 Comprehensive Assessment of Air Quality Dynamics Around Yosemite National Park Using Remote Sensing, GIS, and Computational Analysis During Wildfire EventsAmbreena Javaid ()
International Journal of Innovations in Science & Technology, 2024, vol. 6, issue 3, 1313-1327 Abstract: In recent years, Mariposa County has experienced several significant wildfires, including the catastrophic Rim Fire of 2013. On July 22, 2022, Yosemite National Park faced one of its most devastating wildfires, profoundly affecting Aerosol Optical Depth (AOD) and overall air quality. This study employs an integrated approach using remote sensing, GIS, and advanced computational tools to investigate the impact of these wildfires on air quality, focusing specifically on aerosol pollution dynamics and key atmospheric pollutants. The research leverages satellite data from TROPOMI, MODIS AQUA, and Suomi NPP/VIIRS, along with meteorological inputsfrom GDAS. Data processing and analysis were performed using Python, MATLAB, and R, with spatial mapping and visualization achieved through ArcMap and Google Earth Engine. The study utilized the MODIS MAIAC algorithm to conduct a detailed examination of AOD fluctuations in the Yosemite region, spanning from July 21 to August 1, 2022. Our comprehensive analysis reveals significant temporal and spatial variations in aerosol pollution during the wildfire. Initial findings indicate a marked increase in AOD with the onset of the wildfire, reflecting severe impacts on atmospheric composition. Pre-fire AOD levels were relatively low at 0.12, but surged to 0.20 at the wildfire's peak, demonstrating a substantial rise in atmospheric aerosol loading. The average AOD throughout the study period was recorded at 0.16, highlighting the wildfire's prolonged effect on air quality. Furthermore, the study identifies elevated concentrations of key pollutants, including NO₂, SO₂, CO, HCHO, and O₃, during the wildfire event. Theintegration of data from various satellite sources and the application of machine learning models provided a more nuanced understanding of pollution patterns. The HYSPLIT model was also employed to track the distribution of air masses and contaminants, revealing significant northwestward transport. This research advances our understanding of the intricate relationships between wildfires, aerosol pollution, and air quality in Yosemite National Park. The findings offer critical insights for public health preparedness, the development of resilience strategies against wildfires, and the formulation of effective mitigation measures in fire-prone regions like Yosemite. Keywords: Air pollution; Wildfire; AOD; Yosemite National Park (search for similar items in EconPapers) Downloads: (external link) Related works: Export reference: BibTeX RIS (EndNote, ProCite, RefMan) HTML/Text Persistent link: https://EconPapers.repec.org/RePEc:abq:ijist1:v:6:y:2024:i:3:p:1313-1327 Access Statistics for this article International Journal of Innovations in Science & Technology is currently edited by Prof. Dr. Syed Amer Mahmood More articles in International Journal of Innovations in Science & Technology from 50sea |
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