Analytical study of quadratic and nonquadratic short-time behavior of quantum decay

Cordero, Sergio; García–Calderón, Gastón

doi:10.1103/physreva.86.062116

Cited by 16 publications

(16 citation statements)

References 31 publications

(78 reference statements)

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“…The scaling dynamics holds exactly for the CS gas and simplifies the ensuing analysis by contrast to other many-body systems such as, e.g., the 1D Bose gas, where only recently moderate progress accounting for its dynamics has been reported [52][53][54][55]. Comparing the first leading terms in a long-time asymptotic expansion, it is found that the power-law (14) sets in when the time of evolution satisfies…”

Section: Sudden Expansionmentioning

confidence: 75%

“…Experimentally, it was first demonstrated in [11] and its existence sets the ground for the quantum Zeno effect [12]. It is a consequence of unitary time-evolution, provided that the first and second moments of the Hamiltonian exist, see [13,14] for exceptional cases. That deviations from exponential decay are as well to be expected at long times was pointed out by Khalfin in 1957, for systems whose energy spectrum is bounded from below [8].…”

Section: Introductionmentioning

confidence: 99%

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Exact quantum decay of an interacting many-particle system: the Calogero–Sutherland model

Campo

2016

New J. Phys.

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The exact quantum decay of a one-dimensional Bose gas with inverse-square interactions is presented. The system is equivalent to a gas of particles obeying generalized exclusion statistics. We consider the expansion dynamics of a cloud initially confined in a harmonic trap that is suddenly switched off. The decay is characterized by analyzing the fidelity between the initial and the time-evolving states, also known as the survival probability. It exhibits early on a quadratic dependence on time that turns into a power-law decay, during the course of the evolution. It is shown that the particle number and the strength of interactions determine the power-law exponent in the latter regime, as recently conjectured. The nonexponential character of the decay is linked to the many-particle reconstruction of the initial state from the decaying products. OPEN ACCESS RECEIVED

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Section: Sudden Expansionmentioning

confidence: 75%

Section: Introductionmentioning

confidence: 99%

Exact quantum decay of an interacting many-particle system: the Calogero–Sutherland model

Campo

2016

New J. Phys.

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“…It is of interest to see, in view of (8), that the coefficients C n fulfill the relation [17] Re ∞ n=1 C nCn = 1,…”

Section: Dynamics Of the Decaying Wave Function Using Resonant Stmentioning

confidence: 99%

“…Khalfin demonstrated that if the energy spectra E of the system is bounded from below, i.e., E ∈ (0,∞), the exponential decay law cannot hold at long times [5]. At short times there is also a departure from the exponential behavior that, however, has a dependence on the initial state of the problem [6][7][8]. The experimental verification of the above departures from the exponential decay law remained elusive for decades but has been finally corroborated by experiment [9,10].…”

Section: Introductionmentioning

confidence: 99%

Time-domain resonances and the ultimate fate of a decaying quantum state

2013

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We derive an analytical expression for the propagation of a quantum particle at asymptotic long distances and times from the potential where the particle was initially confined. We obtain that the particle is described by an evolving resonance in time domain that possesses a peaked shape characterized by the resonance parameters of the dominant resonance coefficient of the decaying wave function. The above situation corresponds to an unexplored postexponential regime that represents the ultimate fate of a decaying particle.

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“…In practice, it suffices to take into account in Eq. ( 11) only a few terms from the poles p r and inverse power contributions to achieve satisfactory approximations, except for short times [49]. For details regarding the resonance expansion approach, see [10,16,23].…”

Section: Modelmentioning

confidence: 99%

Decay properties of unstable Tonks-Girardeau gases from a split trap

Kościk

2020

Preprint

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We study the decay properties of Tonks-Girardeau gases escaping from a double-well potential. Initially, the gases are constrained between two infinite delta barriers with an on-centre delta-split potential. The height of one of the obstacles is suddenly lowered and the particles start to tunnel to the open space. Based on the resonance expansion method, we derive a closed-form approximate expression for the N -particle survival probability and demonstrate its effectiveness in both the exponential and non-exponential regimes. We predict a parity effect and provide physical insight into its nature at different stages of the time evolution. We conclude that only during short periods does the decay of many-particle states comply with an exponential law. The decay properties are dramatically affected by the presence of the split barrier. Our results shed new light on the mechanism of the decay process of unstable Tonks-Girardeau gases from single and double quantum wells.

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Analytical study of quadratic and nonquadratic short-time behavior of quantum decay

Cited by 16 publications

References 31 publications

Exact quantum decay of an interacting many-particle system: the Calogero–Sutherland model

Exact quantum decay of an interacting many-particle system: the Calogero–Sutherland model

Time-domain resonances and the ultimate fate of a decaying quantum state

Decay properties of unstable Tonks-Girardeau gases from a split trap

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