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Laser Locking for Long-term Magneto-Optical Trap Stability

Laser Locking for Long-term Magneto-Optical Trap Stability. Kevin W. Vogel Advisor: Georg Raithel. Presented 07/28/04. Outline. Magneto-Optical Trap (MOT) Laser Locking Methods Dichroic Atomic Vapor Laser Locking MOT Improvements. Magneto-Optical Trap (MOT).

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Laser Locking for Long-term Magneto-Optical Trap Stability

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  1. Laser Locking for Long-term Magneto-Optical Trap Stability Kevin W. Vogel Advisor: Georg Raithel Presented 07/28/04

  2. Outline • Magneto-Optical Trap (MOT) • Laser Locking Methods • Dichroic Atomic Vapor Laser Locking • MOT Improvements

  3. Magneto-Optical Trap (MOT) • Capture and cool Rubidium atoms to μK temps • 6 orthogonal pairs of circularly polarized counter propagating laser beams • Anti-Helmholtz magnetic field

  4. 0 Volts ν Frequency Diode Laser Frequency Stabilization • Frequency changes due to temperature and diffraction grating position • Tuned to transition frequency • Locked with a feedback circuit

  5. 0 V 5 MHz 500 MHz 0 V Laser Locking Methods • Saturated Absorption Spectroscopy • Narrow locked frequency range • Easy to lose lock • Lock time: 10 – 60 min. • Dichroic Atomic Vapor Laser Locking (DAVLL) • Difficult to lose lock • Broader locked frequency range • Lock time: ?

  6. DAVLL Setup to MOT

  7. DAVLL Lock Signal • Transition shifted by Zeeman effect • Laser output is linearly polarized • Each circular polarization is absorbed by a shifted transition

  8. Improvements: • Low Noise Circuit • Produces differential absorption signal with minimal electrical noise • Temp Controlled Permanent Magnets • Permanent magnet field strength is temperature dependent • Keeps temp within ±0.003°C

  9. 14 hours! mode hops Results

  10. Other MOT Improvements • Permanent heater to clean Rubidium cell • Larger vacuum chamber cell to increase atom flow • Magnetic coils for larger cell • New laser grating and bracket

  11. Acknowledgments • Georg Raithel, Ramon Torres-Isea, Spencer Olson, Rahul Mhaskar, Tara Cubel, Aaron Reinhard, Natalya Morrow, Rui Zhang, Brenton Knuffman, Alisa Walz-Flannigan, Jae-Hoon Choi, Eberhard Hansis, Alex Povilus • NSF • Physics Department

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