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Development and testing of a frequency-agile optical parametric oscillator system for differential absorption lidar

Weibring, Petter LU ; Smith, JN ; Edner, Hans LU and Svanberg, Sune LU (2003) In Review of Scientific Instruments 74(10). p.4478-4484
Abstract
An all-solid-state fast-tuning lidar transmitter for range- and temporally resolved atmospheric gas concentration measurements has been developed and thoroughly tested. The instrument is based on a commercial optical parametric oscillator (OPO) laser system, which has been redesigned with piezoelectric transducers mounted on the wavelength-tuning mirror and on the crystal angle tuning element in the OPO. Piezoelectric transducers similarly control a frequency-mixing stage and doubling stage, which have been incorporated to extend system capabilities to the mid-IR and UV regions. The construction allows the system to be tuned to any wavelength, in any order, in the range of the piezoelectric transducers on a shot-to-shot basis. This extends... (More)
An all-solid-state fast-tuning lidar transmitter for range- and temporally resolved atmospheric gas concentration measurements has been developed and thoroughly tested. The instrument is based on a commercial optical parametric oscillator (OPO) laser system, which has been redesigned with piezoelectric transducers mounted on the wavelength-tuning mirror and on the crystal angle tuning element in the OPO. Piezoelectric transducers similarly control a frequency-mixing stage and doubling stage, which have been incorporated to extend system capabilities to the mid-IR and UV regions. The construction allows the system to be tuned to any wavelength, in any order, in the range of the piezoelectric transducers on a shot-to-shot basis. This extends the measurement capabilities far beyond the two-wavelength differential absorption lidar method and enables simultaneous measurements of several gases. The system performance in terms of wavelength, linewidth, and power stability is monitored in real time by an etalon-based wave meter and gas cells. The tests showed that the system was able to produce radiation in the 220-4300-nm-wavelength region, with an average linewidth better than 0.2 cm(-1) and a shot-to-shot tunability up to 160 cm(-1) within 20 ms. The utility of real-time linewidth and wavelength measurements is demonstrated by the ability to identify occasional poor quality laser shots and disregard these measurements. Also, absorption cell measurements of methane and mercury demonstrate the performance in obtaining stable wavelength and linewidth during rapid scans in the mid-IR and UV regions. (Less)
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author
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organization
publishing date
type
Contribution to journal
publication status
published
subject
in
Review of Scientific Instruments
volume
74
issue
10
pages
4478 - 4484
publisher
American Institute of Physics (AIP)
external identifiers
  • wos:000185844800037
  • scopus:0142260410
ISSN
1089-7623
DOI
10.1063/1.1599065
language
English
LU publication?
yes
id
4fd419d2-e5d5-4409-9074-9cdfaec08e6c (old id 298251)
date added to LUP
2016-04-01 16:54:06
date last changed
2022-01-28 22:55:48
@article{4fd419d2-e5d5-4409-9074-9cdfaec08e6c,
  abstract     = {{An all-solid-state fast-tuning lidar transmitter for range- and temporally resolved atmospheric gas concentration measurements has been developed and thoroughly tested. The instrument is based on a commercial optical parametric oscillator (OPO) laser system, which has been redesigned with piezoelectric transducers mounted on the wavelength-tuning mirror and on the crystal angle tuning element in the OPO. Piezoelectric transducers similarly control a frequency-mixing stage and doubling stage, which have been incorporated to extend system capabilities to the mid-IR and UV regions. The construction allows the system to be tuned to any wavelength, in any order, in the range of the piezoelectric transducers on a shot-to-shot basis. This extends the measurement capabilities far beyond the two-wavelength differential absorption lidar method and enables simultaneous measurements of several gases. The system performance in terms of wavelength, linewidth, and power stability is monitored in real time by an etalon-based wave meter and gas cells. The tests showed that the system was able to produce radiation in the 220-4300-nm-wavelength region, with an average linewidth better than 0.2 cm(-1) and a shot-to-shot tunability up to 160 cm(-1) within 20 ms. The utility of real-time linewidth and wavelength measurements is demonstrated by the ability to identify occasional poor quality laser shots and disregard these measurements. Also, absorption cell measurements of methane and mercury demonstrate the performance in obtaining stable wavelength and linewidth during rapid scans in the mid-IR and UV regions.}},
  author       = {{Weibring, Petter and Smith, JN and Edner, Hans and Svanberg, Sune}},
  issn         = {{1089-7623}},
  language     = {{eng}},
  number       = {{10}},
  pages        = {{4478--4484}},
  publisher    = {{American Institute of Physics (AIP)}},
  series       = {{Review of Scientific Instruments}},
  title        = {{Development and testing of a frequency-agile optical parametric oscillator system for differential absorption lidar}},
  url          = {{https://lup.lub.lu.se/search/files/4813871/2370935.pdf}},
  doi          = {{10.1063/1.1599065}},
  volume       = {{74}},
  year         = {{2003}},
}