Jump to Content
Your Recent History
View Cart
SUBSCRIPTIONS & PRICING
GENERAL INFORMATION
chapter 19, Slow and Fast Light
Table of Contents
Chapter Contents
- 19.1 Introduction
- 19.1.1 Phase velocity
- 19.1.2 Group velocity
- 19.1.3 Slow light, fast light, backward light, stopped light
- 19.2 Slow Light Based on Material Resonances
- 19.2.1 Susceptibility and the Kramers—Kronig relations
- 19.2.2 Resonance features in materials
- 19.2.3 Spatial compression
- 19.2.4 Two-level and three-level models
- 19.2.5 Electromagnetically induced transparency (EIT)
- 19.2.6 Coherent population oscillation (CPO)
- 19.2.7 Stimulated Brillouin and Raman scattering
- 19.2.8 Other resonance-based phenomena
- 19.3 Slow Light Based on Material Structure
- 19.3.1 Waveguide dispersion
- 19.3.2 Coupled-resonator structures
- 19.3.3 Band-edge dispersion
- 19.4 Additional Considerations
- 19.4.1 Distortion mitigation
- 19.4.2 Figures of merit
- 19.4.3 Theoretical limits of slow and fast light
- 19.4.4 Causality and the many velocities of light
- 19.5 Potential Applications
- 19.5.1 Optical delay lines
- 19.5.1.1 Optical network buffer for all-optical routing
- 19.5.1.2 Network resynchronization and jitter correction
- 19.5.1.3 Tapped delay lines and equalization filters
- 19.5.1.4 Optical memory and stopped light for coherent control
- 19.5.1.5 Optical image buffering
- 19.5.1.6 True time delay for radar and lidar
- 19.5.2 Enhancement of optical nonlinearities
- 19.5.2.1 Wavelength converter
- 19.5.2.2 Single-bit optical switching, optical logic, and other applications
- 19.5.3 Slow- and fast-light interferometry
- 19.5.3.1 Spectral sensitivity enhancement
- 19.5.3.2 White-light cavities
- References
Excerpt
19.1 Introduction
In early 1999, a news article in the prestigious journal Nature led off with the announcement, “An experiment with atoms at nanokelvin temperatures has produced the remarkable observation of light pulses traveling at velocities of only 17 m∕s.” The review continued with the understatement, “Observation of light pulses propagating at a speed no faster than a swiftly moving bicycle… comes as a surprise.” These findings (and their review) marked the beginning of the current wave of interest in the field that has come to be called “slow light.”
When we refer to “the speed of light,” we typically mean c, the phase velocity of light in a vacuum, or the speed of propagation of the phase fronts of monochromatic light. The phase fronts travel more slowly through a material, propagating at the speed c∕n, where n is the index of refraction of the medium. However, this ordinary slowing of the phase velocity is not slow light. “Slow light” and “fast light” refer to changes in the group velocity of light in a medium.
A pulse of light can be decomposed mathematically into a group of monochromatic waves at slightly different frequencies, as in Fig. 19.1. In a dispersive material, these monochromatic waves travel at different speeds. When one views the propagation of the pulse as a whole, its apparent velocity depends on the extent of the spread of individual monochromatic-wave velocities. Each monochromatic wave travels at its own phase velocity, while the pulse travels at the group velocity.
Of course, the group velocity of a pulse of light is not a new concept. The field of slow and fast light has drawn on theory and developments from the work of Sommerfeld and Brillouin from 1907 to 1914, experiments with early laser amplifiers in 1966, and other work done through the end of the 20th century. (For more of the history behind slow and fast light, see Refs. 8 and 9.)
©2009 Society of Photo-Optical Instrumentation Engineers
PURCHASE CHAPTER ($US18)
SPIE Digital Library
This Publication
Google Scholar
PubMed