Impact of Biomass Burning Plumes on Photolysis Rates and Ozone Formation at the Mount Bachelor Observatory

Baylon, P.; Jaffe, Daniel A.; Hall, Samuel R.; Ullmann, Kirk; Alvarado, M. J.; Lefer, B. L.

doi:10.1002/2017jd027341

Cited by 41 publications

(39 citation statements)

References 75 publications

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“…The compositing approach does not examine the case‐by‐case variability. Therefore, we do not explicitly examine other internal factors affecting the fire impact on air quality, such as the chemical evolution of fire‐emitted species and ozone precursors during the course of the plume transport and mixture of the fire emissions with urban pollution (Baylon et al, ). Future work is needed to improve our understanding of these aspects, which would require in situ measurements of the fire plumes as well as detailed modeling of the plume chemistry and small‐scale transport.…”

Section: Resultsmentioning

confidence: 99%

Transport of Central American Fire Emissions to the U.S. Gulf Coast: Climatological Pathways and Impacts on Ozone and PM_2.5

Wang

Estes

et al. 2018

JGR Atmospheres

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Fire emissions from Mexico and Central America are transported regularly to the U.S. Gulf Coast every spring under prevailing circulation patterns and affect U.S. air quality. Here we use a GEOS-Chem passive tracer simulation to develop the climatology of transport pathways of fire emissions over a long-term time period of April and May 2002-2015 and estimate their adverse air quality effects for urban areas along the Gulf Coast. A conceptual model is presented to describe the transport mechanisms, which involve southerly low-level jets in the lower troposphere and warm conveyor belt in the middle troposphere. The warm conveyor belts and the southerly low-level jets explain 31% and 69% of the interannual variability of the mid-altitude (1.5-6 km) and low-altitude events (0-1.5 km), respectively. Considering both transport and fire emissions, approximately 9% of the study period (59-88 days of 854 days) were identified as large pollution events during which Central American fire emissions adversely impacted surface air quality at several major urban centers along the Gulf Coast, including Houston and Corpus Christi in TX, New Orleans in LA, Mobile in AL, and Pensacola in FL. Compared to clean maritime flow from the Gulf of Mexico, these events were estimated to result in average enhancements of maximum daily average 8-hr (MDA8) ozone and daily PM 2.5 (fine particulate matter <2.5 μm in diameter) in the Gulf Coast cities of 3-12 ppbv and 2-5 μg/m 3 , respectively. Only one ozone exceedance day (79 ppbv, on 18 May 2003) was found among the fire-impact days for the Houston region.

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Section: Resultsmentioning

confidence: 99%

Transport of Central American Fire Emissions to the U.S. Gulf Coast: Climatological Pathways and Impacts on Ozone and PM_2.5

Wang

Estes

et al. 2018

JGR Atmospheres

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“…Increasing numbers of vehicles on the national highways provide three-dimensional corridors of smoke which contains oxides of nitrogen and black carbon. Subsequently, ground level ozone (O 3 ) is produced as a result of the photolysis of oxides of nitrogen by wavelengths less than 420 nm present in solar radiation in a rich environment of VOCs (Baylon et al, 2018), which is one of the primary species that can initiate Chronic Obstructive Pulmonary Disease (COPD) and Asthma due to its strong oxidative capacity. Thus, the possibility of COVID-19 susceptibility is much higher in those who are already exposed to oxidants in polluted areas.…”

Section: B Polluted Air Affecting Respiratory Functionalitymentioning

confidence: 99%

Potential link between compromised air quality and transmission of the novel corona virus (SARS-CoV-2) in affected areas

Manoj

Kumar

Valsaraj

et al. 2020

Environmental Research

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The emergence of a novel human corona virus disease (COVID-19) has been declared as a pandemic by the World Health Organization. One of the mechanisms of airborne transmission of the severe acute respiratory syndrome - corona virus ( SARS-CoV-2 ) amid humans is through direct ejection of droplets via sneezing, coughing and vocalizing. Nevertheless, there are ample evidences of the persistence of infectious viruses on inanimate surfaces for several hours to a few days. Through a critical review of the current literature and a preliminary analysis of the link between SARS-CoV-2 transmission and air pollution in the affected regions, we offer a perspective that polluted environment could enhance the transmission rate of such deadly viruses under moderate-to-high humidity conditions. The aqueous atmospheric aerosols offer a conducive surface for adsorption/absorption of organic molecules and viruses onto them, facilitating a pathway for higher rate of transmission under favourable environmental conditions. This mechanism partially explains the role of polluted air besides the exacerbation of chronic respiratory diseases in the rapid transmission of the virus amongst the public. Hence, it is stressed that more ambitious policies towards a cleaner environment are required globally to nip in the bud what could be the seeds of a fatal outbreak such as COVID-19.

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“…In addition to the pollutants directly emitted by fires, chemistry in smoke plumes can produce ozone (O 3 ), which can negatively impact human health (U.S. EPA, 2013) as well as affect vegetation, water quality, soil, and the ecosystems that they support (European Environmental Agency, 2018). O 3 formation can occur due to the emission of nitrogen dioxide (NO 2 ), HONO, and volatile organic compounds (VOCs) and the presence of sunlight (Baylon et al, 2018), with enhanced photolysis rates occurring most predominantly during midday, when photolysis rates are fastest. In 2012, the estimated median contribution of fires to maximum daily 8 h average (MDA8) O 3 in Texas during the month of June was 2 ppbv, with maximum impacts of over 40 ppbv (McDonald-Buller et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…Large uncertainties exist, however, in quantifying O 3 production, which stems from uncertainties in fire emissions, combustion efficiency, meteorological patterns, chemical and photochemical reactions, and the effects of aerosols on plume chemistry and photolysis rates. Aerosols have been shown to both increase O 3 formation (e.g., scattering particles can increase photolysis rates) as well as decrease O 3 (absorbing aerosol and black carbon-containing aerosol can reduce photolysis rates) (Baylon et al, 2018). Hence, the aerosol composition and size distribution, which varies within and between plumes (Collier et al, 2016), and the location of the aerosol within the plume (Alvarado et al, 2015) impact O 3 production.…”

Section: Introductionmentioning

confidence: 99%

Simulating the forest fire plume dispersion, chemistry, and aerosol formation using SAM-ASP version 1.0

et al. 2020

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Abstract. Biomass burning is a major source of trace gases and aerosols that can ultimately impact health, air quality, and climate. Global and regional-scale three-dimensional Eulerian chemical transport models (CTMs) use estimates of the primary emissions from fires and can unphysically mix them across large-scale grid boxes, leading to incorrect estimates of the impact of biomass burning events. On the other hand, plume-scale process models allow for explicit simulation and examination of the chemical and physical transformations of trace gases and aerosols within biomass burning smoke plumes, and they may be used to develop parameterizations of this aging process for coarser grid-scale models. Here we describe the coupled SAM-ASP plume-scale process model, which consists of coupling the large-eddy simulation model, the System for Atmospheric Modelling (SAM), with the detailed gas and aerosol chemistry model, the Aerosol Simulation Program (ASP). We find that the SAM-ASP version 1.0 model is able to correctly simulate the dilution of CO in a California chaparral smoke plume, as well as the chemical loss of NOx, HONO, and NH3 within the plume, the formation of PAN and O3, the loss of OA, and the change in the size distribution of aerosols as compared to measurements and previous single-box model results. The newly coupled model is able to capture the cross-plume vertical and horizontal concentration gradients as the fire plume evolves downwind of the emission source. The integration and evaluation of SAM-ASP version 1.0 presented here will support the development of parameterizations of near-source biomass burning chemistry that can be used to more accurately simulate biomass burning chemical and physical transformations of trace gases and aerosols within coarser grid-scale CTMs.

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Impact of Biomass Burning Plumes on Photolysis Rates and Ozone Formation at the Mount Bachelor Observatory

Cited by 41 publications

References 75 publications

Transport of Central American Fire Emissions to the U.S. Gulf Coast: Climatological Pathways and Impacts on Ozone and PM_2.5

Transport of Central American Fire Emissions to the U.S. Gulf Coast: Climatological Pathways and Impacts on Ozone and PM_2.5

Potential link between compromised air quality and transmission of the novel corona virus (SARS-CoV-2) in affected areas

Simulating the forest fire plume dispersion, chemistry, and aerosol formation using SAM-ASP version 1.0

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Impact of Biomass Burning Plumes on Photolysis Rates and Ozone Formation at the Mount Bachelor Observatory

Cited by 41 publications

References 75 publications

Transport of Central American Fire Emissions to the U.S. Gulf Coast: Climatological Pathways and Impacts on Ozone and PM2.5

Transport of Central American Fire Emissions to the U.S. Gulf Coast: Climatological Pathways and Impacts on Ozone and PM2.5

Potential link between compromised air quality and transmission of the novel corona virus (SARS-CoV-2) in affected areas

Simulating the forest fire plume dispersion, chemistry, and aerosol formation using SAM-ASP version 1.0

Contact Info

Product

Resources

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Transport of Central American Fire Emissions to the U.S. Gulf Coast: Climatological Pathways and Impacts on Ozone and PM_2.5

Transport of Central American Fire Emissions to the U.S. Gulf Coast: Climatological Pathways and Impacts on Ozone and PM_2.5