Nonlinear decoherence in quantum state preparation of a trapped ion

We investigate system-environment correlations based on the exact dynamics of a qubit and its environment in the framework of pure decoherence (phase damping). We focus on the relation of decoherence and the build-up of system-reservoir entanglement for an arbitrary (possibly mixed) initial qubit state. In the commonly employed regime where the qubit dynamics can be described by a Markov master equation of Lindblad type, we find that for almost all qubit initial states inside the Bloch sphere, decoherence is complete while the total state is still separable -no entanglement is involved. In general, both "separable" and "entangling" decoherence occurs, depending on temperature and initial qubit state. Moreover, we find situations where classical and quantum correlations periodically alternate as a function of time in the regime of low temperatures.

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“…Describing pure decoherence (phase damping), we will assume a standard model [20,21] [9,[22][23][24][25].…”

Section: Open Quantum System Model For Decoherence and Reduced Dymentioning

confidence: 99%

Decoherence and the nature of system-environment correlations

Pernice

Strunz

2011

Phys. Rev. A

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“…Therefore there is no energy dissipation in this system. Note that this form of coupling has been used to study quantum decoherence in Bose-Einstein condensation and trapped ion by Kuang and coworkers [37]. The renormalization term has the following form…”

Section: Physical Model and Solutionmentioning

confidence: 99%

Amplification of quantum discord between two uncoupled qubits in a common environment by phase decoherence

Yuan

Kuang

Liao

2010

J. Phys. B: At. Mol. Opt. Phys.

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We study analytically the dynamic behaviors of quantum correlation measured by quantum discord between two uncoupled qubits, which are immersed in a common Ohmic environment. We show that the quantum discord of the two noninteracting qubits can be greatly amplified or protected for certain initially prepared X-type states in the time evolution. Especially, it is found that there does exist the stable amplification of the quantum discord for the case of two identical qubits, and the quantum discord can be protected for the case of two different qubits with a large detuning. It is also indicated that in general there does exist a sudden change of the quantum discord in the time evolution at a critic time point t c , and the discord amplification and protection may occur only in the time interval 0 < t ≤ t c for certain X-type states. This sheds new light on the creation and protection of quantum correlation.

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“…In principle, an exact solution of the spin-boson model in the same perpendicular coupling case θ = π/2 was also obtained 14 , which however does not lend itself to a description of the effective qubit dynamics because tracing out the bath is still highly nontrivial. Furthermore, in the simple case that the coupling direction and the energy basis direction of the system are parallel (θ = 0), the spin-boson model is also exactly solvable 15,16 .Away from the limiting cases of parallel and perpendicular coupling, θ = 0, π/2, perturbative approaches have been employed 6,7,9,16 . However, as pointed out in 16 , the previous perturbative approaches show a pathological behavior for the subohmic heat bath by predicting the instantaneous loss of phase coherence for any finite coupling η.…”

mentioning

confidence: 99%

Consistent perturbative treatment of the subohmic spin-boson model yielding arbitrarily smallT2/T1decoherence time ratios

Noh

Fischer

2014

Phys. Rev. B

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We present a perturbative treatment of the subohmic spin-boson model which remedies a crucial flaw in previous treatments. The problem is traced back to the incorrect application of a Markov type approximation to specific terms in the temporal evolution of the reduced density matrix. The modified solution is consistent both with numerical simulations and the exact solution obtained when the bath-coupling spin-space direction is parallel to the qubit energy-basis spin. We therefore demonstrate that the subohmic spin-boson model is capable of describing arbitrarily small ratios of the T2 and T1 decoherence times, associated to the decay of the off-diagonal and diagonal reduced density-matrix elements, respectively. An analytical formula for T2/T1 at the absolute zero of temperature is provided in the limit of a subohmic bath with vanishing spectral power law exponent. Small ratios closely mimic the experimental results for solid state (flux) qubits, which are subject predominantly to low-frequency electromagnetic noise, and we suggest a reanalysis of the corresponding experimental data in terms of a nonanalytic decay of off-diagonal coherence.Since the advent of quantum information technology, the problem of two-state systems aka qubits, immersed in environmental (bath) degrees of freedom has increasingly gained importance, cf., e.g., 1-3 . The spin-boson model, succinctly describing such a physical situation, namely an open two-state quantum system interacting with a bath, accounts for two-state energy relaxation and dephasing, and therefore has been studied extensively 4,5 . It was, for example, used to describe physical contexts as diverse as flux qubits implemented using superconducting quantum interference devices (SQUIDs) 6-10 , electron transfer in biomolecules 11 , and phonon coupling in atomic tunneling 12 . The spin-boson model introduces a continuum of independent simple harmonic oscillators with a given spectral weight distribution as the environment, assuming them to couple with the qubit linearly. The Hamiltonian of the entire (closed) system therefore reads (setting = 1)Here, − → σ = (σ x , σ y , σ z ) are the usual Pauli matrices andb † k ,b k are creation and annihilation operators of harmonic oscillators in the (infinitely extended) bath, labelled by the quantum number(s) k, which can stand, e.g., for the momentum of the bath excitations. The coupling direction − → n is parametrized by two angles θ,ϕ as − → n = (sin θ cos ϕ, sin θ sin ϕ, cos θ).The bath is conventionally characterized by the quantity J(ω) ≡ k λ 2 k δ(ω − ω k ), which determines the dynamics of the spin-boson model. This spectral density of the bath is effectively a density of states summation weighed by the coupling strength squared λ 2 k , hence the name. Usually it is assumed that J(ω) is of a power law form up to a cutoff, J(ω) = ηω, where ω c is the (physical) cutoff frequency of the bath, assumed to be much larger than the system frequency spacing ω s . The strength of coupling is parametrized by the dimensionless η. Baths h...

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Nonlinear decoherence in quantum state preparation of a trapped ion

Cited by 39 publications

References 50 publications

Decoherence and the nature of system-environment correlations

Decoherence and the nature of system-environment correlations

Amplification of quantum discord between two uncoupled qubits in a common environment by phase decoherence

Consistent perturbative treatment of the subohmic spin-boson model yielding arbitrarily smallT2/T1decoherence time ratios

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