Continuous-time quantum walks in the presence of a quadratic perturbation

Candeloro, Alessandro; Razzoli, Luca; Cavazzoni, Simone; Bordone, Paolo; Paris, Matteo G. A.

doi:10.1103/physreva.102.042214

Cited by 7 publications

(3 citation statements)

References 50 publications

(100 reference statements)

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“…We also leave open the question of whether real NNN couplings can be effectively implemented in quantum walks via Floquet engineering. In principle, this could be used to simulate quadratic perturbations to the usual quantum walk Hamiltonian [55] or quantum walks on other structures such as complex networks [22].…”

Section: Discussionmentioning

confidence: 99%

Floquet engineering of continuous-time quantum walks: towards the simulation of complex and next-to-nearest neighbor couplings

Novo,

Ribeiro

2020

Preprint

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Section: Discussionmentioning

confidence: 99%

Floquet engineering of continuous-time quantum walks: towards the simulation of complex and next-to-nearest neighbor couplings

Novo,

Ribeiro

2020

Preprint

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“…The parameter γ ≥ 0 is referred to as the decoherence rate, and L is the graph Laplacian. From an operational point of view, intrinsic decoherence corresponds to a randomized quadratic perturbation [32].…”

Section: Noisy Quantum Walksmentioning

confidence: 99%

Decoherence and classicalization of continuous-time quantum walks on graphs

Gabriele

Benedetti

Paris

2022

Quantum Inf Process

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We address decoherence and classicalization of continuous-time quantum walks (CTQWs) on graphs. In particular, we investigate three different models of decoherence and employ the quantum-classical (QC) dynamical distance as a figure of merit to assess whether, and to which extent, decoherence classicalizes the CTQW, i.e. turns it into the analogue classical process. We show that the dynamics arising from intrinsic decoherence, i.e. dephasing in the energy basis, do not fully classicalize the walker and partially preserves quantum features. On the other hand, dephasing in the position basis, as described by the Haken–Strobl master equation or by the quantum stochastic walk (QSW) model, asymptotically destroys the quantumness of the walker, making it equivalent to a classical random walk. We also investigate how fast is the classicalization process and observe a larger rate of convergence of the QC-distance to its asymptotic value for intrinsic decoherence and the QSW models, whereas in the Haken–Strobl scenario, larger values of the decoherence rate induce localization of the walker.

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“…By fully connected vertex we mean a vertex which is adjacent (connected) to all the other vertices of the graph, as shown in figure 1. The dynamics of the central vertex of the star graph and that of any vertex of the complete graph are equivalent, showing periodic perfect revivals and strong localization on the initial vertex [15], even in the presence of a perturbation λL 2 [16]. The spatial search of a marked vertex on the complete graph or on the star graph, when the target is the central vertex, are equivalent [17], and the same qualitative results are observed even in the presence of weak random telegraph noise [18].…”

Section: Introductionmentioning

confidence: 99%

Universality of the fully connected vertex in Laplacian continuous-time quantum walk problems

Razzoli

Bordone

Paris

2022

J. Phys. A: Math. Theor.

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A fully connected vertex w in a simple graph G of order N is a vertex connected to all the other N − 1 vertices. Upon denoting by L the Laplacian matrix of the graph, we prove that the continuous-time quantum walk (CTQW)—with Hamiltonian H = γL—of a walker initially localized at |w〉 does not depend on the graph G. We also prove that for any Grover-like CTQW—with Hamiltonian H = γL + ∑w λw |w〉〈w|—the probability amplitude at the fully connected marked vertices w does not depend on G. The result does not hold for CTQW with Hamiltonian H = γA (adjacency matrix). We apply our results to spatial search and quantum transport for single and multiple fully connected marked vertices, proving that CTQWs on any graph G inherit the properties already known for the complete graph of the same order, including the optimality of the spatial search. Our results provide a uniﬁed framework for several partial results already reported in literature for fully connected vertices, such as the equivalence of CTQW and of spatial search for the central vertex of the star and wheel graph, and any vertex of the complete graph.

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Continuous-time quantum walks in the presence of a quadratic perturbation

Cited by 7 publications

References 50 publications

Floquet engineering of continuous-time quantum walks: towards the simulation of complex and next-to-nearest neighbor couplings

Floquet engineering of continuous-time quantum walks: towards the simulation of complex and next-to-nearest neighbor couplings

Decoherence and classicalization of continuous-time quantum walks on graphs

Universality of the fully connected vertex in Laplacian continuous-time quantum walk problems

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