Quick Navigation

Topics

Quantum Algorithms

Photon creation in a resonant cavity with a nonstationary plasma mirror and its detection with Rydberg atoms

arXiv
Authors: Toru Kawakubo, Katsuji Yamamoto

Year

2010

Paper ID

10492

Status

Preprint

Abstract Read

~2 min

Abstract Words

111

Citations

N/A

Abstract

We investigate the dynamical Casimir effect and its detection with Rydberg atoms. The photons are created in a resonant cavity with a plasma mirror of a semiconductor slab which is irradiated by periodic laser pulses. The canonical Hamiltonian is derived for the creation and annihilation operators showing the explicit time-variation in the couplings, which originates from the external configuration such as a nonstationary plasma mirror. The number of created photons is evaluated as squeezing from the Heisenberg equations with the Hamiltonian. Then, the detection of the photons as the atomic excitations is examined through the atom-field interaction. Some consideration is made for a feasible experimental realization with a semiconductor plasma mirror.

Why This Paper Matters

  • It adds a 2010 reference point for readers tracking recent quantum research.
  • We investigate the dynamical Casimir effect and its detection with Rydberg atoms.

Paper Tools

Become a member to use research tools

Sign in to open papers, visit source links, share, cite, compare, copy DOI links, request category corrections, and build your reading list.

Show Paper arXiv Publisher Share Cite This Paper Copy URL Compare Copy DOI Add to Reading List Category Correction Request

References & Citation Signals

Local Citation Graph (Related-Paper Links)

Current Paper #10492 #69983 Spectral Leakage and Masking Ef... #69982 Dimensionality Reduction of QAO... #69981 A Hybrid Quantum-Classical Appr... #69980 Complexity Inequalities for Qua...

External citation index: OpenAlex citation signal

Community Reactions

Quick sentiment from readers on this paper.

Score: 0
Likes: 0 Dislikes: 0

Sign in to react to this paper.

Discussion & Reviews (Moderated)

Average Rating: 0.0 / 5 (0 ratings)

No written reviews yet.