Abstract
Abstract. Lidar technology has been rapidly advancing over the past several decades. It can be used to measure a variety of atmospheric constituents at very high temporal and spatial resolutions. While the number of lidars continues to increase worldwide, there is generally a dependency on an operator, particularly for high-powered lidar systems. Environment and Climate Change Canada (ECCC) has recently developed a fully autonomous, mobile lidar system called AMOLITE (Autonomous Mobile Ozone Lidar Instrument for Tropospheric Experiments) to simultaneously measure the vertical profile of tropospheric ozone, aerosol and water vapor (nighttime only) from near the ground to altitudes reaching 10 to 15 km. This current system uses a dual-laser, dual-lidar design housed in a single climate-controlled trailer. Ozone profiles are measured by the differential absorption lidar (DIAL) technique using a single 1 m Raman cell filled with CO2. The DIAL wavelengths of 287 and 299 nm are generated as the second and third Stokes lines resulting from stimulated Raman scattering of the cell pumped using the fourth harmonic of a Nd:YAG laser (266 nm). The aerosol lidar transmits three wavelengths simultaneously (355, 532 and 1064 nm) employing a detector designed to measure the three backscatter channels, two nitrogen Raman channels (387 and 607 nm) and one cross-polarization channel at 355 nm. In addition, we added a water vapor channel arising from the Raman-shifted 355 nm output (407 nm) to provide nighttime water vapor profiles. AMOLITE participated in a validation experiment alongside four other ozone DIAL systems before being deployed to the ECCC Oski-ôtin ground site in the Alberta oil sands region in November 2016. Ozone was found to increase throughout the troposphere by as much as a factor of 2 from stratospheric intrusions. The dry stratospheric air within the intrusion was measured to be less than 0.2 g kg−1. A biomass burning event that impacted the region over an 8-day period produced lidar ratios of 35 to 65 sr at 355 nm and 40 to 100 sr at 532. Over the same period the Ångström exponent decreased from 1.56±0.2 to 1.35±0.2 in the 2–4 km smoke region.
Highlights
Tropospheric ozone, aerosols and water vapor are important atmospheric constituents affecting air quality and climate
Strawbridge et al.: A fully autonomous ozone, aerosol and nighttime water vapor lidar dar (DIAL) is the ability to measure this vertical column with high enough temporal resolution to understand atmospheric mixing and exchange processes
The AMOLITE instrument uses three different lidar techniques to measure different atmospheric constituents: a Mie backscatter lidar to measure the vertical profile of aerosol at three different wavelengths, a differential absorption lidar (DIAL) to measure the vertical ozone profile and a Raman lidar to measure the water vapor profile
Summary
Tropospheric ozone, aerosols and water vapor are important atmospheric constituents affecting air quality and climate. In addition to the lidar measurements, operation of a windRASS (wind radioacoustic sounding system – model MFAS, Scintec, Rottenburg, Germany) provides the local meteorological wind fields at 10 m vertical resolution from 40 to typically 500 m above ground, directly determining the upwind sources near ground level and aloft over the site. These remote sensors provide a coherent 3-D picture of the transport processes impacting the ground site and the region nearby.
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