Mathematical Models for Unstable Quantum Systems and Gamow States

Gadella, M.; Fortín, Sebastián; Jorge, Juan Pablo; Losada, Marcelo

doi:10.3390/e24060804

Cited by 5 publications

(4 citation statements)

References 125 publications

(190 reference statements)

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“…The rejection of collapse does not necessarily lead to unitary dynamics. For example, the idea of describing non-unitary dynamics without appealing to collapse was studied extensively by I. Prigogine and the Brussels–Austin school [ 52 , 53 ] (related to this, see also [ 54 ], for a more recent review on quantum unstable systems). However, in the philosophy of physics community, the irreversible approaches are usually not taken into account, favoring alternatives that appeal to unitary evolutions only.…”

Section: The Ideas Behind Quantum Probabilitymentioning

confidence: 99%

Non-Kolmogorovian Probabilities and Quantum Technologies

Holik

2022

Entropy

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In this work, we focus on the philosophical aspects and technical challenges that underlie the axiomatization of the non-Kolmogorovian probability framework, in connection with the problem of quantum contextuality. This fundamental feature of quantum theory has received a lot of attention recently, given that it might be connected to the speed-up of quantum computers—a phenomenon that is not fully understood. Although this problem has been extensively studied in the physics community, there are still many philosophical questions that should be properly formulated. We analyzed different problems from a conceptual standpoint using the non-Kolmogorovian probability approach as a technical tool.

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Section: The Ideas Behind Quantum Probabilitymentioning

confidence: 99%

Non-Kolmogorovian Probabilities and Quantum Technologies

Holik

2022

Entropy

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“…The construction relies on some results of Mathematical Analysis that we do not want to mention here, since we do not want to involve the reader with mathematical details that, although important, distract from the objective of this presentation. They will be published in a forthcoming paper [43].…”

Section: The Algebra Of Observables and The Statesmentioning

confidence: 99%

Averages of observables on Gamow states

Gadella

Millán

2022

Communications Faculty of Sciences University of Ankara Series A2-A3 Physical Sciences and Engineering

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We propose a formulation of Gamow states, which is the part of unstable quantum states that decays exponentially, with two advantages in relation with the usual formulation of the same concept using Gamow vectors. The first advantage is that this formulation shows that Gamow states cannot be pure states, so that they may have a non-zero entropy. The second is thepossibility of correctly defining averages of observables on Gamow states.

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“…Perhaps the simplest one-dimensional quantum mechanical model possessing quasi-stationary (resonance) states, decaying via tunneling leakage, is the double rectangular potential barrier model [ Figure 1 a], which was introduced in a famous paper by Gamov to model

decay [ 7 ]. When the barrier height

is infinite, the system sustains a set of stationary (non-decaying) bound states at some quantized energies; however, when the barrier height

is not infinite, some of these states, those with energies close to the bottom of the barriers, become metastable, i.e., they become resonance states (also known as Gamow or Siegert states, or quasi-bound states; see, e.g., [ 9 , 10 , 11 , 12 , 13 , 14 ] and references therein). This means that an initial wave function prepared in a bound state of the infinite barrier approximately maintains its shape but decays in time in a nearly exponential manner through tunneling leakage across the barriers, generating small-amplitude outgoing waves that spread outward the barrier region [ 9 , 10 , 11 ].…”

Section: Introductionmentioning

confidence: 99%

Accelerating Quantum Decay by Multiple Tunneling Barriers

Pinotti,

Longhi

2023

Entropy

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A quantum particle constrained between two high potential barriers provides a paradigmatic example of a system sustaining quasi-bound (or resonance) states. When the system is prepared in one of such quasi-bound states, the wave function approximately maintains its shape but decays in time in a nearly exponential manner radiating into the surrounding space, the lifetime being of the order of the reciprocal of the width of the resonance peak in the transmission spectrum. Naively, one could think that adding more lateral barriers would preferentially slow down or prevent the quantum decay since tunneling is expected to become less probable and due to quantum backflow induced by multiple scattering processes. However, this is not always the case and in the early stage of the dynamics quantum decay can be accelerated (rather than decelerated) by additional lateral barriers, even when the barrier heights are arbitrarily large. The decay acceleration originates from resonant tunneling effects and is associated to large deviations from an exponential decay law. We discuss such a counterintuitive phenomenon by considering the hopping dynamics of a quantum particle on a tight-binding lattice with on-site potential barriers.

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Mathematical Models for Unstable Quantum Systems and Gamow States

Cited by 5 publications

References 125 publications

Non-Kolmogorovian Probabilities and Quantum Technologies

Non-Kolmogorovian Probabilities and Quantum Technologies

Averages of observables on Gamow states

Accelerating Quantum Decay by Multiple Tunneling Barriers

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