Author:
Gładysz Piotr,Pustelny Szymon,Słowik Karolina
Abstract
AbstractSuperluminal light propagation is typically accompanied by significant absorption that might prevent its observation in realistic samples. We propose an all-optical implementation exploiting the two-photon resonance in three-level media to overcome this problem. With several computational methods, we analyze three possible configurations of optically-dressed systems and identify an optimal configuration for superluminal propagation. Due to the far-detuned operating regime with low absorption, this scenario avoids the usual need for population inversion, gain assistance or nonlinear optical response. Our analysis covers a broad parameter space and aims for the identification of conditions where significant pulse advancement can be achieved at high transmission levels. In this context, a figure of merit is introduced accounting for a trade-off between the desired group-index values and transmission level. This quantity helps to identify the optimal characteristics of the dressing beam.
Funder
Narodowe Centrum Nauki
Narodowe Centrum Badań i Rozwoju
Publisher
Springer Science and Business Media LLC
Reference49 articles.
1. Rayleigh, J. W. S. B. The collected optics papers of Lord Rayleigh (Optical Society of America, 1994).
2. Sommerfeld, A. & Brillouin, L. Wave propagation and group velocity (1960).
3. Born, M. & Wolf, E. Principles of optics, 7th (expanded) edition. United Kingdom: Press Syndicate of the University of Cambridge 461, 401–424 (1999).
4. Wicht, A., Rinkleff, R.-H., Molella, L. S. & Danzmann, K. Comparative study of anomalous dispersive transparent media. Physical Review A66, 063815 (2002).
5. Kasapi, A., Jain, M., Yin, G. & Harris, S. E. Electromagnetically induced transparency: propagation dynamics. Phys. Rev. Lett. 74, 2447 (1995).