Quantum Geometric Phases as a New Window on Gravitational Waves
- URL: http://arxiv.org/abs/2508.05881v3
- Date: Wed, 13 Aug 2025 21:10:21 GMT
- Title: Quantum Geometric Phases as a New Window on Gravitational Waves
- Authors: Partha Nandi, Frederik G. Scholtz,
- Abstract summary: Low-frequency gravitational waves induce purely quantum geometric phases in mesoscopic optomechanical systems.<n>We propose a Ramsey-type interferometric protocol in which the photon-number states of a quantized optical mode become entangled with the mirror's center-of-mass motion.<n>This framework establishes a distinctly quantum approach for probing low-frequency gravitational wave modes, offering an alternative to conventional detection strategies based on spacetime strain.
- Score: 0.49157446832511503
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We investigate how low-frequency gravitational waves (LFGWs), originating from distant astrophysical or cosmological sources, can induce purely quantum geometric phases in mesoscopic optomechanical systems. These phases represent subtle imprints with no classical counterpart, going beyond standard dynamical or Berry-type contributions that admit Hannay-angle analogues. Such ultra-weak waves couple to the motion of a mechanical mirror and generate distinctive phase shifts in the system's quantum state that cannot arise in any classical description. To access this effect, we propose a Ramsey-type interferometric protocol in which the photon-number states of a quantized optical mode become entangled with the mirror's center-of-mass motion, enabling a direct readout of the LFGW-induced geometric phase. This framework establishes a distinctly quantum approach for probing low-frequency gravitational wave modes, offering an alternative to conventional detection strategies based on spacetime strain.
Related papers
- Gravitational wave detection via photon-graviton scattering and quantum interference [0.0]
We present a fully quantum field-theoretic framework for gravitational wave (GW) detection.<n>In this picture, the GW acts as a coherent background that induces inelastic energy exchanges with the electromagnetic field.<n>We show that the scattering-induced phase shifts render frequency-entangled photon pairs distinguishable.
arXiv Detail & Related papers (2026-01-28T12:47:27Z) - Nonlinear dynamical Casimir effect and Unruh entanglement in waveguide QED with parametrically modulated coupling [83.88591755871734]
We study theoretically an array of two-level qubits moving relative to a one-dimensional waveguide.
When the frequency of this motion approaches twice the qubit resonance frequency, it induces parametric generation of photons and excitation of the qubits.
We develop a comprehensive general theoretical framework that incorporates both perturbative diagrammatic techniques and a rigorous master-equation approach.
arXiv Detail & Related papers (2024-08-30T15:54:33Z) - Quantum theory of orbital angular momentum in spatiotemporal optical vortices [0.0]
STOVs are structured electromagnetic fields propagating in free space with phase singularities in the space-time domain.
We develop a quantum theory for STOVs with an arbitrary tilt, extending beyond the paraxial limit.
Our findings represent a step towards the exploitation of quantum effects of structured light for various applications.
arXiv Detail & Related papers (2024-03-02T01:03:00Z) - Finite Pulse-Time Effects in Long-Baseline Quantum Clock Interferometry [45.73541813564926]
We study the interplay of the quantum center-of-mass $-$ that can become delocalized $-$ together with the internal clock transitions.
We show at the example of a Gaussian laser beam that the proposed quantum-clock interferometers are stable against perturbations from varying optical fields.
arXiv Detail & Related papers (2023-09-25T18:00:03Z) - Macroscopic quantum entanglement between an optomechanical cavity and a
continuous field in presence of non-Markovian noise [10.363406065066538]
We develop a framework to quantify the amount of entanglement in the system numerically.
We apply our framework to the case of the Advanced Laser Interferometer Gravitational-Wave Observatory.
arXiv Detail & Related papers (2023-09-21T23:10:29Z) - Controlling topological phases of matter with quantum light [0.0]
Controlling the topological properties of quantum matter is a major goal of condensed matter physics.
We consider a prototypical model for topological phase transition, the one-dimensional Su-Schrieffer-Heeger (SSH) model, coupled to a single mode cavity.
We show that depending on the lattice geometry and the strength of light-matter coupling one can either turn a trivial phase into a topological one or viceversa.
arXiv Detail & Related papers (2022-04-12T16:27:10Z) - Quantum structured light: Non-classical spin texture of twisted
single-photon pulses [8.19841678851784]
A framework for the quantum density of spin and OAM for single-photons remains elusive.
We develop a theoretical framework and put forth the concept of quantum structured light for space-time wavepackets at the single-photon level.
Our work paves the way for quantum spin-OAM physics in twisted single photon pulses.
arXiv Detail & Related papers (2021-02-26T01:08:57Z) - Spin Entanglement and Magnetic Competition via Long-range Interactions
in Spinor Quantum Optical Lattices [62.997667081978825]
We study the effects of cavity mediated long range magnetic interactions and optical lattices in ultracold matter.
We find that global interactions modify the underlying magnetic character of the system while introducing competition scenarios.
These allow new alternatives toward the design of robust mechanisms for quantum information purposes.
arXiv Detail & Related papers (2020-11-16T08:03:44Z) - Waveguide quantum optomechanics: parity-time phase transitions in
ultrastrong coupling regime [125.99533416395765]
We show that the simplest set-up of two qubits, harmonically trapped over an optical waveguide, enables the ultrastrong coupling regime of the quantum optomechanical interaction.
The combination of the inherent open nature of the system and the strong optomechanical coupling leads to emerging parity-time (PT) symmetry.
The $mathcalPT$ phase transition drives long-living subradiant states, observable in the state-of-the-art waveguide QED setups.
arXiv Detail & Related papers (2020-07-04T11:02:20Z) - Hyperentanglement in structured quantum light [50.591267188664666]
Entanglement in high-dimensional quantum systems, where one or more degrees of freedom of light are involved, offers increased information capacities and enables new quantum protocols.
Here, we demonstrate a functional source of high-dimensional, noise-resilient hyperentangled states encoded in time-frequency and vector-vortex structured modes.
We generate highly entangled photon pairs at telecom wavelength that we characterise via two-photon interference and quantum state tomography, achieving near-unity visibilities and fidelities.
arXiv Detail & Related papers (2020-06-02T18:00:04Z) - Quantum Hall phase emerging in an array of atoms interacting with
photons [101.18253437732933]
Topological quantum phases underpin many concepts of modern physics.
Here, we reveal that the quantum Hall phase with topological edge states, spectral Landau levels and Hofstadter butterfly can emerge in a simple quantum system.
Such systems, arrays of two-level atoms (qubits) coupled to light being described by the classical Dicke model, have recently been realized in experiments with cold atoms and superconducting qubits.
arXiv Detail & Related papers (2020-03-18T14:56:39Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.