Response of the quantum ground state to a parametric drive

Ranjani Seshadri

doi:10.1016/j.physleta.2025.130369

Response of the quantum ground state to a parametric drive

Ranjani Seshadri

Research output: Contribution to journal › Article › peer-review

Abstract

The phenomenon of Parametric Resonance (PR) is very well studied in classical systems with one of the textbook examples being the stabilization of a Kapitza's pendulum in the inverted configuration when the suspension point is oscillated vertically. One important aspect that distinguishes between classical PR and ordinary resonance is that in the former, if the initial energy of the system is at its minimum (x˙=x=0), the system does not evolve. In a quantum system, however, even when the system is in the minimum energy (ground) state, the system has non-trivial evolution under PR due to the delocalized nature of the ground-state wavefunction. Here we study the evolution of such a system which exhibits a purely quantum effect with no classical analog. In particular, we focus on the quantum mechanical analog of PR by varying with time the parabolic potential i.e. the frequency of the quantum harmonic oscillator.

Original language	English
Article number	130369
Journal	Physics Letters, Section A: General, Atomic and Solid State Physics
Volume	539
DOIs	https://doi.org/10.1016/j.physleta.2025.130369
State	Published - 15 Apr 2025
Externally published	Yes

Keywords

Parametric resonance
Quantum harmonic oscillator

ASJC Scopus subject areas

General Physics and Astronomy

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10.1016/j.physleta.2025.130369

Cite this

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title = "Response of the quantum ground state to a parametric drive",

abstract = "The phenomenon of Parametric Resonance (PR) is very well studied in classical systems with one of the textbook examples being the stabilization of a Kapitza's pendulum in the inverted configuration when the suspension point is oscillated vertically. One important aspect that distinguishes between classical PR and ordinary resonance is that in the former, if the initial energy of the system is at its minimum (x˙=x=0), the system does not evolve. In a quantum system, however, even when the system is in the minimum energy (ground) state, the system has non-trivial evolution under PR due to the delocalized nature of the ground-state wavefunction. Here we study the evolution of such a system which exhibits a purely quantum effect with no classical analog. In particular, we focus on the quantum mechanical analog of PR by varying with time the parabolic potential i.e. the frequency of the quantum harmonic oscillator.",

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AB - The phenomenon of Parametric Resonance (PR) is very well studied in classical systems with one of the textbook examples being the stabilization of a Kapitza's pendulum in the inverted configuration when the suspension point is oscillated vertically. One important aspect that distinguishes between classical PR and ordinary resonance is that in the former, if the initial energy of the system is at its minimum (x˙=x=0), the system does not evolve. In a quantum system, however, even when the system is in the minimum energy (ground) state, the system has non-trivial evolution under PR due to the delocalized nature of the ground-state wavefunction. Here we study the evolution of such a system which exhibits a purely quantum effect with no classical analog. In particular, we focus on the quantum mechanical analog of PR by varying with time the parabolic potential i.e. the frequency of the quantum harmonic oscillator.

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Response of the quantum ground state to a parametric drive

Abstract

Keywords

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