A versatile instrument with an optical parametric oscillator transmitter tunable from 1.5 to 3.1 μm for aerosol lidar and DIAL

Lidar is a valuable tool for atmospheric monitoring, allowing range-resolved profile measurements of a variety of quantities including aerosols, wind, pollutants and greenhouse gases. We report here the development of a versatile fielddeployable instrument for monitoring the lower troposphere. This region includes the effects of surface–atmosphere interactions and is an area where the resolution of satellite data is generally poor. Our instrument has been designed with the goal of making range-resolved measurements of greenhouse gases such as carbon dioxide, as well as probing the structure of the boundary layer. The key component is a tunable laser source based on an optical parametric oscillator covering the wavelength range 1.5–3.1 μm. This relatively eye-safe spectral region includes absorption lines of carbon dioxide and other greenhouse gases enabling the application of the differential absorption lidar (DIAL) technique, whilst also being suitable for aerosol lidar. We also report the use of an avalanche photodiode detector with high sensitivity and low noise. Field tests of the instrument were performed, recording continuous lidar signals over extended periods. The data were digitized at up to 8 signals per second. Scattering from aerosols and molecules was detected to a maximum range of 2 km, whilst scattering from cloud was recorded at up to 6 km. The data are plotted as time-versus-range images to show the dynamic state of the atmosphere evolving over time. These results demonstrate that the lidar achieves key requirements for both aerosol scatter and DIAL: tunability of the transmitter wavelength, sensitivity to molecular and aerosol scattering and robustness for field use.

[1]  E. David Hinkley,et al.  Laser monitoring of the atmosphere , 1976 .

[2]  Philip B. Russell,et al.  Lidar measurement of particles and gases by elastic backscattering and differential absorption , 1976 .

[3]  J. Monteith,et al.  Boundary Layer Climates. , 1979 .

[4]  Gérard Mégie,et al.  Laser Remote Sensing: Fundamentals and Applications , 1985 .

[5]  Noboru Yoshikane,et al.  Differential Absorption Lidar at 1.67 µm for Remote Sensing of Methane Leakage , 1999 .

[6]  Scott M Spuler,et al.  Raman-shifted eye-safe aerosol lidar. , 2004, Applied optics.

[7]  Jens Bösenberg,et al.  Differential-Absorption Lidar for Water Vapor and Temperature Profiling , 2005 .

[8]  C. Weitkamp Lidar, Range-Resolved Optical Remote Sensing of the Atmosphere , 2005 .

[9]  Gang Li,et al.  The HITRAN 2008 molecular spectroscopic database , 2005 .

[10]  Valentin Simeonov,et al.  Trace Gas Species Detection in the Lower Atmosphere by Lidar: From Remote Sensing of Atmospheric Pollutants to Possible Air Pollution Abatement Strategies , 2005 .

[11]  P. Flamant,et al.  Two-micrometer heterodyne differential absorption lidar measurements of the atmospheric CO2 mixing ratio in the boundary layer. , 2006, Applied optics.

[12]  Melinda Marquis,et al.  Carbon Crucible , 2008, Science.

[13]  M. Wirth,et al.  Development of an OPO system at 1.57 μm for integrated path DIAL measurement of atmospheric carbon dioxide , 2008 .

[14]  J. Abshire,et al.  Pulsed Airborne Lidar Measurements of Atmospheric CO2 Column Absorption and Line Shapes from 3-13 km Altitudes , 2009 .

[15]  Daisuke Sakaizawa,et al.  Development of a 1.6 microm differential absorption lidar with a quasi-phase-matching optical parametric oscillator and photon-counting detector for the vertical CO2 profile. , 2009, Applied optics.

[16]  G. Somesfalean,et al.  Vertical lidar sounding of atomic mercury and nitric oxide in a major Chinese city , 2010 .

[17]  R. Vilar,et al.  Simple eye-safe lidar for cloud height measurement and small forest fire detection , 2010 .

[18]  Michela Gelfusa,et al.  First open field measurements with a portable CO2 lidar/dial system for early forest fires detection , 2011, Remote Sensing.

[19]  Tamer F. Refaat,et al.  Backscatter 2-$\mu\hbox{m}$ Lidar Validation for Atmospheric $\hbox{CO}_{2}$ Differential Absorption Lidar Applications , 2011, IEEE Transactions on Geoscience and Remote Sensing.

[20]  Jeffrey R. Chen,et al.  Frequency stabilization of distributed-feedback laser diodes at 1572 nm for lidar measurements of atmospheric carbon dioxide. , 2011, Applied optics.

[21]  Fabrizio Innocenti,et al.  Infrared differential absorption Lidar (DIAL) measurements of hydrocarbon emissions. , 2011, Journal of environmental monitoring : JEM.

[22]  Kevin S Repasky,et al.  Micropulse differential absorption lidar for identification of carbon sequestration site leakage. , 2013, Applied optics.