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Laser Offset Stabilization for Terahertz (THz) Frequency Generation

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Laser Offset Stabilization for Terahertz (THz) Frequency Generation Kevin Cossel Dr. Geoff Blake California Institute of Technology – PowerPoint PPT presentation

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Title: Laser Offset Stabilization for Terahertz (THz) Frequency Generation


1
Laser Offset Stabilization for Terahertz (THz)
Frequency Generation
  • Kevin Cossel
  • Dr. Geoff Blake
  • California Institute of Technology

2
What is Terahertz Spectroscopy?
  • 1x1011-1x1013 Hz or 0.1-10 Terahertz (THz)
  • 3 - 300 cm-1
  • 3000 - 30 µm
  • Also known as far-infrared (FIR) or
    sub-millimeter spectroscopy
  • Study low-energy processes both in the laboratory
    and in remote sensing applications

3
Why study Thz region?
  • Many uses
  • High-resolution spectroscopy
  • Vibration-rotation coupling
  • Lower spectral density expected
  • Remote sensing
  • Astronomy
  • Matched to emission from cold dust clouds
  • Characterize organic material (especially amino
    acids) present in the interstellar medium
  • Lower spectral density expected
  • SOFIA Herschel
  • Need lab data first

4
THz sources
  • Existing sources have problems
  • Solid-state electronic oscillators
  • Power drops above 200 MHz
  • Doubling/tripling not good above 1 THz
  • Lasers
  • Low frequency long lifetime, no direct bandgap
    lasers
  • Quantum cascade lasers gt3 THz, 10 Kelvin,
    narrow tunability
  • THz Time Domain Spectroscopy
  • Probe with sub-picosecond pulses
  • Gate detector with laser
  • Limited resolution
  • Optical-heterodyne

5
Purpose
  • Develop a spectrometer that can be used to
    characterize the spectra of molecules in the
    range of 0.5-10 Terahertz (THz)
  • Need THz source
  • Inexpensive
  • Multiterahertz bandwidth
  • Accurate
  • Low linewidth (lt10 MHz)
  • High-stability

6
Frequency Modulation
Whats happening?
Change current change laser frequency
The same as adding frequency components
Then scan the laser
7
Frequency Modulation Spectroscopy of HDO
8
Diode laser locking
  • Use feedback to reduce wavelength fluctuations
    (reduce linewidth)
  • FMS signal is error signal
  • Negative error increases wavelength
  • Use PID controller
  • Feedback P I D
  • P proportional to error signal
  • I integrate error (remove offset)
  • D derivative (anticipate movement)

Locking Range
0
Error
Wavelength
9
Tunable locking
  • Lock laser 1 to HDO line
  • Generate offset between laser 1 and laser 2
  • Lock offset
  • Lock laser 3 to different HDO line
  • Output is difference between laser 2 laser 3
  • Narrow tune offset
  • Wide tune lock to different lines

10
FMS Locking
  • Electro-optic modulator provides frequency
    modulation
  • Photodetector varying intensity beat note
  • Mix with driving RF DC output
  • Feedback DC error signal to PID controller
  • Controls piezo which adjust wavelength

11
Offset Locking
  • Laser 1 locked to HDO
  • Lasers 1 and 2 combined on fast (40 GHz)
    photodetector
  • Output difference frequency
  • Mix with tunable RF source Output 0-1 GHz
  • Send to source locking counter
  • Feedback to laser 2, offset locking up to 20 GHz

12
Results FMS locking
  • 2 hours
  • Free-running (blue)
  • 47 MHz standard deviation
  • 4.9 MHz RMSE
  • 2 MHz/second drift
  • Locked (red)
  • Mean 20 kHz
  • 3.5 MHz standard deviation
  • 5x10-5 MHz/second drift
  • 10 seconds
  • Free-running (blue)
  • 30 MHz peak-peak deviations
  • 5.5 MHz standard deviation
  • Locked (red)
  • 10 MHz peak-peak
  • 3 MHz standard deviation

13
Results Offset locking
  • Difference frequency
  • Two free-running (blue, left)
  • 300 MHz drift
  • 5 MHz RMSE
  • One laser PID locked (red)
  • PID offset locking
  • 1.3 MHz standard deviation (over 75 seconds)
  • Mean accurate to 260 kHz
  • lt1x10-6 MH/second drift (stable for 15 hours)

14
Discussion
  • Currently
  • PID lock
  • 20 kHz accuracy
  • 3 MHz linewidth
  • Low drift
  • Offset (Lasers 1 2)
  • 20 GHz (easily changed to 40 GHz)
  • 300 kHz accuracy
  • Very stable
  • High spectral density of HDO
  • Predicted gt3 THz bandwidth, 8 MHz linewidth, 300
    kHz accuracy
  • Work to lower linewidth/improve accuracy

15
Conclusion
  • Developed a technique for generating a tunable
    THz difference between two lasers with a final
    linewidth of lt10 MHz
  • Combine lasers on ErAs/InGaAs photomixer to
    generate THz radiation
  • Other techniques could provide higher stability
    at the cost of tunability or wide bandwidth but
    limited resolution
  • Compromise system
  • Working on improving linewidth (hopefully 1 MHz)
    and bandwidth (up to 15 THz)
  • Tunability/linewidth combination already useful
    for spectroscopy (developing Fourier transform
    terahertz spectrometer)

16
Acknowledgements
Dr. Geoff Blake Rogier Braakman Matthew
Kelley Dan Holland NSF Grant
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