| 报告题目 | Quantum interface with atoms trapped near an optical nanofiber: dispersive response theory with applications to QND measurement and spin squeezing |
| 报告人 | 戚晓东 教授 |
| 报告人单位 | 美国新墨西哥大学Ivan H. Deutsch组 |
| 报告时间 | 2015-12-25 |
| 报告地点 | 合肥微尺度物质科学国家实验室九楼会议室(9004) |
| 主办单位 | 合肥微尺度物质科学国家实验室 |
| 报告介绍 | 报告摘要:
We study the strong coupling between photons and atoms that can be achieved in an optical nanofiber geometry when the interaction is dispersive. While the Purcell enhancement factor for spontaneous emission into the guided mode does not reach the strong-coupling regime for individual atoms, one can obtain high cooperativity for ensembles of a few thousand atoms due to the tight confinement of the guided modes and constructive interference over the entire chain of trapped atoms. We studied the theory of the phase shift and polarization rotation induced on the guided light by the trapped atoms using the dyadic Green's function method. The Green's function is related to a full Heisenberg-Langevin treatment of the dispersive response of the quantized field to tensor polarizable atoms. In this talk, I will illustrate how do we apply our formalism to quantum nondemolition (QND) measurement of the atoms via polarimetry. We study shot-noise-limited detection of atom number for atoms in a completely mixed spin state and the squeezing of projection noise for atoms in clock states. Compared with squeezing of atomic ensembles in free space, we capitalize on unique features that arise in the nanofiber geometry including anisotropy of both the intensity and polarization of the guided modes. We use a first principles stochastic master equation to model the squeezing as function of time in the presence of decoherence due to optical pumping. We find a peak metrological squeezing of ~5 dB is achievable with current technology for ~2500 atoms prepared in clock states trapped 180 nm from the surface of a nanofiber with radius a=225nm. The theory established can be used to guide the design of nanofiber- or waveguide-based quantum interfaces.
参考文献:
[1] X. Qi, B. Q. Baragiola, P. S. Jessen, I. H. Deutsch, arXiv:1509.02625 [quant-ph].
[2] S. T. Dawkins, R. Mitsch, D. Reitz, E. Vetsch, and A. Rauschenbeutel, Phys. Rev. Lett. 107, 243601 (2011).
[3] I. H. Deutsch and P. S. Jessen, Optics Communications 283, 681 (2010). |
