Your search keyword '"Carollo F"' showing total 7 results

1. Quantum spin chain dissipative mean-field dynamics

Author

Benatti, F, primary, Carollo, F, additional, Floreanini, R, additional, and Narnhofer, H, additional

Published

2018

2. Quantum fluctuations in mesoscopic systems

Author

Benatti, F, primary, Carollo, F, additional, Floreanini, R, additional, and Narnhofer, H, additional

Published

2017

3. Quantum spin chain dissipative mean-field dynamics

Author

Benatti, F., Carollo, F., Floreanini, R., Narnhofer, H., Benatti, F., Carollo, F., Floreanini, R., and Narnhofer, H.

Abstract

We study the emergent dynamics resulting from the infinite volume limit of the mean-field dissipative dynamics of quantum spin chains with clustering, but not time-invariant states. We focus upon three algebras of spin operators: the commutative algebra of mean-field operators, the quasi-local algebra of microscopic, local operators and the collective algebra of fluctuation operators. In the infinite volume limit, mean-field operators behave as time-dependent, commuting scalar macroscopic averages while quasi-local operators, despite the dissipative underlying dynamics, evolve unitarily in a typical non-Markovian fashion. Instead, the algebra of collective fluctuations, which is of bosonic type with time-dependent canonical commutation relations, undergoes a time-evolution that retains the dissipative character of the underlying microscopic dynamics and exhibits non-linear features. These latter disappear by extending the time-evolution to a larger algebra where it is represented by a continuous one-parameter semigroup of completely positive maps. The corresponding generator is not of Lindblad form and displays mixed quantum-classical features, thus indicating that peculiar hybrid systems may naturally emerge at the level of quantum fluctuations in many-body quantum systems endowed with non time-invariant states.

4. Quantum spin chain dissipative mean-field dynamics

Author

Benatti, F., Carollo, F., Floreanini, R., Narnhofer, H., Benatti, F., Carollo, F., Floreanini, R., and Narnhofer, H.

Abstract

We study the emergent dynamics resulting from the infinite volume limit of the mean-field dissipative dynamics of quantum spin chains with clustering, but not time-invariant states. We focus upon three algebras of spin operators: the commutative algebra of mean-field operators, the quasi-local algebra of microscopic, local operators and the collective algebra of fluctuation operators. In the infinite volume limit, mean-field operators behave as time-dependent, commuting scalar macroscopic averages while quasi-local operators, despite the dissipative underlying dynamics, evolve unitarily in a typical non-Markovian fashion. Instead, the algebra of collective fluctuations, which is of bosonic type with time-dependent canonical commutation relations, undergoes a time-evolution that retains the dissipative character of the underlying microscopic dynamics and exhibits non-linear features. These latter disappear by extending the time-evolution to a larger algebra where it is represented by a continuous one-parameter semigroup of completely positive maps. The corresponding generator is not of Lindblad form and displays mixed quantum-classical features, thus indicating that peculiar hybrid systems may naturally emerge at the level of quantum fluctuations in many-body quantum systems endowed with non time-invariant states.

5. Quantum spin chain dissipative mean-field dynamics

Author

Benatti, F., Carollo, F., Floreanini, R., Narnhofer, H., Benatti, F., Carollo, F., Floreanini, R., and Narnhofer, H.

Abstract

We study the emergent dynamics resulting from the infinite volume limit of the mean-field dissipative dynamics of quantum spin chains with clustering, but not time-invariant states. We focus upon three algebras of spin operators: the commutative algebra of mean-field operators, the quasi-local algebra of microscopic, local operators and the collective algebra of fluctuation operators. In the infinite volume limit, mean-field operators behave as time-dependent, commuting scalar macroscopic averages while quasi-local operators, despite the dissipative underlying dynamics, evolve unitarily in a typical non-Markovian fashion. Instead, the algebra of collective fluctuations, which is of bosonic type with time-dependent canonical commutation relations, undergoes a time-evolution that retains the dissipative character of the underlying microscopic dynamics and exhibits non-linear features. These latter disappear by extending the time-evolution to a larger algebra where it is represented by a continuous one-parameter semigroup of completely positive maps. The corresponding generator is not of Lindblad form and displays mixed quantum-classical features, thus indicating that peculiar hybrid systems may naturally emerge at the level of quantum fluctuations in many-body quantum systems endowed with non time-invariant states.

6. Quantum spin chain dissipative mean-field dynamics

Author

Benatti, F., Carollo, F., Floreanini, R., Narnhofer, H., Benatti, F., Carollo, F., Floreanini, R., and Narnhofer, H.

Abstract

We study the emergent dynamics resulting from the infinite volume limit of the mean-field dissipative dynamics of quantum spin chains with clustering, but not time-invariant states. We focus upon three algebras of spin operators: the commutative algebra of mean-field operators, the quasi-local algebra of microscopic, local operators and the collective algebra of fluctuation operators. In the infinite volume limit, mean-field operators behave as time-dependent, commuting scalar macroscopic averages while quasi-local operators, despite the dissipative underlying dynamics, evolve unitarily in a typical non-Markovian fashion. Instead, the algebra of collective fluctuations, which is of bosonic type with time-dependent canonical commutation relations, undergoes a time-evolution that retains the dissipative character of the underlying microscopic dynamics and exhibits non-linear features. These latter disappear by extending the time-evolution to a larger algebra where it is represented by a continuous one-parameter semigroup of completely positive maps. The corresponding generator is not of Lindblad form and displays mixed quantum-classical features, thus indicating that peculiar hybrid systems may naturally emerge at the level of quantum fluctuations in many-body quantum systems endowed with non time-invariant states.

7. Quantum spin chain dissipative mean-field dynamics

Author

Fabio Benatti, Federico Carollo, Roberto Floreanini, Heide Narnhofer, Benatti, F., Carollo, F., Floreanini, R., and Narnhofer, H.

Subjects

Statistics and Probability, quantum fluctuation, Scalar (mathematics), FOS: Physical sciences, General Physics and Astronomy, Type (model theory), 01 natural sciences, 010305 fluids & plasmas, many-body systems, open quantum systems, quantum central limit theorem, quantum fluctuations, 0103 physical sciences, Commutative algebra, 010306 general physics, Spin (physics), Quantum, Mathematical Physics, Quantum fluctuation, Mathematical physics, Physics, open quantum system, Quantum Physics, Semigroup, Statistical and Nonlinear Physics, Mathematical Physics (math-ph), Condensed Matter - Other Condensed Matter, many-body system, Modeling and Simulation, Dissipative system, Quantum Physics (quant-ph), Other Condensed Matter (cond-mat.other)

Abstract

We study the emergent dynamics resulting from the infinite volume limit of the mean-field dissipative dynamics of quantum spin chains with clustering, but not time-invariant states. We focus upon three algebras of spin operators: the commutative algebra of mean-field operators, the quasi-local algebra of microscopic, local operators and the collective algebra of fluctuation operators. In the infinite volume limit, mean-field operators behave as time-dependent, commuting scalar macroscopic averages while quasi-local operators, despite the dissipative underlying dynamics, evolve unitarily in a typical non-Markovian fashion. Instead, the algebra of collective fluctuations, which is of bosonic type with time-dependent canonical commutation relations, undergoes a time-evolution that retains the dissipative character of the underlying microscopic dynamics and exhibits non-linear features. These latter disappear by extending the time-evolution to a larger algebra where it is represented by a continuous one-parameter semigroup of completely positive maps. The corresponding generator is not of Lindblad form and displays mixed quantum-classical features, thus indicating that peculiar hybrid systems may naturally emerge at the level of quantum fluctuations in many-body quantum systems endowed with non time-invariant states., 65 pages

Published

2018