1 / 11

Tunable Slow Light in Cesium Vapor

2. Slow light. Goal: obtain large pulse delays for high-bandwidth pulsesThe group velocity of a pulse is given by: We can obtain exceptional pulse propagation speeds in spectral regions where refractive index changes rapidly with frequency (high dispersion).We desire a region where dn/dw is la

jesimae
Download Presentation

Tunable Slow Light in Cesium Vapor

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


    1. 1 Tunable Slow Light in Cesium Vapor Aaron Schweinsberg, Ryan M. Camacho, Michael V. Pack, Robert W. Boyd, and John C. Howell The Institute of Optics, University of Rochester, Rochester, NY 14627 Frontiers in Optics Wednesday, October 11, 2006

    2. 2 Slow light Goal: obtain large pulse delays for high-bandwidth pulses The group velocity of a pulse is given by: We can obtain exceptional pulse propagation speeds in spectral regions where refractive index changes rapidly with frequency (high dispersion). We desire a region where dn/dw is large, but also constant over the bandwidth of the pulse.

    3. 3 Slow light in atomic vapors Need dn/dw large, over a large bandwidth. This condition can be met in the region between the absorption resonances of the ground-state hyperfine levels in an atomic vapor. Working far from resonance, we find that pulse distortion is dominated by group velocity dispersion, rather than absorption.

    4. 4 Theory (cont.) (a) - absorption spectrum showing ~10 GHz ground state hyperfine splitting in cesium (can accommodate wide bandwidth pulses) (b) - associated index profile and group velocity

    5. 5 Experimental Setup 852-nm diode laser is tuned between the hyperfine resonances. Density of cesium atoms in the cell controlled by heater Delay can also be tuned by application of resonant pump beams

    6. 6 Pulse delay through cesium vapor Delay adjusted by changing cell temperature. Temperatures ranged from 90° C to 120° C. 275 ps pulses delayed by up to 25 times the input pulse duration. Useful delay limited by dispersive broadening.

    7. 7 Delay through cesium (740 ps input) There is a trade-off between broadening and delay. If we allow only minimal broadening, fractional delay can be greater for longer input pulses. 740 ps pulses can be delayed up to 80 times their initial width! Three 10-cm Cs cells were used in series. Temperatures ranged from 110° C to 160° C.

    8. 8 Measurements of broadening Broadening data for delayed 740 ps pulses Fractional broadening, defined as (T - T0) / T0, never exceeds 0.6. Useful delay is likely to be limited by the reduction of the peak pulse height due to dispersive broadening.

    9. 9 Rapid tuning of the delay Delay can be tuned by applying strong pump fields directly to the resonances. Optical pumping reduces the effective number density of Cs atoms seen by the signal. Used a 80 MHz AOM to turn two resonant 30 mW pump beams on and off Delay of a pair of 275 ps pulses altered by 1 ns, equal in this case to the initial pulse separation. (one bit slot)

    10. 10 Measuring the switching speed Pump turn-on time of 100 ns (as switched by AOM) Reconfiguration of delay takes place over ~ 700 ns. Higher pump powers could reduce reconfiguration time.

    11. 11 Summary

    12. 12 Outline Theory of slow light in cesium vapor Large delay of high-bandwidth pulses The effects of pulse broadening Tuning the pulse delay Conclusion

More Related