Development of an Empirical Model to Estimate Real-World Fine Particulate Matter Emission Factors: The Traffic Air Quality Model

Abstract. Wildfires can significantly impact air quality and human health. However, little is known about how duff and peat burning contributes to these impacts. This study investigates the air quality impacts of duff consumption during the four largest wildfire events this century in southeastern United States, with a focus on the different impacts on fine particulate matter less than 2.5 μm in size (PM2.5) and ozone (O3). The emissions of duff burning were estimated based on a field measurement. The emissions from the burning of other fuels were obtained from the Fire INventory from NCAR (FINN). The air quality impacts were simulated using a 3-D regional air quality model. The results show the duff burning emitted PM2.5 comparable to the burning of the above-ground fuels. The simulated surface PM2.5 concentrations due to duff burning increased by 61.3 % locally over a region approximately 300 km within the fire site and by 21.3 % and 29.7 % in the remote metro Atlanta and Charlotte during the 2016 southern Appalachian fires, and by 131.9 % locally and by 17.7 % and 24.8 % in the remote metro Orlando and Miami during the 2007 Okefenokee fire. However, the simulated ozone impacts from the duff burning were negligible due to the small duff emission factors of ozone precursors such as NOx. This study suggests the need to improve the modeling of PM2.5 and the air quality, human health, and climate impacts of wildfires in moist ecosystems by including duff burning in global fire emission inventories.

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Fine PM emission factors from residential burning of solid fuels using traditional cast-iron coal stoves

Clean Air Journal ◽

10.17159/2410-972x/2018/v28n1a10 ◽

2018 ◽

Cited By ~ 1

Author(s):

Ncobile C Nkosi ◽

Stuart J Piketh ◽

Roelof P Burger

Keyword(s):

Particulate Matter ◽

Air Quality ◽

Emission Factor ◽

Fine Particulate Matter ◽

Field Measurements ◽

Emission Factors ◽

Solid Fuels ◽

Fine Particulate ◽

Residential Coal ◽

Stove Operation

Residential burning of solid fuels is a major source of fine particulate matter (PM2.5), which degrades indoor and ambient air quality in low-income settlements. The adverse impact of fine particulate emissions on the environment and human health is well-documented in other countries such as China and India; however, there is need for local studies to report on emission factors from residential burning of solid fuels. An emission factor quantifies the total mass of a pollutant emitted per amount of fuel burned. Emission factor is an input parameter in air quality modelling to forecast a pollutant concentrations over time and when calculating total emissions from a specific source. Local emission factors are central to managing air quality for they give results that are representative of the source compared with international emission factors. Quantifying emissions, understanding household fuel use patterns and interaction with the stove (stove operation behaviour) during a burning event is fundamental when designing emission control strategies. The aim of the study is to quantify fine particulate matter emissions from residential coal burning using systematic field measurements. The objectives of the study are (i) to characterize stove operation behavior effect on the emissions and (ii) to quantify PM2.5 emission factors using field measurements. Isokinetic (2015) and direct (2014) stack sampling tests were done to observe how PM emissions profiles change with stove operation behavior and to quantify PM2.5 emitted per kilogram of fuel burned. Fine PM emission profiles change with stove operation behavior with an emission factor ranging 6.8 g.kg-1 and 13.5 g.kg-1. The study results implies that residential coal burning is a major source of fine particulate matter in the residential area. As demonstrated that stove operation behaviour affect stove to fuel combination emissions; it is therefore suggested that those factors leading to increase emissions should be kept minimum.

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Description and Evaluation of the Fine Particulate Matter Forecasts in the NCAR Regional Air Quality Forecasting System

Atmosphere ◽

10.3390/atmos12030302 ◽

2021 ◽

Vol 12 (3) ◽

pp. 302

Author(s):

Rajesh Kumar ◽

Piyush Bhardwaj ◽

Gabriele Pfister ◽

Carl Drews ◽

Shawn Honomichl ◽

...

Keyword(s):

Particulate Matter ◽

Air Quality ◽

Information Dissemination ◽

Fine Particulate Matter ◽

Model Errors ◽

Air Quality Forecast ◽

Fine Particulate ◽

Regional Air Quality ◽

Forecasting System ◽

Air Quality Forecasting

This paper describes a quasi-operational regional air quality forecasting system for the contiguous United States (CONUS) developed at the National Center for Atmospheric Research (NCAR) to support air quality decision-making, field campaign planning, early identification of model errors and biases, and support the atmospheric science community in their research. This system aims to complement the operational air quality forecasts produced by the National Oceanic and Atmospheric Administration (NOAA), not to replace them. A publicly available information dissemination system has been established that displays various air quality products, including a near-real-time evaluation of the model forecasts. Here, we report the performance of our air quality forecasting system in simulating meteorology and fine particulate matter (PM2.5) for the first year after our system started, i.e., 1 June 2019 to 31 May 2020. Our system shows excellent skill in capturing hourly to daily variations in temperature, surface pressure, relative humidity, water vapor mixing ratios, and wind direction but shows relatively larger errors in wind speed. The model also captures the seasonal cycle of surface PM2.5 very well in different regions and for different types of sites (urban, suburban, and rural) in the CONUS with a mean bias smaller than 1 µg m−3. The skill of the air quality forecasts remains fairly stable between the first and second days of the forecasts. Our air quality forecast products are publicly available at a NCAR webpage. We invite the community to use our forecasting products for their research, as input for urban scale (<4 km), air quality forecasts, or the co-development of customized products, just to name a few applications.

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Characterization of air quality and fine particulate matter sources in the town of Hinton, Alberta

Atmospheric Pollution Research ◽

10.1016/j.apr.2017.07.003 ◽

2018 ◽

Vol 9 (1) ◽

pp. 84-94 ◽

Cited By ~ 3

Author(s):

Md. Aynul Bari ◽

Warren B. Kindzierski

Keyword(s):

Particulate Matter ◽

Air Quality ◽

Fine Particulate Matter ◽

Fine Particulate ◽

The Town

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Meteorological controls on atmospheric particulate pollution during hazard reduction burns

10.5194/acp-2017-491 ◽

2017 ◽

Author(s):

Giovanni Di Virgilio ◽

Melissa Anne Hart ◽

Ningbo Jiang

Keyword(s):

Particulate Matter ◽

Air Quality ◽

Fine Particulate Matter ◽

Meteorological Conditions ◽

Atmospheric Conditions ◽

Hazard Reduction ◽

Particulate Pollution ◽

Fine Particulate ◽

Projected Changes ◽

Sydney Australia

Abstract. Internationally, severe wildfires are an escalating problem likely to worsen given projected changes to climate. Hazard reduction burns (HRB) are used to suppress wildfire occurrences, but they generate considerable emissions of atmospheric fine particulate matter, which depending upon prevailing atmospheric conditions, can degrade air quality. Our objectives are to improve understanding of the relationships between meteorological conditions and air quality during HRBs in Sydney, Australia. We identify the primary meteorological covariates linked to high PM2.5 pollution (particulates

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Effect of selective catalytic reduction denitrification on fine particulate matter emission characteristics

Fuel ◽

10.1016/j.fuel.2018.10.086 ◽

2019 ◽

Vol 238 ◽

pp. 18-25 ◽

Cited By ~ 9

Author(s):

Teng Cheng ◽

Chengqiang Zheng ◽

LinJun Yang ◽

Hao Wu ◽

Hongmei Fan

Keyword(s):

Particulate Matter ◽

Selective Catalytic Reduction ◽

Catalytic Reduction ◽

Fine Particulate Matter ◽

Emission Characteristics ◽

Particulate Matter Emission ◽

Fine Particulate

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Supplementary material to "Synoptic meteorological modes of variability for fine particulate matter (PM<sub>2.5</sub>) air quality in major metropolitan regions of China"

10.5194/acp-2017-916-supplement ◽

2017 ◽

Author(s):

Danny M. Leung ◽

Amos P. K. Tai ◽

Loretta J. Mickley ◽

Jonathan M. Moch ◽

Aaron van Donkelaar ◽

...

Keyword(s):

Particulate Matter ◽

Air Quality ◽

Fine Particulate Matter ◽

Metropolitan Regions ◽

Modes Of Variability ◽

Fine Particulate ◽

Supplementary Material

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Effect of the uncertainty in meteorology on air quality model predictions

Időjárás ◽

10.28974/idojaras.2021.4.5 ◽

2021 ◽

Vol 125 (4) ◽

pp. 625-646

Author(s):

Zita Ferenczi ◽

Emese Homolya ◽

Krisztina Lázár ◽

Anita Tóth

Keyword(s):

Air Pollution ◽

Particulate Matter ◽

Air Quality ◽

Weather Prediction ◽

Horizontal Resolution ◽

Model System ◽

Air Quality Model ◽

Quality Model ◽

Near Surface ◽

The Impact

An operational air quality forecasting model system has been developed and provides daily forecasts of ozone, nitrogen oxides, and particulate matter for the area of Hungary and three big cites of the country (Budapest, Miskolc, and Pécs). The core of the model system is the CHIMERE off-line chemical transport model. The AROME numerical weather prediction model provides the gridded meteorological inputs for the chemical model calculations. The horizontal resolution of the AROME meteorological fields is consistent with the CHIMERE horizontal resolution. The individual forecasted concentrations for the following 2 days are displayed on a public website of the Hungarian Meteorological Service. It is essential to have a quantitative understanding of the uncertainty in model output arising from uncertainties in the input meteorological fields. The main aim of this research is to probe the response of an air quality model to its uncertain meteorological inputs. Ensembles are one method to explore how uncertainty in meteorology affects air pollution concentrations. During the past decades, meteorological ensemble modeling has received extensive research and operational interest because of its ability to better characterize forecast uncertainty. One such ensemble forecast system is the one of the AROME model, which has an 11-member ensemble where each member is perturbed by initial and lateral boundary conditions. In this work we focus on wintertime particulate matter concentrations, since this pollutant is extremely sensitive to near-surface mixing processes. Selecting a number of extreme air pollution situations we will show what the impact of the meteorological uncertainty is on the simulated concentration fields using AROME ensemble members.

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