An evaluation of CMAQ NO<sub>2</sub> using observed chemistry‐meteorology correlations

Harkey, Monica; Holloway, Tracey; Oberman, J.; Scotty, Erica

doi:10.1002/2015jd023316

Cited by 30 publications

(33 citation statements)

References 234 publications

(432 reference statements)

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“…Global CTMs typically have a horizontal resolution of 2-5 • . Meanwhile, high-resolution simulations have been conducted using regional models, which have shown the ability to simulate observed high tropospheric NO 2 columns over major polluted regions such as East Asia, North America, and Europe (e.g., Uno et al, 2007;Kim et al, 2009;Huijnen et al, 2010a;Itahashi et al, 2014;Yamaji et al, 2014;Canty et al, 2015;Han et al, 2015;Harkey et al, 2015). High-resolution simulations can lead to improvements in two ways: (1) through reduced spatial representation gaps between observed and simulated fields and (2) via improved representation of large-scale concentration fields through a consideration of small-scale processes.…”

Section: Introductionmentioning

confidence: 99%

Global high-resolution simulations of tropospheric nitrogen dioxide using CHASER V4.0

et al. 2018

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Abstract. We evaluate global tropospheric nitrogen dioxide (NO 2 ) simulations using the CHASER V4.0 global chemical transport model (CTM) at horizontal resolutions of 0.56, 1.1, and 2.8 • . Model evaluation was conducted using satellite tropospheric NO 2 retrievals from the Ozone Monitoring Instrument (OMI) and the Global Ozone Monitoring Experiment-2 (GOME-2) and aircraft observations from the 2014 Front Range Air Pollution and Photochemistry Experiment (FRAPPÉ). Agreement against satellite retrievals improved greatly at 1.1 and 0.56 • resolutions (compared to 2.8 • resolution) over polluted and biomass burning regions. The 1.1 • simulation generally captured the regional distribution of the tropospheric NO 2 column well, whereas 0.56 • resolution was necessary to improve the model performance over areas with strong local sources, with mean bias reductions of 67 % over Beijing and 73 % over San Francisco in summer. Validation using aircraft observations indicated that high-resolution simulations reduced negative NO 2 biases below 700 hPa over the Denver metropolitan area. These improvements in high-resolution simulations were attributable to (1) closer spatial representativeness between simulations and observations and (2) better representation of large-scale concentration fields (i.e., at 2.8 • ) through the consideration of small-scale processes. Model evaluations conducted at 0.5 and 2.8 • bin grids indicated that the contributions of both these processes were comparable over most polluted regions, whereas the latter effect (2) made a larger contribution over eastern China and biomass burning areas. The evaluations presented in this paper demonstrate the potential of using a high-resolution global CTM for studying megacity-scale air pollutants across the entire globe, potentially also contributing to global satellite retrievals and chemical data assimilation.

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Section: Introductionmentioning

confidence: 99%

Global high-resolution simulations of tropospheric nitrogen dioxide using CHASER V4.0

et al. 2018

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“…We also evaluate whether the difference between morning and mid-day NO 2 values are similar between AQS and satellites. Due to the time-lag in peak values between surface and column NO 2 discussed in Fishman et al (2008), and the role of boundary layer height in determining diurnal variability of NO 2 discussed in Song et al (2011) andHarkey et al (2015), we would expect a lower level of agreement for temporal differences than we see for concurrent NO 2 values. Indeed, figure 2(c) shows a relatively weak agreement between diurnal change from satellites and diurnal change at the surface, with summer mean r 2 =0.25.…”

Section: Monitor Versus Satellite Nomentioning

confidence: 56%

“…Our standard analysis approach allocates GOME-2 and OMI level-2 data products to 0.25°x 0.25°and 0.5°x 0.5°grids using the Wisconsin Horizontal Interpolation Program for Satellites (WHIPS) v2.1 (Harkey et al 2015), which utilizes the NASA OMNO2d gridding algorithm (Bucsela et al 2016). The WHIPS software allows users to apply a cloud filter, and we use only pixels with a cloud fraction less than 0.3.…”

Section: Study Methodsmentioning

confidence: 99%

Evaluating current satellite capability to observe diurnal change in nitrogen oxides in preparation for geostationary satellite missions

Penn

Holloway

2020

Environ. Res. Lett.

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This study characterizes the degree to which current polar-orbiting satellites can evaluate the daytime change in NO 2 vertical column density (VCD) in urban, suburban, and rural areas. We examine these issues by considering the diurnal cycle of NO 2 over the United States, using the large NO 2 monitoring network supported by states, tribes, and the US Environmental Protection Agency (EPA). Through this analysis, we identify the potential opportunities and limitations of current space-based NO 2 data in capturing diurnal change. Ground-based monitoring data from the US EPA are compared with satellite retrievals of NO 2 from the KNMI Tropospheric Emissions Monitoring Internet Service (TEMIS) for two instruments: GOME-2 with a mid-morning overpass, and OMI with an early afternoon overpass. Satellite data show evidence of higher morning NO 2 in the vicinity of large urban areas. Both satellites and ground monitors show ∼1.5-2x greater NO 2 abundance between morning and afternoon in urban areas. Despite differences in horizontal resolution and overpass time, the two satellite retrievals show similar agreement with ground-based NO 2 measurements. When analyzed on a pixel-by-pixel basis, we find evidence for spatial structure in the diurnal change in NO 2 between city center and surrounding areas in Southern California. Wider analysis of urban-suburban structure in diurnal NO 2 change is hindered by resolution differences in the two satellite instruments, which have the potential to create data artefacts. This study highlights the value of future geostationary instruments to provide comparable satellite retrievals for NO 2 over the course of a day, and research needs related to the effective utilization of NO 2 satellite data for air quality applications.

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“…This allows nearly one-to-one comparison between modeled and satellite tropospheric columns. WHIPS has been used previously for model evaluation in numerous air quality studies in the U.S. [Harkey et al, 2015;Kemball-Cook et al, 2015], and here WHIPS is used to process satellite data for air quality model evaluation in India.…”

Section: Satellite Observations Supporting Model Results Evaluationmentioning

confidence: 99%

Urban Emissions and Regional Air Quality in India

Karambelas

2017

Proc. Wisc. Space Conf.

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Satellite observations from the Ozone Monitoring Instrument are used in support of model evaluation of seasonal average results from the U.S. Environmental Protection Agency (EPA) Community Multi-scale Air Quality (CMAQ) model. Model evaluation was conducted with the purpose of identifying regional biases in model output compared to tropospheric columns. Comparison with tropospheric column NO2, an anthropogenic indicator, reveal that there are uncertainties regarding the emissions inventory input to CMAQ. Results have implications for developing accurate model inputs to produce accurate model output for relevant health impact assessments, which are increasingly important with increasing population, urbanization, and pollution in the region.

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An evaluation of CMAQ NO₂ using observed chemistry‐meteorology correlations

Cited by 30 publications

References 234 publications

Global high-resolution simulations of tropospheric nitrogen dioxide using CHASER V4.0

Global high-resolution simulations of tropospheric nitrogen dioxide using CHASER V4.0

Evaluating current satellite capability to observe diurnal change in nitrogen oxides in preparation for geostationary satellite missions

Urban Emissions and Regional Air Quality in India

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An evaluation of CMAQ NO2 using observed chemistry‐meteorology correlations

Cited by 30 publications

References 234 publications

Global high-resolution simulations of tropospheric nitrogen dioxide using CHASER V4.0

Global high-resolution simulations of tropospheric nitrogen dioxide using CHASER V4.0

Evaluating current satellite capability to observe diurnal change in nitrogen oxides in preparation for geostationary satellite missions

Urban Emissions and Regional Air Quality in India

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An evaluation of CMAQ NO₂ using observed chemistry‐meteorology correlations