visualize the impact of the given formalism we consider the two well known models viz. Harmonic Oscillator and one dimensional potential well within the framework of supersymmetry. For the Harmonic Oscillator case we obtain similar periodic time dependence but dissimilar parameter dependences compared to the results obtained from both micro-canonical and canonical ensembles in quantum mechanics without supersymmetry. On the other hand, for one dimensional potential well problem we found significantly different time scale and the other parameter dependence compared to the results obtained from non-supersymmetric quantum mechanics. Finally, to establish the consistency of the prescribed formalism in the classical limit, we demonstrate the phase space averaged version of the classical version of OTOCs from a model independent Hamiltonian along with the previously mentioned these well cited models.

Facets (new session)
Description
Metadata
Settings
- owl:sameAs
- Inference Rule:

About: The concept of out-of-time-ordered correlation (OTOC) function is treated as a very strong theoretical probe of quantum randomness, using which one can study both chaotic and non-chaotic phenomena in the context of quantum statistical mechanics. In this paper, we define a general class of OTOC, which can perfectly capture quantum randomness phenomena in a better way. Further we demonstrate an equivalent formalism of computation using a general time independent Hamiltonian having well defined eigenstate representation for integrable supersymmetric quantum systems. We found that one needs to consider two new correlators apart from the usual one to have a complete quantum description. To visualize the impact of the given formalism we consider the two well known models viz. Harmonic Oscillator and one dimensional potential well within the framework of supersymmetry. For the Harmonic Oscillator case we obtain similar periodic time dependence but dissimilar parameter dependences compared to the results obtained from both micro-canonical and canonical ensembles in quantum mechanics without supersymmetry. On the other hand, for one dimensional potential well problem we found significantly different time scale and the other parameter dependence compared to the results obtained from non-supersymmetric quantum mechanics. Finally, to establish the consistency of the prescribed formalism in the classical limit, we demonstrate the phase space averaged version of the classical version of OTOCs from a model independent Hamiltonian along with the previously mentioned these well cited models. Goto Sponge NotDistinct Permalink

An Entity of Type : fabio:Abstract, within Data Space : covidontheweb.inria.fr associated with source document(s)

Attributes	Values
type	abstract
value	The concept of out-of-time-ordered correlation (OTOC) function is treated as a very strong theoretical probe of quantum randomness, using which one can study both chaotic and non-chaotic phenomena in the context of quantum statistical mechanics. In this paper, we define a general class of OTOC, which can perfectly capture quantum randomness phenomena in a better way. Further we demonstrate an equivalent formalism of computation using a general time independent Hamiltonian having well defined eigenstate representation for integrable supersymmetric quantum systems. We found that one needs to consider two new correlators apart from the usual one to have a complete quantum description. To visualize the impact of the given formalism we consider the two well known models viz. Harmonic Oscillator and one dimensional potential well within the framework of supersymmetry. For the Harmonic Oscillator case we obtain similar periodic time dependence but dissimilar parameter dependences compared to the results obtained from both micro-canonical and canonical ensembles in quantum mechanics without supersymmetry. On the other hand, for one dimensional potential well problem we found significantly different time scale and the other parameter dependence compared to the results obtained from non-supersymmetric quantum mechanics. Finally, to establish the consistency of the prescribed formalism in the classical limit, we demonstrate the phase space averaged version of the classical version of OTOCs from a model independent Hamiltonian along with the previously mentioned these well cited models.
Subject	Thermodynamics Concepts in physics Conservation laws Quantum mechanics
part of	The Generalized OTOC from Supersymmetric Quantum Mechanics: Study of Random Fluctuations from Eigenstate Representation of Correlation Functions
is abstract of	The Generalized OTOC from Supersymmetric Quantum Mechanics: Study of Random Fluctuations from Eigenstate Representation of Correlation Functions
is hasSource of	covid:ann/target/7b9ce13bc129050bbd04a0f11e4e53507e342d4e covid:ann/target/8aa86e73736a8dbd702c727b8a13fbd9d5a54af1 covid:ann/target/71b840b8ee02b45673c7d8ea5ccb70f8c63897d2 covid:ann/target/c3cf0d0aaec53e5c23f0467b694e103ef5027317 covid:ann/target/10a4084e00472833775e49c14902721f90f1e6e5 covid:ann/target/bef1fa12d6af37546c7eebc9ac287515a31b34e3 covid:ann/target/35d93367e6ab0480ea2bdb027e4e8761117a3969 covid:ann/target/cb6bbbc63e860fa19d8781e143b53efc176706ad covid:ann/target/5f8363abc632759c25a965b7e44759de04c045ec covid:ann/target/f2371ed6dabe026f504b0c75f0b18824e397c7f0 covid:ann/target/7c021af6cba4ce753403f38077d40e8c09c7589b covid:ann/target/ca0d14736fd44be1db874ff4a25257e904b13f44 covid:ann/target/ffbf8cc1b7a07b7cfad3d155b3727ac5d09d93d9 covid:ann/target/6cae04db0ea201c92cc2e9acdcadb92e087cceeb covid:ann/target/d01dac483af74e063ca842feec0c9c12556b4127 covid:ann/target/0df3b7ca3162e16a8c9e6bddffa4974752d220bf covid:ann/target/3245880e90fc9eb856f6d536a5a1a74cbeb6928e covid:ann/target/2da2bb2eb3a0cdd011e589c1c084dce7f50c14dc covid:ann/target/d7bbedaaf16bc80919aded86fa9cda105a27d2cb covid:ann/target/b3436e0e8267c41669cf2c8a148074a78ae55697 covid:ann/target/b46c143d143e0b13dbba56e10a02abae91a8ca1a covid:ann/target/c6738d7a777c703e373461cff5c35977e28d2087 covid:ann/target/034088047f6f0f4613a95ac2360f909cc0f77ae6 covid:ann/target/63cbfe6b05af4b10380aff98929c9f5b0807a1e9 covid:ann/target/20a58e4ad05b31c3f67117c628f1e16d399ed091

Faceted Search & Find service v1.13.91 as of Mar 24 2020

Alternative Linked Data Documents: Sponger | ODE Content Formats:

RDF

ODATA

Microdata

About

OpenLink Virtuoso version 07.20.3229 as of Jul 10 2020, on Linux (x86_64-pc-linux-gnu), Single-Server Edition (94 GB total memory)
Data on this page belongs to its respective rights holders.
Virtuoso Faceted Browser Copyright © 2009-2024 OpenLink Software