More Like this

1. Observing low-altitude features in ozone concentrations in a shoreline environment via uncrewed aerial systems

   https://doi.org/10.5194/amt-17-2833-2024  

   Radtke, Josie K; Kies, Benjamin N; Mottishaw, Whitney A; Zeuli, Sydney M; Voon, Aidan_T H; Koerber, Kelly L; Petty, Grant W; Vermeuel, Michael P; Bertram, Timothy H; Desai, Ankur R; et al (January 2024, Atmospheric Measurement Techniques)

   Abstract. Ozone is a pollutant formed in the atmosphere by photochemical processes involving nitrogen oxides (NOx) and volatile organic compounds (VOCs) when exposed to sunlight. Tropospheric boundary layer ozone is regularly measured at ground stations and sampled infrequently through balloon, lidar, and crewed aircraft platforms, which have demonstrated characteristic patterns with altitude. Here, to better resolve vertical profiles of ozone within the atmospheric boundary layer, we developed and evaluated an uncrewed aircraft system (UAS) platform for measuring ozone and meteorological parameters of temperature, pressure, and humidity. To evaluate this approach, a UAS was flown with a portable ozone monitor and a meteorological temperature and humidity sensor to compare to tall tower measurements in northern Wisconsin. In June 2020, as a part of the WiscoDISCO20 campaign, a DJI M600 hexacopter UAS was flown with the same sensors to measure Lake Michigan shoreline ozone concentrations. This latter UAS experiment revealed a low-altitude structure in ozone concentrations in a shoreline environment showing the highest ozone at altitudes from 20–100 m a.g.l. These first such measurements of low-altitude ozone via a UAS in the Great Lakes region revealed a very shallow layer of ozone-rich air lying above the surface. 

   more » « less
2. Investigations into lake breeze influence on ozone measurements at the Lake Michigan shoreline using an Unmanned Aerial System and LIDAR at Chiwaukee Prairie State Natural Area, Wisconsin

   Cleary, P.A. (December 2020, Transactions American Geophysical Union)

   The air quality at the Lake Michigan shoreline in southeastern Wisconsin is heavily influenced by the combination of Chicago area urban emissions and the meteorology over the lake. In June 2020, a multi-rotor DJI M600 Pro unmanned aerial system (UAS) equipped with a small ozone monitor (2B POM) and a meteorological sensor (iMET-XF) was flown on forecasted ozone exceedance days in the morning and evening to measure ozone, temperature, pressure and humidity profiles from 5-120 m AGL at the Chiwaukee Prairie State Natural Area in Southeastern Wisconsin. The Wisconsin DNR lakeshore air quality monitor at Chiwaukee Prairie in Kenosha, WI (AIRS ID 55-059-0019) sits 0.16 km from the shoreline and at the Wisconsin-Illinois boarder, near to where the UAS flights took place. The Chiwaukee Priaire monitoring station was equipped for an enhanced monitoring season, with a LIDAR Wind Profiler instrument. The combination of UAS measurements with the LIDAR meteorological measurements provide an understanding of the vertical structure in the meteorology of lake breeze and ozone during exceedance days. Temperature measurements aloft from the UAS show an atmospheric inversion at this site all sampling days (June 8, 9, 15-19). The ozone measurements trend with the temperature data, typically with higher ozone aloft than at the surface with a regular feature at 50-80 m AGL. We will discuss the results from the UAS with the LIDAR measurements to help understand the lake breeze influence on the local ozone measurements. 

   more » « less
3. Evaluating the performance of WRF in simulating winds and surface meteorology during a Southern California wildfire event

   https://doi.org/10.3389/feart.2023.1305124  

   Kumar, Mukesh; Kosović, Branko; Nayak, Hara P; Porter, William C; Randerson, James T; Banerjee, Tirtha (January 2024, Frontiers in Earth Science)

   The intensity and frequency of wildfires in California (CA) have increased in recent years, causing significant damage to human health and property. In October 2007, a number of small fire events, collectively referred to as the Witch Creek Fire or Witch Fire started in Southern CA and intensified under strong Santa Ana winds. As a test of current mesoscale modeling capabilities, we use the Weather Research and Forecasting (WRF) model to simulate the 2007 wildfire event in terms of meteorological conditions. The main objectives of the present study are to investigate the impact of horizontal grid resolution and planetary boundary layer (PBL) scheme on the model simulation of meteorological conditions associated with a Mega fire. We evaluate the predictive capability of the WRF model to simulate key meteorological and fire-weather forecast parameters such as wind, moisture, and temperature. Results of this study suggest that more accurate predictions of temperature and wind speed relevant for better prediction of wildfire spread can be achieved by downscaling regional numerical weather prediction products to 1 km resolution. Furthermore, accurate prediction of near-surface conditions depends on the choice of the planetary boundary layer parameterization. The MYNN parameterization yields more accurate prediction as compared to the YSU parameterization. WRF simulations at 1 km resolution result in better predictions of temperature and wind speed than relative humidity during the 2007 Witch Fire. In summary, the MYNN PBL parameterization scheme with finer grid resolution simulations improves the prediction of near-surface meteorological conditions during a wildfire event. 

   more » « less
4. Wind Profiling in the Lower Atmosphere from Wind-Induced Perturbations to Multirotor UAS

   https://doi.org/10.3390/s20051341  

   González-Rocha, Javier; De Wekker, Stephan F.; Ross, Shane D.; Woolsey, Craig A. (March 2020, Sensors)

   We present a model-based approach to estimate the vertical profile of horizontal wind velocity components using motion perturbations of a multirotor unmanned aircraft system (UAS) in both hovering and steady ascending flight. The state estimation framework employed for wind estimation was adapted to a set of closed-loop rigid body models identified for an off-the-shelf quadrotor. The quadrotor models used for wind estimation were characterized for hovering and steady ascending flight conditions ranging between 0 and 2 m/s. The closed-loop models were obtained using system identification algorithms to determine model structures and estimate model parameters. The wind measurement method was validated experimentally above the Virginia Tech Kentland Experimental Aircraft Systems Laboratory by comparing quadrotor and independent sensor measurements from a sonic anemometer and two SoDAR instruments. Comparison results demonstrated quadrotor wind estimation in close agreement with the independent wind velocity measurements. However, horizontal wind velocity profiles were difficult to validate using time-synchronized SoDAR measurements. Analysis of the noise intensity and signal-to-noise ratio of the SoDARs proved that close-proximity quadrotor operations can corrupt wind measurement from SoDARs, which has not previously been reported. 

   more » « less
5. Intercomparison of Small Unmanned Aircraft System (sUAS) Measurements for Atmospheric Science during the LAPSE-RATE Campaign

   https://doi.org/10.3390/s19092179  

   Barbieri, Lindsay; Kral, Stephan; Bailey, Sean; Frazier, Amy; Jacob, Jamey; Reuder, Joachim; Brus, David; Chilson, Phillip; Crick, Christopher; Detweiler, Carrick; et al (May 2019, Sensors)

   Small unmanned aircraft systems (sUAS) are rapidly transforming atmospheric research. With the advancement of the development and application of these systems, improving knowledge of best practices for accurate measurement is critical for achieving scientific goals. We present results from an intercomparison of atmospheric measurement data from the Lower Atmospheric Process Studies at Elevation—a Remotely piloted Aircraft Team Experiment (LAPSE-RATE) field campaign. We evaluate a total of 38 individual sUAS with 23 unique sensor and platform configurations using a meteorological tower for reference measurements. We assess precision, bias, and time response of sUAS measurements of temperature, humidity, pressure, wind speed, and wind direction. Most sUAS measurements show broad agreement with the reference, particularly temperature and wind speed, with mean value differences of 1.6 ± 2.6 ∘ C and 0.22 ± 0.59 m/s for all sUAS, respectively. sUAS platform and sensor configurations were found to contribute significantly to measurement accuracy. Sensor configurations, which included proper aspiration and radiation shielding of sensors, were found to provide the most accurate thermodynamic measurements (temperature and relative humidity), whereas sonic anemometers on multirotor platforms provided the most accurate wind measurements (horizontal speed and direction). We contribute both a characterization and assessment of sUAS for measuring atmospheric parameters, and identify important challenges and opportunities for improving scientific measurements with sUAS. 

   more » « less