Your search keyword '"Open quantum system"' showing total 14,808 results

1. How to Partition a Quantum Observable.

Author

Webb, Caleb Merrick and Stafford, Charles Allen

Subjects

*THERMODYNAMIC laws, *SECOND law of thermodynamics, *CONFIGURATION space, *HILBERT space, *ENTROPY, *QUANTUM entropy

Abstract

We present a partition of quantum observables in an open quantum system that is inherited from the division of the underlying Hilbert space or configuration space. It is shown that this partition leads to the definition of an inhomogeneous continuity equation for generic, non-local observables. This formalism is employed to describe the local evolution of the von Neumann entropy of a system of independent quantum particles out of equilibrium. Crucially, we find that all local fluctuations in the entropy are governed by an entropy current operator, implying that the production of entanglement entropy is not measured by this partitioned entropy. For systems linearly perturbed from equilibrium, it is shown that this entropy current is equivalent to a heat current, provided that the system-reservoir coupling is partitioned symmetrically. Finally, we show that any other partition of the coupling leads directly to a divergence of the von Neumann entropy. Thus, we conclude that Hilbert-space partitioning is the only partition of the von Neumann entropy that is consistent with the laws of thermodynamics. [ABSTRACT FROM AUTHOR]

Published

2024

2. Quasi-equilibrium and quantum correlation in an open spin-pair system.

Author

Taboada, J. Agustín, Segnorile, Héctor H., González, Cecilia E., and Zamar, Ricardo C.

Subjects

*QUANTUM correlations, *QUASI-equilibrium, *QUANTUM theory, *THERMAL equilibrium, *SPIN-lattice relaxation, *NUCLEAR magnetic resonance spectroscopy

Abstract

Quasi-equilibrium states that can be prepared in solids through Nuclear Magnetic Resonance (NMR) techniques are out-of-equilibrium states that slowly relax towards thermodynamic equilibrium with the lattice. In this work, we use the quantum discord dynamics as a witness of the quantum correlation in this kind of state. The studied system is a set of dipole interacting spin pairs whose initial state is prepared with the NMR Jeener–Broekaert pulse sequence, starting from equilibrium at high temperature and high external magnetic field. It then evolves as an open quantum system within two consecutive dynamic scenarios: adiabatic decoherence driven by the coupling of the pairs to a common phonon field, described within a non-Markovian approach, and spin–lattice relaxation represented by the high-temperature limit of the Born–Markov master equation, and driven by thermal fluctuations. In this way, the studied model is endowed with the dynamics of a realistic solid sample. The quantum discord rapidly increases during the preparation of the initial state, escalating several orders of magnitude compared with thermal equilibrium at room temperature. During decoherence—despite the decay of coherences—the quantum discord oscillates upon this high value, holding the same value as the initial state. Finally, the quantum discord dissipates within a time scale shorter than but comparable to spin–lattice relaxation. [ABSTRACT FROM AUTHOR]

Published

2024

3. Superoperator Master Equations for Depolarizing Dynamics.

Author

Teretenkov, A. E.

Abstract

The work is devoted to superoperator master equations. Namely, the superoperator master equations in the case of the twirling hyperprojector with respect to the whole unitary group are derived. To be consistent with such a hyperprojector the free dynamics is assumed to be depolarizing. And it is perturbed by the arbitrary Gorini–Kossakowski–Sudarshan–Lindblad generator. The explicit form of the second order master equations are presented in this case. [ABSTRACT FROM AUTHOR]

Published

2024

4. General properties of the spectral form factor in open quantum systems.

Author

Zhou, Yi-Neng, Zhou, Tian-Gang, and Zhang, Pengfei

Abstract

The spectral form factor (SFF) can probe the eigenvalue statistic at different energy scales as its time variable varies. In closed quantum chaotic systems, the SFF exhibits a universal dip-ramp-plateau behavior, which reflects the spectrum rigidity of the Hamiltonian. In this work, we explore the general properties of SFF in open quantum systems. We find that in open systems the SFF first decays exponentially, followed by a linear increase at some intermediate time scale, and finally decreases to a saturated plateau value. We derive general relations between (i) the early-time decay exponent and Lindblad operators; (ii) the long-time plateau value and the number of steady states. We also explain the effective field theory perspective of general behaviors. We verify our theoretical predictions by numerically simulating the Sachdev–Ye–Kitaev (SYK) model, random matrix theory (RMT), and the Bose–Hubbard model. [ABSTRACT FROM AUTHOR]

Published

2024

5. Passive error correction with a qubit-oscillator system in noisy environment

Author

Zhu, Yanzhang and Hwang, Myung-Joong

Published

2024

6. On the coupling of three-level quantum refrigerators in the weak coupling limit.

Author

Abdou Chakour, M H Ben, El Allati, A, and Hassouni, Y

Subjects

*QUANTUM correlations, *REFRIGERATORS, *QUBITS

Abstract

We propose a model of two identical autonomous quantum refrigerators that interact through their qubits coupled to cold thermal baths. We consider the same specific disposition for each refrigerator related to a three-level system coupled to different thermal baths and, in turn, to a qubit as the object to be cooled. By coupling the two systems, we show that under certain conditions on the model parameters, the devices can operate in the regime of an independent autonomous quantum refrigerator or be subject to an adjustment of the thermodynamic performances. We further investigate the correlations induced by the interaction between the two refrigerators, and illustrate their behavior with respect to their thermodynamic performances. We have found that adjusting the different interaction constants of the model can lead to an evolution of the quantum correlations of the two machines that is inversely related to the behavior of the thermodynamic quantities of both refrigerators. However, this is not necessarily the case when the temperatures of the model are considered as the reference parameters. [ABSTRACT FROM AUTHOR]

Published

2024

7. Coherence dynamics of spin systems in critical environment with topological characterization.

Author

Luan, Hongliang, Zhang, Qiang, Wen, Jing, and Yin, Shaoying

Subjects

*COHERENCE (Nuclear physics), *QUANTUM phase transitions, *SYSTEM dynamics, *LOGARITHMIC functions, *QUANTUM coherence

Abstract

The coherence dynamics of the central systems are investigated in the spin-chain environment with topological characterization. For the single- and two-spin coherence, their critical behaviors can detect the topological quantum phase transitions (TQPTs) in weaker coupling regions. Their noncritical behaviors show periodic oscillations or keep constant. For the quantum coherence of a symmetric W state, the bipartite coherence is dominant due to its polygamy. The critical behaviors of global coherence ( QC a : bc and QC b : c ) and multipartite monogamy can also detect the TQPTs. In the strong coupling regions ( g a (b , c) ≫ 1 ), the coherence dynamics of single-spin, two-spin, and bipartite block of three-spin system can be characterized by Gaussian envelope, but the envelope line of three-spin coherence can be only described by negative logarithmic function. Finally, the resistance to the topological spin-chain environment becomes stronger from the single- to three-spin coherence. [ABSTRACT FROM AUTHOR]

Published

2024

8. Using and Optimizing Time-Dependent Decoherence Rates and Coherent Control for a Qutrit System.

Author

Morzhin, Oleg V. and Pechen, Alexander N.

Abstract

We consider an open qutrit system in which the evolution of the density matrix is governed by the Gorini–Kossakowski–Sudarshan–Lindblad master equation with simultaneous coherent (in the Hamiltonian) and incoherent (in the dissipation superoperator) controls. To control the qutrit, we propose to use not only coherent control but also generally time-dependent decoherence rates which are adjusted by the so-called incoherent control. In our approach, the incoherent control makes the decoherence rates time-dependent in a specific controlled manner and within a clear physical mechanism. We consider the problem of maximizing the Hilbert–Schmidt overlap between the final state of the system and a given target state , as well as the problem of minimizing the squared Hilbert–Schmidt distance between these states. For both problems, we perform their realifications, derive the corresponding Pontryagin functions, adjoint systems (with two variants of transversality conditions for the two terminal objectives), and gradients of the objectives, and adapt the one-, two-, and three-step gradient projection methods. For the problem of maximizing the overlap, we also adapt the regularized first-order Krotov method. In the numerical experiments, we analyze first the operation of the methods and second the obtained control processes, in respect of considering the environment as a resource via incoherent control. [ABSTRACT FROM AUTHOR]

Published

2024

9. On Time-Dependent Projectors and a Generalization of the Thermodynamical Approach in the Theory of Open Quantum Systems.

Author

Meretukov, Kh. Sh. and Teretenkov, A. E.

Abstract

We develop a consistent perturbative technique for obtaining a time-local linear master equation based on projection methods in the case where the projection operator depends on time. Then we introduce a generalization of the Kawasaki–Gunton projection operator, which allows us to use this technique to derive, generally speaking, nonlinear master equations in the case of arbitrary ansatzes consistent with some set of observables. Most of the results obtained are of a very general nature, but when discussing them, we put emphasis on the application of these results to the theory of open quantum systems. [ABSTRACT FROM AUTHOR]

Published

2024

10. Generation of C-NOT, SWAP, and C-Z Gates for Two Qubits Using Coherent and Incoherent Controls and Stochastic Optimization.

Author

Morzhin, O. V. and Pechen, A. N.

Abstract

In this work, we consider a general form of the dynamics of open quantum systems determined by the Gorini–Kossakowsky–Sudarchhan–Lindblad type master equation with simultaneous coherent and incoherent controls with three particular forms of the two-qubit Hamiltonians. Coherent control enters in the Hamiltonian and incoherent control enters in both the Hamiltonian and the superoperator of dissipation. For these systems, we analyze the control problems of generating two-qubit C-NOT, SWAP, and C-Z gates using with piecewise constant controls and stochastic optimization in the form of an adapted version of the dual annealing algorithm. In the numerical experiment, we analyze the minimal infidelity obtained by the dual annealing for various values of strength of the interaction between the system and the environment. [ABSTRACT FROM AUTHOR]

Published

2024

11. Control of the von Neumann Entropy for an Open Two-Qubit System Using Coherent and Incoherent Drives †.

Author

Morzhin, Oleg V. and Pechen, Alexander N.

Subjects

*QUANTUM entropy, *QUBITS, *ENTROPY, *QUANTUM thermodynamics, *GENETIC algorithms

Abstract

This article is devoted to developing an approach for manipulating the von Neumann entropy S (ρ (t)) of an open two-qubit system with coherent control and incoherent control inducing time-dependent decoherence rates. The following goals are considered: (a) minimizing or maximizing the final entropy S (ρ (T)) ; (b) steering S (ρ (T)) to a given target value; (c) steering S (ρ (T)) to a target value and satisfying the pointwise state constraint S (ρ (t)) ≤ S ¯ for a given S ¯ ; (d) keeping S (ρ (t)) constant at a given time interval. Under the Markovian dynamics determined by a Gorini–Kossakowski–Sudarshan–Lindblad type master equation, which contains coherent and incoherent controls, one- and two-step gradient projection methods and genetic algorithm have been adapted, taking into account the specifics of the objective functionals. The corresponding numerical results are provided and discussed. [ABSTRACT FROM AUTHOR]

Published

2024

12. Postponing the decay of entanglement and quantum coherence for maximally entangled mixed states under the action of correlated noise channels.

Author

Awasthi, Natasha, Singh, Ashutosh, and Joshi, Dheeraj Kumar

Subjects

QUANTUM entanglement, QUANTUM coherence, QUANTUM states, QUANTUM information science, SUDDEN death, NOISE

Abstract

We investigate the dynamics of a maximally entangled mixed state (MEMS) under the action of correlated noise channels. The channel acts in a way that its successive uses are correlated. We have studied the MEMS properties, including quantum coherence and entanglement. For partially correlated channels, both the entanglement and coherence of MEMS are found to decay much slower than those of the memoryless channels. Moreover, we observe a freezing effect of coherence for phase damping as well as depolarizing channels and freezing of entanglement for phase-damping channels with perfect memory. For amplitude damping and depolarizing channels, memory helps in either delaying the sudden death of entanglement or slowing the decay rate of coherence. These observations suggest that memory channels perform better than memoryless channels in maintaining the integrity of quantum states and have utility in quantum information processing protocols. [ABSTRACT FROM AUTHOR]

Published

2023

13. Incoherent GRAPE for Optimization of Quantum Systems with Environmentally Assisted Control.

Author

Petruhanov, V. and Pechen, A.

Subjects

*GRAPES, *QUANTUM gates, *MATHEMATICAL optimization, *DENSITY matrices, *CUBIC equations, *QUBITS

Abstract

In this work, we review several results on development and application of incoherent version of GRAPE (Gradient Ascent Pulse Engineering) approach to optimization for open quantum systems driven by both coherent and incoherent controls. In the incoherent control approach, the environment serves as a control together with coherent field, and decoherence rates become generally time-dependent. For a qubit, explicit analytic expressions for evolution of the density matrix were obtained by solving a cubic equation via Cardano method. We discuss applications of incoherent GRAPE method (inGRAPE) to high fidelity gate generation for open one- and two-qubit systems and surprising properties of the underlying control landscapes, forming two groups — smooth single peak landscapes for Hadamard, C-NOT and C-Z gates, and more complicated with two peaks for T (or π/8) gate. For a qutrit, a formulation of the environment-assisted incoherent control with time-dependent decoherence rates is provided. [ABSTRACT FROM AUTHOR]

Published

2023

14. Quantum Control by the Environment: Turing Uncomputability, Optimization over Stiefel Manifolds, Reachable Sets, and Incoherent GRAPE.

Author

Pechen, A. N.

Subjects

*GRAPES, *QUANTUM computing, *QUANTUM gates, *CHEMICAL reactions, *SET-valued maps

Abstract

The ability to control quantum systems is necessary for many applications of quantum technologies ranging from gate generation in quantum computation to NMR and laser control of chemical reactions. In many practical situations, the controlled quantum systems are open, i.e., interacting with the environment. While often influence of the environment is considered as an obstacle for controlling the systems, in some cases it can be exploited as a useful resource. In this note, we briefly review some results on control of open quantum systems using environment as a resource, including Turing uncomputability of discrete quantum control, parametrization of Kraus maps by points of the Stiefel manifolds and corresponding Riemanninan optimization, control by dissipation and time-dependent decoherence rates, reachable sets, and incoherent GRAPE (Gradient Ascent Pulse Engineering) for gradient-based optimization. [ABSTRACT FROM AUTHOR]

Published

2023

15. Dissipative learning of a quantum classifier.

Author

Korkmaz, Ufuk and Türkpençe, Denz

Subjects

*MACHINE learning, *ARTIFICIAL neural networks, *QUANTUM computing, *QUANTUM theory, *DIFFERENTIABLE functions

Abstract

The expectation that quantum computation might bring performance advantages in machine learning algorithms motivates the work on the quantum versions of artificial neural networks. In this study, we analyse the learning dynamics of a quantum classifier model that works as an open quantum system which is an alternative to the standard quantum circuit model. According to the obtained results, the model can be successfully trained with a gradient descent (GD)-based algorithm. The fact that these optimisation processes have been obtained with continuous dynamics, shows promise for the development of a differentiable activation function for the classifier model. [ABSTRACT FROM AUTHOR]

Published

2023

16. Quantum simulation of a general anti-PT-symmetric Hamiltonian with a trapped ion qubit

Author

Ji Bian, Pengfei Lu, Teng Liu, Hao Wu, Xinxin Rao, Kunxu Wang, Qifeng Lao, Yang Liu, Feng Zhu, and Le Luo

Subjects

Open quantum system, Non-Hermitian quantum mechanics, Parity-time symmetry, Anti-parity-time symmetry, Quantum simulation, Science (General), Q1-390

Abstract

Non-Hermitian systems satisfying parity-time (PT) symmetry have aroused considerable interest owing to their exotic features. Anti-PT symmetry is an important counterpart of the PT symmetry, and has been studied in various classical systems. Although a Hamiltonian with anti-PT symmetry only differs from its PT-symmetric counterpart in a global ±i phase, the information and energy exchange between systems and environment are different under them. It is also suggested theoretically that anti-PT symmetry is a useful concept in the context of quantum information storage with qubits coupled to a bosonic bath. So far, the observation of anti-PT symmetry in individual quantum systems remains elusive. Here, we implement an anti-PT-symmetric Hamiltonian of a single qubit in a single trapped ion by a designed microwave and optical control-pulse sequence. We characterize the anti-PTphase transition by mapping out the eigenvalues at different ratios between coupling strengths and dissipation rates. The full information of the quantum state is also obtained by quantum state tomography. Our work allows quantum simulation of genuine open-system feature of an anti-PT-symmetric system, which paves the way for utilizing non-Hermitian properties for quantum information processing.

Published

2023

17. Krotov Type Optimization of Coherent and Incoherent Controls for Open Two-Qubit Systems

Author

O. V. Morzhin and A. N. Pechen

Subjects

open quantum system, incoherent quantum control, nonlocal improvement, optimization, Mathematics, QA1-939

Abstract

This work considers two-qubit open quantum systems driven by coherent and incoherent controls. Incoherent control induces time-dependent decoherence rates via time-dependent spectral density of the environment which is used as a resource for controlling the system. The system evolves according to the Gorini–Kossakowski– Sudarshan–Lindblad master equation with time-dependent coefficients. For two types of interaction with coherent control, three types of objectives are considered: 1) maximizing the Hilbert–Schmidt overlap between the final and target density matrices; 2) minimizing the Hilbert–Schmidt distance between these matrices; 3) steering the overlap to a given value. For the first problem, we develop the Krotov type methods directly in terms of density matrices with or without regularization for piecewise continuous controls with constaints and find the cases where the methods produce (either exactly or with some precision) zero controls which satisfy the Pontryagin maximum principle and produce the overlap’s values close to their upper bounds. For the problems 2) and 3), we find cases when the dual annealing method steers the objectives close to zero and produces a non-zero control.

Published

2023

18. How to Partition a Quantum Observable

Author

Caleb Merrick Webb and Charles Allen Stafford

Subjects

open quantum system, entropy, partitioning, thermodynamics, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

We present a partition of quantum observables in an open quantum system that is inherited from the division of the underlying Hilbert space or configuration space. It is shown that this partition leads to the definition of an inhomogeneous continuity equation for generic, non-local observables. This formalism is employed to describe the local evolution of the von Neumann entropy of a system of independent quantum particles out of equilibrium. Crucially, we find that all local fluctuations in the entropy are governed by an entropy current operator, implying that the production of entanglement entropy is not measured by this partitioned entropy. For systems linearly perturbed from equilibrium, it is shown that this entropy current is equivalent to a heat current, provided that the system-reservoir coupling is partitioned symmetrically. Finally, we show that any other partition of the coupling leads directly to a divergence of the von Neumann entropy. Thus, we conclude that Hilbert-space partitioning is the only partition of the von Neumann entropy that is consistent with the laws of thermodynamics.

Published

2024

19. Relaxation dynamics of an unlike spin pair system.

Author

Consuelo-Leal, A., Sare, Hugo D. Fernández, and Auccaise, R.

Subjects

*DENSITY matrices, *QUANTUM states, *NUCLEAR magnetic resonance, *MAGNETIZATION

Abstract

Redfield master equation was applied to study the dynamics of an ensemble of interacting pairs of unlike spins at room temperature. This spin quantum system is a workbench quantum model to analyze the relaxation dynamics of a heteronuclear two-level spin system interacting by a pure dipole–dipole coupling. Expressions for the density matrix elements and their relaxation rate constants of each coherence order were computed. In addition, the solutions were evaluated considering three initial quantum states, and the theoretical predictions, such as multiexponential evolutions and enhancement, are behaviors that the solutions preserve and agree with previous studies performed for magnetization time evolutions. Moreover, the solutions computed to predict the dynamics of the longitudinal magnetization avoid the disagreement reported by I. Solomon. [ABSTRACT FROM AUTHOR]

Published

2023

20. Quantum Control Landscapes for Generation of H and T Gates in an Open Qubit with Both Coherent and Environmental Drive.

Author

Petruhanov, Vadim N. and Pechen, Alexander N.

Subjects

QUBITS, QUANTUM computing, QUANTUM gates, HILBERT space, SUBMANIFOLDS, LANDSCAPES

Abstract

An important problem in quantum computation is the generation of single-qubit quantum gates such as Hadamard (H) and π / 8 (T) gates, which are components of a universal set of gates. Qubits in experimental realizations of quantum computing devices are interacting with their environment. While the environment is often considered as an obstacle leading to a decrease in the gate fidelity, in some cases, it can be used as a resource. Here, we consider the problem of the optimal generation of H and T gates using coherent control and the environment as a resource acting on the qubit via incoherent control. For this problem, we studied the quantum control landscape, which represents the behavior of the infidelity as a functional of the controls. We considered three landscapes, with infidelities defined by steering between two, three (via Goerz–Reich–Koch approach), and four matrices in the qubit Hilbert space. We observed that, for the H gate, which is a Clifford gate, for all three infidelities, the distributions of minimal values obtained with a gradient search have a simple form with just one peak. However, for the T gate, which is a non-Clifford gate, the situation is surprisingly different—this distribution for the infidelity defined by two matrices also has one peak, whereas distributions for the infidelities defined by three and four matrices have two peaks, which might indicate the possible existence of two isolated minima in the control landscape. It is important that, among these three infidelities, only those defined with three and four matrices guarantee the closeness of the generated gate to a target and can be used as a good measure of closeness. We studied sets of optimized solutions for the most general and previously unexplored case of coherent and incoherent controls acting together and discovered that they form sub-manifolds in the control space, and unexpectedly, in some cases, two isolated sub-manifolds. [ABSTRACT FROM AUTHOR]

Published

2023

21. Preparing maximally entangled states by monitoring the environment-system interaction.

Author

Abu-Nada, Ali A. and Salhab, Moataz A.

Subjects

*QUANTUM information science, *CIRCUIT complexity, *AUTOMATIC control systems, *ION traps, *QUANTUM gates, *OPTICAL pumping, *INFORMATION resources

Abstract

A common assumption in an open quantum system is that the noise induced by the environment, due to the interaction between a quantum system and its environment, is responsible for the disappearance of quantum properties. Interestingly, Barreiro et al. [Nature470 (2011) 486] show, experimentally, using an open-system quantum ion traps simulator, an environment state can be engineered and controlled to pump an arbitrary quantum system toward a maximally entangled state and thus can be considered a resource for quantum information processing. Here, we demonstrate this idea to pump an arbitrary maximally mixed state into Greenberger–Horne–Zeilinger (GHZ) state by simulating our quantum circuit using one of the IBM Q processors. Barreiro et al. [Nature470 (2011) 486] offer the circuits for the execution of the GHZ pumping. Nevertheless, those are collected gates that are suitable to the trapped-ions platform, so their circuits implementation on the IBM Q devices would result in large depth circuits and thus requires many gates. Consequently, we suggest a different circuit structure that follows a similar goal, but has been considered the features of the IBM Q platform. Moreover, we run the simulation of our circuit using the QASM simulator and free-web-based interface, IBM Quantum Experience, with and without error mitigation, to investigate the effect of the noise on the preparation of the initial mixed states of the qubits in addition to the population of the target state of the system. [ABSTRACT FROM AUTHOR]

Published

2023

22. Quantum Markov semigroup for open quantum system interacting with quantum Bernoulli noises.

Author

Zhang, Lu and Wang, Caishi

Subjects

*QUANTUM noise, *OPEN spaces, *FUNCTIONALS

Abstract

Quantum Bernoulli noises (QBNs) refer to the annihilation and creation operators acting on the space of square integrable Bernoulli functionals, which satisfy the canonical anti-commutation relation (CAR) in equal time. In this paper, we consider the Markov evolution of an open quantum system interacting with QBNs. Let be the system space of an open quantum system interacting with QBNs. Then ⊗ just describes the coupled quantum system. In the framework of ⊗ , we first construct a quantum Markov semigroup that respects the interactions between the system and QBNs, and then we prove that under some mild conditions the semigroup has faithful invariant states. To support our main results mentioned above, we prove several technical propositions and theorems about operators defined in ⊗ . Some other results are also obtained. [ABSTRACT FROM AUTHOR]

Published

2023

23. Emulating Non-Hermitian Dynamics in a Finite Non-Dissipative Quantum System.

Author

Flament, Eloi, Impens, François, and Guéry-Odelin, David

Subjects

*DENSITY of states, *TIME management, *MATHEMATICAL continuum

Abstract

We discuss the emulation of non-Hermitian dynamics during a given time window using a low-dimensional quantum system coupled to a finite set of equidistant discrete states acting as an effective continuum. We first emulate the decay of an unstable state and map the quasi-continuum parameters, enabling the precise approximation of non-Hermitian dynamics. The limitations of this model, including in particular short- and long-time deviations, are extensively discussed. We then consider a driven two-level system and establish criteria for non-Hermitian dynamics emulation with a finite quasi-continuum. We quantitatively analyze the signatures of the finiteness of the effective continuum, addressing the possible emergence of non-Markovian behavior during the time interval considered. Finally, we investigate the emulation of dissipative dynamics using a finite quasi-continuum with a tailored density of states. We show through the example of a two-level system that such a continuum can reproduce non-Hermitian dynamics more efficiently than the usual equidistant quasi-continuum model. [ABSTRACT FROM AUTHOR]

Published

2023

24. Qubit Control and Applications to Quantum Computation and Open Quantum Systems

Author

Yang, Zhibo

Subjects

Chemistry, Quantum physics, Physics, Open Quantum System, Quantum Algorithms, Quantum Computing, Quantum Comtrol, Quantum Physics

Abstract

Quantum computing has the potential to solve problems that are intractable for classical computers. In practice, physical qubits are coupled to their environments and are open quantum systems. To mitigate and correct environmental noises or utilize environmental degrees of freedom, one needs to carefully study the qubit properties in a open quantum system setting. In this thesis, we will first provide an overview of environmental couplings that are relevant to the quantum hardware of interest in the following chapters.We begin the main body of this thesis by introducing a robust control method for the implementation of quantum logic gates in superconducting devices. By switching between two time-constant Hamiltonians, single and two-qubit gates can be implemented with fidelity exceeding the threshold of most quantum error corrections codes in the presence of TLS bath and Markovian bath. This method is inspired by variational quantum algorithms (VQA), and we continue to study quantum machine learning (QML), which is a specific type of VQA, in the following chapter. We investigate the impact of dephasing on QML and show dephasing significantly lower image classification accuracy of QML models. However, we also reveal that increasing virtual bond dimension of QML networks by adding ancilla can improve the accuracy and adding two ancilla can mostly compensate for the accuracy loss due to dephasing.We then investigate qubits in open quantum system for quantum emulation. Specifically, we focus on the emulation of energy transfer between chromosomes in natural light-harvesting complexes using ion-trap quantum devices. This uphill energy transfer is assisted by vibrational modes in the molecules and is named vibration assisted energy transfer (VAET). We start with the study of VAET between two sites (qubits) coupled to one vibrational mode in the presence of classical white noise, which has the effect of dephasing. We show that in the weak noise regime, energy transfer is enhanced by VAET and harmed by the classical noise. In strong noise regime, the VAET signature is wiped out and the energy transfer efficiency will first increase with noise strength and then decrease to a quantum Zeno regime, a phenomenon termed as environment-assisted quantum transport (ENAQT). This is followed by the study of an expanded system with three sites coupled to two vibrational modes. We present a rich array of energy transfer processes. Among them, two phonon process associated to the mode coupled to the bridging site is found to have the greatest contribution to the energy transfer process. We also investigate the model in different scenarios, including varying coupling strength and temperature, presence of dephasing and coupled nodes, finding similar patterns but different relative energy transfer efficiencies. We then conclude with the impact of these studies on the application of near-term quantum devices.

Published

2024

25. Postponing the decay of entanglement and quantum coherence for maximally entangled mixed states under the action of correlated noise channels

Author

Natasha Awasthi, Ashutosh Singh, and Dheeraj Kumar Joshi

Subjects

quantum entanglement, concurrence, memory channel, quantum coherence, open quantum system, Technology

Abstract

We investigate the dynamics of a maximally entangled mixed state (MEMS) under the action of correlated noise channels. The channel acts in a way that its successive uses are correlated. We have studied the MEMS properties, including quantum coherence and entanglement. For partially correlated channels, both the entanglement and coherence of MEMS are found to decay much slower than those of the memoryless channels. Moreover, we observe a freezing effect of coherence for phase damping as well as depolarizing channels and freezing of entanglement for phase-damping channels with perfect memory. For amplitude damping and depolarizing channels, memory helps in either delaying the sudden death of entanglement or slowing the decay rate of coherence. These observations suggest that memory channels perform better than memoryless channels in maintaining the integrity of quantum states and have utility in quantum information processing protocols.

Published

2023

26. Exact solution of a non-Hermitian PT -symmetric spin chain.

Author

Kattel, Pradip, Pasnoori, Parameshwar R, and Andrei, Natan

Subjects

*BOUND states, *PHASE transitions, *SYMMETRY breaking, *SPIN-spin interactions

Abstract

We construct the exact solution of a non-Hermitian P T -symmetric isotropic Heisenberg spin chain with integrable boundary fields. We find that the system exhibits two types of phases named A and B. In the B type phase, the P T symmetry remains unbroken and it comprises of eigenstates with only real energies, whereas the A type phase exhibits both P T symmetry broken and unbroken sectors, comprising of eigenstates with only complex and real energies respectively. The P T -symmetry broken sector comprises of pairs of eigenstates whose energies are complex conjugates of each other. The existence of two sectors in the A type phase is associated with the exponentially localized bound states at the edges with complex energies which are described by boundary strings. We find that both A and B type phases can be further divided into sub-phases which exhibit different ground states. We also compute the bound state wavefunction in one magnon sector and find that as the imaginary value of the boundary parameter is increased, the exponentially localized wavefunction broadens thereby protruding more into the bulk, which indicates that exponentially localized bound states may not be stabilized for large imaginary values of the boundary parameter. [ABSTRACT FROM AUTHOR]

Published

2023

27. Time-Convolutionless Master Equations for Composite Open Quantum Systems.

Author

Karasev, A. Yu. and Teretenkov, A. E.

Abstract

In this work we consider the master equations for composite open quantum systems. We provide purely algebraic formulae for terms of perturbation series defining such equations. We also give conditions under which the Bogolubov–van Hove limit exists and discuss some corrections to this limit. We present an example to illustrate our results. In particular, this example shows, that inhomogeneous terms in time-convolutionless master equations can vanish after reservoir correlation time, but lead to renormalization of initial conditions at such a timescale. [ABSTRACT FROM AUTHOR]

Published

2023

28. Completely positive reduced dynamics with non-Markovian initial states

Author

Samira Nazifkar and Iman Sargolzahi

Subjects

open quantum system, completely positive map, markov state, Physics, QC1-999

Abstract

Consider an open quantum system S, interacting with its environment E, and also an ancillary Hilbert space R. The reduced dynamics of the system S is given by a completely positive map, if the set S={ρSE} , of possible initial states of the system-environment, can be written as a steered set from a tripartite Markov state ƮRSE. In this paper, we call such steered states as Markovian states ρSE, and study a physical case, in which the reduced dynamics of the system can be completely positive, even when the initial states of the system-environment ρSE are non-Markovian.

Published

2023

29. Quantum Dynamics Far from Equilibrium: A Case Study in the Spherical Model

Author

Henkel, Malte and Dobrev, Vladimir, editor

Published

2022

30. A Mean-Field Laser Quantum Master Equation

Author

Fagnola, Franco, Mora, Carlos M., Accardi, Luigi, editor, Mukhamedov, Farrukh, editor, and Al Rawashdeh, Ahmed, editor

Published

2022

31. Numerical analysis for inchworm Monte Carlo method: Sign problem and error growth.

Author

Cai, Zhenning, Lu, Jianfeng, and Yang, Siyao

Subjects

*NUMERICAL analysis, *ORDINARY differential equations, *MONTE Carlo method, *QUANTUM Monte Carlo method

Abstract

We consider the numerical analysis of the inchworm Monte Carlo method, which is proposed recently to tackle the numerical sign problem for open quantum systems. We focus on the growth of the numerical error with respect to the simulation time, for which the inchworm Monte Carlo method shows a flatter curve than the direct application of Monte Carlo method to the classical Dyson series. To better understand the underlying mechanism of the inchworm Monte Carlo method, we distinguish two types of exponential error growth, which are known as the numerical sign problem and the error amplification. The former is due to the fast growth of variance in the stochastic method, which can be observed from the Dyson series, and the latter comes from the evolution of the numerical solution. Our analysis demonstrates that the technique of partial resummation can be considered as a tool to balance these two types of error, and the inchworm Monte Carlo method is a successful case where the numerical sign problem is effectively suppressed by such means. We first demonstrate our idea in the context of ordinary differential equations, and then provide complete analysis for the inchworm Monte Carlo method. Several numerical experiments are carried out to verify our theoretical results. [ABSTRACT FROM AUTHOR]

Published

2023

32. Tunable Non-Markovianity for Bosonic Quantum Memristors.

Author

Tang, Jia-Liang, Alvarado Barrios, Gabriel, Solano, Enrique, and Albarrán-Arriagada, Francisco

Subjects

*MEMRISTORS, *QUBITS, *DECAY rates (Radioactivity), *STEADY state conduction

Abstract

We studied the tunable control of the non-Markovianity of a bosonic mode due to its coupling to a set of auxiliary qubits, both embedded in a thermal reservoir. Specifically, we considered a single cavity mode coupled to auxiliary qubits described by the Tavis–Cummings model. As a figure of merit, we define the dynamical non-Markovianity as the tendency of a system to return to its initial state, instead of evolving monotonically to its steady state. We studied how this dynamical non-Markovianity can be manipulated in terms of the qubit frequency. We found that the control of the auxiliary systems affects the cavity dynamics as an effective time-dependent decay rate. Finally, we show how this tunable time-dependent decay rate can be tuned to engineer bosonic quantum memristors, involving memory effects that are fundamental for developing neuromorphic quantum technologies. [ABSTRACT FROM AUTHOR]

Published

2023

33. Interacting Stochastic Schrödinger Equation.

Author

Zhang, Lu, Wang, Caishi, and Chen, Jinshu

Subjects

*QUANTUM noise, *HILBERT space, *OPEN spaces, *FUNCTIONALS, *NONLINEAR Schrodinger equation, *SCHRODINGER operator

Abstract

Being the annihilation and creation operators on the space h of square integrable Bernoulli functionals, quantum Bernoulli noises (QBN) satisfy the canonical anti-commutation relation (CAR) in equal time. Let K be the Hilbert space of an open quantum system interacting with QBN (the environment). Then K ⊗ h just describes the coupled quantum system. In this paper, we introduce and investigate an interacting stochastic Schrödinger equation (SSE) in the framework K ⊗ h , which might play a role in describing the evolution of the open quantum system interacting with QBN (the environment). We first prove some technical propositions about operators in K ⊗ h . In particular, we obtain the spectral decomposition of the tensor operator I K ⊗ N , where I K means the identity operator on K and N is the number operator in h , and give a representation of I K ⊗ N in terms of operators I K ⊗ ∂ k ∗ ∂ k , k ≥ 0 , where ∂ k and ∂ k ∗ are the annihilation and creation operators on h , respectively. Based on these technical propositions as well as Mora and Rebolledo's results on a general SSE, we show that under some mild conditions, our interacting SSE has a unique solution admitting some regularity properties. Some other results are also proven. [ABSTRACT FROM AUTHOR]

Published

2023

34. Optimization of Coherent Dynamics of Localized Surface Plasmons in Gold and Silver Nanospheres; Large Size Effects.

Author

Kolwas, Krystyna

Subjects

*SURFACE plasmons, *SURFACE dynamics, *METAL nanoparticles, *STRUCTURAL colors, *GOLD nanoparticles, *GOLD films, *PLASMONS (Physics), *SURFACE plasmon resonance

Abstract

Noble metal nanoparticles have attracted attention in recent years due to a number of their exciting applications in plasmonic applications, e.g., in sensing, high-gain antennas, structural colour printing, solar energy management, nanoscale lasing, and biomedicines. The report embraces the electromagnetic description of inherent properties of spherical nanoparticles, which enable resonant excitation of Localized Surface Plasmons (defined as collective excitations of free electrons), and the complementary model in which plasmonic nanoparticles are treated as quantum quasi-particles with discrete electronic energy levels. A quantum picture including plasmon damping processes due to the irreversible coupling to the environment enables us to distinguish between the dephasing of coherent electron motion and the decay of populations of electronic states. Using the link between classical EM and the quantum picture, the explicit dependence of the population and coherence damping rates as a function of NP size is given. Contrary to the usual expectations, such dependence for Au and Ag NPs is not a monotonically growing function, which provides a new perspective for tailoring plasmonic properties in larger-sized nanoparticles, which are still hardly available experimentally. The practical tools for comparing the plasmonic performance of gold and silver nanoparticles of the same radii in an extensive range of sizes are also given. [ABSTRACT FROM AUTHOR]

Published

2023

35. Spectral density classification for environment spectroscopy

Author

J Barr, G Zicari, A Ferraro, and M Paternostro

Subjects

open quantum system, neural network, spectral density, spin-boson, Ohmic, sub-Ohmic, Computer engineering. Computer hardware, TK7885-7895, Electronic computers. Computer science, QA75.5-76.95

Abstract

Spectral densities encode the relevant information characterizing the system–environment interaction in an open-quantum system problem. Such information is key to determining the system’s dynamics. In this work, we leverage the potential of machine learning techniques to reconstruct the features of the environment. Specifically, we show that the time evolution of a system observable can be used by an artificial neural network to infer the main features of the spectral density. In particular, for relevant examples of spin-boson models, we can classify with high accuracy the Ohmicity parameter of the environment as either Ohmic, sub-Ohmic or super-Ohmic, thereby distinguishing between different forms of dissipation.

Published

2024

36. Noise-resilient phase transitions and limit-cycles in coupled Kerr oscillators

Author

H Alaeian, M Soriente, K Najafi, and S F Yelin

Subjects

open quantum system, limit-cycle, quantum synchronization, Keldysh formalism, Bose–Hubbard model, cumulant expansion, Science, Physics, QC1-999

Abstract

In recent years, there has been considerable focus on exploring driven-dissipative quantum systems, as they exhibit distinctive dissipation-stabilized phases. Among them dissipative time crystal is a unique phase emerging as a shift from disorder or stationary states to periodic behaviors. However, understanding the resilience of these non-equilibrium phases against quantum fluctuations remains unclear. This study addresses this query within a canonical parametric quantum optical system, specifically, a multi-mode cavity with self- and cross-Kerr non-linearity. Using mean-field (MF) theory we obtain the phase diagram and delimit the parameter ranges that stabilize a non-stationary limit-cycle phase. Leveraging the Keldysh formalism, we study the unique spectral features of each phase. Further, we extend our analyses beyond the MF theory by explicitly accounting for higher-order correlations through cumulant expansions. Our findings unveil insights into the modifications of the open quantum systems phases, underscoring the significance of quantum correlations in non-equilibrium steady states. Importantly, our results conclusively demonstrate the resilience of the non-stationary phase against quantum fluctuations, rendering it a dissipation-induced genuine quantum synchronous phase.

Published

2024

37. Bound on the distance between controlled quantum state and target state under decoherence

Author

Kohei Kobayashi

Subjects

decoherence, open quantum system, quantum control, Science, Physics, QC1-999

Abstract

To implement quantum information technologies, carefully designed control for preparing a desired state plays a key role. However, in realistic situation, the actual performance of those methodologies is severely limited by decoherence. Therefore, it is important to evaluate how close we can steer the controlled state to a desired target state under decoherence. In this paper, we provide an upper bound of the distance between the two controlled quantum systems in the presence and absence of decoherence. The bound quantifies the degree of achievement of the control for a given target state under decoherence, and can be straightforwardly calculated without solving any equation. Moreover, the upper bound is applied to derive a theoretical limit of the probability for obtaining the target state under decoherence.

Published

2024

38. Control of the von Neumann Entropy for an Open Two-Qubit System Using Coherent and Incoherent Drives

Author

Oleg V. Morzhin and Alexander N. Pechen

Subjects

quantum control, von Neumann entropy, quantum thermodynamics, open quantum system, coherent control, incoherent control, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

This article is devoted to developing an approach for manipulating the von Neumann entropy S(ρ(t)) of an open two-qubit system with coherent control and incoherent control inducing time-dependent decoherence rates. The following goals are considered: (a) minimizing or maximizing the final entropy S(ρ(T)); (b) steering S(ρ(T)) to a given target value; (c) steering S(ρ(T)) to a target value and satisfying the pointwise state constraint S(ρ(t))≤S¯ for a given S¯; (d) keeping S(ρ(t)) constant at a given time interval. Under the Markovian dynamics determined by a Gorini–Kossakowski–Sudarshan–Lindblad type master equation, which contains coherent and incoherent controls, one- and two-step gradient projection methods and genetic algorithm have been adapted, taking into account the specifics of the objective functionals. The corresponding numerical results are provided and discussed.

Published

2023

39. Quantum Manifestation of the Classical Bifurcation in the Driven Dissipative Bose–Hubbard Dimer.

Author

Muraev, Pavel, Maksimov, Dmitrii, and Kolovsky, Andrey

Subjects

*QUANTUM theory, *DENSITY matrices, *FREQUENCIES of oscillating systems, *LIMIT cycles

Abstract

We analyze the classical and quantum dynamics of the driven dissipative Bose–Hubbard dimer. Under variation of the driving frequency, the classical system is shown to exhibit a bifurcation to the limit cycle, where its steady-state solution corresponds to periodic oscillation with the frequency unrelated to the driving frequency. This bifurcation is shown to lead to a peculiarity in the stationary single-particle density matrix of the quantum system. The case of the Bose–Hubbard trimer, where the discussed limit cycle bifurcates into a chaotic attractor, is briefly discussed. [ABSTRACT FROM AUTHOR]

Published

2023

40. Universal signature of quantum entanglement across cosmological distances.

Author

Brahma, Suddhasattwa, Berera, Arjun, and CalderĂłn-Figueroa, Jaime

Subjects

*COSMOLOGICAL distances, *QUANTUM entanglement, *INFLATIONARY universe, *QUANTUM information theory, *QUANTUM fluctuations

Abstract

Although the paradigm of inflation has been extensively studied to demonstrate how macroscopic inhomogeneities in our Universe originate from quantum fluctuations, most of the established literature ignores the crucial role that entanglement between the modes of the fluctuating field plays in its observable predictions. In this paper, we import techniques from quantum information theory to reveal hitherto undiscovered predictions for inflation which, in turn, signals how quantum entanglement across cosmological scales can affect large scale structure. Our key insight is that observable long-wavelength modes must be part of an open quantum system, so that the quantum fluctuations can decohere in the presence of an environment of short-wavelength modes. By assuming the simplest model of single-field inflation, and considering the leading order interaction term from the gravitational action, we derive a universal lower bound on the observable effect of such inescapable entanglement. Although this signal is too weak for direct detection in the foreseeable future, we discuss the importance of its theoretical implications. [ABSTRACT FROM AUTHOR]

Published

2022

41. Stable Many-Body Resonances in Open Quantum Systems.

Author

Peña, Rubén, Kyaw, Thi Ha, and Romero, Guillermo

Subjects

*THERMAL neutrons, *QUANTUM information science, *HUMAN information processing, *PHASES of matter, *RESONANCE, *SYSTEM dynamics

Abstract

Periodically driven quantum many-body systems exhibit novel nonequilibrium states, such as prethermalization, discrete time crystals, and many-body localization. Recently, the general mechanism of fractional resonances has been proposed that leads to slowing the many-body dynamics in systems with both U (1) and parity symmetry. Here, we show that fractional resonance is stable under local noise models. To corroborate our finding, we numerically study the dynamics of a small-scale Bose–Hubbard model that can readily be implemented in existing noisy intermediate-scale quantum (NISQ) devices. Our findings suggest a possible pathway toward a stable nonequilibrium state of matter, with potential applications of quantum memories for quantum information processing. [ABSTRACT FROM AUTHOR]

Published

2022

42. The Irreversible Quantum Dynamics of the Three-Level su (1, 1) Bosonic Model.

Author

Bogoliubov, Nikolai M. and Rybin, Andrei V.

Subjects

*QUANTUM theory, *DENSITY matrices, *HAMILTONIAN systems

Abstract

We study the quantum dynamics of the opened three-level su(1, 1) bosonic model. The effective non-Hermitian Hamiltonians describing the system of the Lindblad equation in the short time limit are constructed. The obtained non-Hermitian Hamiltonians are exactly solvable by the Algebraic Bethe Ansatz. This approach allows representing biorthogonal and nonorthogonal bases of the system. We analyze the biorthogonal expectation values of a number of particles in the zero mode and represent it in the determinantal form. The time-dependent density matrix satisfying the Lindblad master equation is found in terms of the nonorthogonal basis. [ABSTRACT FROM AUTHOR]

Published

2022

43. Multiparameter estimation for a two-qubit system coupled to independent reservoirs using quantum Fisher information

Author

Bukbech, S., El Anouz, K., El Allali, Z., Metwally, N., and El Allati, A.

Published

2023

44. Influence of initial correlations on evolution over time of an open quantum system.

Author

Los, Victor F.

Subjects

*STATISTICAL correlation, *QUANTUM theory, *OPERATOR functions, *EVOLUTION equations, *QUANTUM correlations

Abstract

A novel approach to accounting for the influence of initial system–bath correlations on the dynamics of an open quantum system, based on the conventional projection operator technique, is suggested. To avoid the difficulties of treating the initial correlations, the conventional Nakajima–Zwanzig inhomogeneous generalized master equations (GMEs) for a system's reduced statistical operator and correlation function are exactly converted into the homogeneous GMEs (HGMEs), which take into account the initial correlations in the kernel governing the evolution of these HGMEs. In the second order (Born) approximation in the system–bath interaction, the obtained HGMEs are local in time and valid at all timescales. They are further specialized for a realistic equilibrium Gibbs initial (at t = t 0 ) system+bath state (for a system reduced statistical operator an external force at t > t 0 is applied) and then for a bath of oscillators (Boson field). As an example, the evolution of a selected quantum oscillator (a localized mode) interacting with a Boson field (Fano-like model) is considered at different timescales. It is shown explicitly how the initial correlations influence the oscillator evolution process. In particular, it is shown that the equilibrium system's correlation function acquires at the large timescale the additional constant phase factor conditioned by survived initial system–bath correlations. [ABSTRACT FROM AUTHOR]

Published

2024

45. Quantum Control Landscapes for Generation of H and T Gates in an Open Qubit with Both Coherent and Environmental Drive

Author

Vadim N. Petruhanov and Alexander N. Pechen

Subjects

incoherent control, control by environment, open quantum system, qubit, quantum gate generation, gradient method, Applied optics. Photonics, TA1501-1820

Abstract

An important problem in quantum computation is the generation of single-qubit quantum gates such as Hadamard (H) and π/8 (T) gates, which are components of a universal set of gates. Qubits in experimental realizations of quantum computing devices are interacting with their environment. While the environment is often considered as an obstacle leading to a decrease in the gate fidelity, in some cases, it can be used as a resource. Here, we consider the problem of the optimal generation of H and T gates using coherent control and the environment as a resource acting on the qubit via incoherent control. For this problem, we studied the quantum control landscape, which represents the behavior of the infidelity as a functional of the controls. We considered three landscapes, with infidelities defined by steering between two, three (via Goerz–Reich–Koch approach), and four matrices in the qubit Hilbert space. We observed that, for the H gate, which is a Clifford gate, for all three infidelities, the distributions of minimal values obtained with a gradient search have a simple form with just one peak. However, for the T gate, which is a non-Clifford gate, the situation is surprisingly different—this distribution for the infidelity defined by two matrices also has one peak, whereas distributions for the infidelities defined by three and four matrices have two peaks, which might indicate the possible existence of two isolated minima in the control landscape. It is important that, among these three infidelities, only those defined with three and four matrices guarantee the closeness of the generated gate to a target and can be used as a good measure of closeness. We studied sets of optimized solutions for the most general and previously unexplored case of coherent and incoherent controls acting together and discovered that they form sub-manifolds in the control space, and unexpectedly, in some cases, two isolated sub-manifolds.

Published

2023

46. The Quantum State Engineering by Adiabatic Decoherence-Free Subspace

Author

Gao, Yue, Ping, Yifan, Liu, Zhongju, Kacprzyk, Janusz, Series Editor, Pal, Nikhil R., Advisory Editor, Bello Perez, Rafael, Advisory Editor, Corchado, Emilio S., Advisory Editor, Hagras, Hani, Advisory Editor, Kóczy, László T., Advisory Editor, Kreinovich, Vladik, Advisory Editor, Lin, Chin-Teng, Advisory Editor, Lu, Jie, Advisory Editor, Melin, Patricia, Advisory Editor, Nedjah, Nadia, Advisory Editor, Nguyen, Ngoc Thanh, Advisory Editor, Wang, Jun, Advisory Editor, MacIntyre, John, editor, Zhao, Jinghua, editor, and Ma, Xiaomeng, editor

Published

2021

47. The study of quantum speed limit time in a quantum critical environment

Author

S Haseli

Subjects

quantum speed limit, open quantum system, quantum critical environment, Physics, QC1-999

Abstract

Quantum theory sets a bound on the speed of quantum evolution. The shortest time needed for a quantm system to evolve from an initial state to the target state is known as the quantum speed limit time. The study of this time in open and closed quantum systems has been the subject of much work in quantum information theory. Quantum speed limit time is inversely related to the evolution rate of a quantum process. This relation is such that the speed of evolution decreases with increasing quantum speed limit time and vice versa. In this work we study the QSL time for the case in which a qubit interacts with a quantum critical environment. We choose the environment to be an Ising spin chain in a transverse field. It is observed that for the quantum speed limit time has a direct relation with quantum coherence of the initial state of the system. We will also study the effect of perturbation coupling on quantum speed limit time. It is observed that the quantum speed limit time decreases with increasing the coupling parameter. It is also observed that the quantum speed limit time decreases with increasing the number of spin in spin chain.

Published

2022

48. Disentanglement Dynamics in Nonequilibrium Environments.

Author

Chen, Mingli, Chen, Haonan, Han, Tao, and Cai, Xiangji

Subjects

*QUANTUM correlations, *DENSITY matrices, *TENSOR products, *QUBITS, *SUDDEN death, *QUANTUM transitions

Abstract

We theoretically study the non-Markovian disentanglement dynamics of a two-qubit system coupled to nonequilibrium environments with nonstationary and non-Markovian random telegraph noise statistical properties. The reduced density matrix of the two-qubit system can be expressed as the Kraus representation in terms of the tensor products of the single qubit Kraus operators. We derive the relation between the entanglement and nonlocality of the two-qubit system which are both closely associated with the decoherence function. We identify the threshold values of the decoherence function to ensure the existences of the concurrence and nonlocal quantum correlations for an arbitrary evolution time when the two-qubit system is initially prepared in the composite Bell states and the Werner states, respectively. It is shown that the environmental nonequilibrium feature can suppress the disentanglement dynamics and reduce the entanglement revivals in non-Markovian dynamics regime. In addition, the environmental nonequilibrium feature can enhance the nonlocality of the two-qubit system. Moreover, the entanglement sudden death and rebirth phenomena and the transition between quantum and classical nonlocalities closely depend on the parameters of the initial states and the environmental parameters in nonequilibrium environments. [ABSTRACT FROM AUTHOR]

Published

2022

49. Toward Scalable Control of Open Quantum Systems

Author

Chalermpusitarak, Teerawat and Chalermpusitarak, Teerawat

Abstract

An open quantum system is composed of a quantum system of interest that one can control and extract information, and its environment that is uncontrollable and directly inaccessible. The environment acts as a source of noise, which influences the dynamics of the system in an undesirable way. With the advanced development of quantum technologies, the need to precisely control the quantum system has become more dramatic. Dynamical error suppression techniques, such as dynamical decoupling and quantum optimal control techniques, have emerged as key tools to mitigate the effect of noise and improve the quality of control. Importantly, they rely on some degree of knowledge about the environment in order to succeed in suppressing the noise. Therefore, noise characterization is a crucial step before deploying any dynamical error suppression tools. It can be shown that the environment affects the dynamics of the system of interest via its noise correlation functions, or equivalently the polyspectra. Thus, these quantities are what can be learned from the system's dynamics in the presence of control. The protocols for characterizing the noise in this way fall under the umbrella of quantum noise spectroscopy. Historically, most of these protocols have been restricted to characterizing classical noise processes affecting the quantum system of interest, mostly due to the difficulty of moving beyond this limit. Ideally, however, one would like to have spectroscopy protocols capable of characterizing arbitrary noise, such as the one that may be present in a real quantum device. Thus, there is a need to generalize existing quantum noise spectroscopy protocols. Only in this way, the information they provide will be useful to predict and eventually control realistic noisy quantum systems. In the first part of this thesis, we study the implications of having a quantum environment interacting with a system. We find that the quantum environment can generate correlations with a rich str, Thesis (PhD Doctorate), Doctor of Philosophy, School of Environment and Sc, Griffith Sciences, Full Text

Published

2024

50. Dissipativity of the Quantum Measurement Model

Author

Zorin, Alexander V., Sevastianov, Leonid A., Tretyakov, Nikolay P., Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Gribaudo, Marco, editor, Sopin, Eduard, editor, and Kochetkova, Irina, editor

Published

2020