PPLN Frequency-Doubling Project - PowerPoint PPT Presentation

About This Presentation
Title:

PPLN Frequency-Doubling Project

Description:

... in nonlinear optics (periodic poling, new crystal types), we can efficiently ... for the Fabry-Perot (based on PZTs) is thus ... Crystal Temperature Scan ... – PowerPoint PPT presentation

Number of Views:86
Avg rating:3.0/5.0
Slides: 12
Provided by: DianaS81
Category:

less

Transcript and Presenter's Notes

Title: PPLN Frequency-Doubling Project


1
PPLN Frequency-Doubling Project
  • Diana Parno
  • Hall A Parity Collaboration Meeting
  • May 17, 2007

2
Green Laser Upgrade
  • The 100 mW commercial green laser is problematic
  • Not enough power
  • May be unreliable over time (it spent the fall
    with the manufacturer for extended repairs)
  • Possible solution Use nonlinear optics to build
    a higher-power, more reliable green laser.

3
Second Harmonic Generation
  • The pump wave generates a polarization inside a
    nonlinear optical crystal oscillating at twice
    the pump frequency.
  • The nonlinear polarization radiates an EM wave
    with twice the pump frequency. This second
    harmonic propagates in the same direction.
  • With advances in nonlinear optics (periodic
    poling, new crystal types), we can efficiently
    convert a reliable infrared laser to a reliable
    green one.

4
Periodic Poling
  • Second harmonic generation (SHG) depends on the
    phase difference f
  • flt180 Energy transfers from pump to 2nd
    harmonic
  • fgt180 Energy transfers from 2nd harmonic to
    pump
  • Without phase matching, SHG intensity oscillates
    with a low amplitude over the crystal length
  • Periodic poling induces a 180 phase shift in the
    2nd harmonic at every domain reversal, so that
    SHG is efficient over the entire crystal length

5
Single-Pass SHG
  • Why not use a powerful (several Watt) commercial
    green laser?
  • NdYAG lasers are converted to 532 nm through SHG
  • These lasers lock to secondary cavities for
    multiple passes through the crystal
  • Our fast feedback scheme for the Fabry-Perot
    (based on PZTs) is thus impossible for these
    lasers
  • Single-pass SHG allows us to achieve efficient
    locking to the Fabry-Perot cavity for Compton
    polarimetry

6
SHG Apparatus
  • The pump infrared beam must be carefully steered
    and focused into the SHG crystal (periodically
    poled lithium niobate PPLN)

Prism
Dichroic mirror
Infrared laser (1064 nm, 700 mW)
SHG crystal (inside oven)
Steering mirror
Steering mirror
Half-wave plate
Lenses
7
SHG Achievements
  • We have achieved 10-15 mW of green power with a
    700-mW infrared input
  • Optimal phase-matching temperature is 62C
  • Changes in alignment, polarization and lasing
    temperature may also improve efficiency

8
Crystal Temperature Scan
  • We expect a well-defined temperature response
    symmetrical sidebands about a sharp peak

Gregory Miller, Stanford PhD thesis, 1998
  • For our crystal, poor temperature stability and
    resolution obscure the structure

9
Pump Power Scan
  • We expect a quadratic increase in SHG power as a
    function of pump power
  • The structure we see is significantly different
  • Possible temperature effects?
  • Scans taken 15 hours apart show a substantial
    difference our setup has clear stability
    problems

Possible peak
Turn-on
10
SHG Future Work
  • Design a more stable oven/temperature controller
    for the PPLN crystal
  • Improve separation of fundamental and
    second-harmonic beams
  • Fully characterize crystal response to changes in
    pump power and polarization, crystal temperature
  • Consider techniques for power amplification
  • Test a 5-W fiber amplifier with our seed laser
    this summer

11
Thank you!
Write a Comment
User Comments (0)
About PowerShow.com