Urban ozone (O3) formation
can be limited by NO
x
, VOCs, or both,
complicating the design
of effective O3 abatement plans. A satellite-retrieved
ratio of formaldehyde to NO2 (HCHO/NO2), developed
from theory and modeling, has previously been used to indicate O3 formation chemistry. Here, we connect this space-based indicator
to spatiotemporal variations in O3 recorded by on-the-ground
monitors over major U.S. cities. High-O3 events vary nonlinearly
with OMI HCHO and NO2, and the transition from VOC-limited
to NO
x
-limited O3 formation
regimes occurs at higher HCHO/NO2 value (3 to 4) than previously
determined from models, with slight intercity variations. To extend
satellite records back to 1996, we develop an approach to harmonize
observations from GOME and SCIAMACHY that accounts for differences
in spatial resolution and overpass time. Two-decade (1996–2016)
multisatellite HCHO/NO2 captures the timing and location
of the transition from VOC-limited to NO
x
-limited O3 production regimes in major U.S. cities, which
aligns with the observed long-term changes in urban–rural gradient
of O3 and the reversal of O3 weekend effect.
Our findings suggest promise for applying space-based HCHO/NO2 to interpret local O3 chemistry, particularly
with the new-generation satellite instruments that offer finer spatial
and temporal resolution.
Nitrogen dioxide (NO2) is a regulated air pollutant that is of particular concern in many cities, where concentrations are high. Emissions of nitrogen oxides to the atmosphere lead to the formation of ozone and particulate matter, with adverse impacts on human health and ecosystems. The effects of emissions are often assessed through modeling based on inventories relying on indirect information that is often outdated or incomplete. Here we show that NO2 measurements from the new, high-resolution TROPOMI satellite sensor can directly determine the strength and distribution of emissions from Paris. From the observed build-up of NO2 pollution, we find highest emissions on cold weekdays in February 2018, and lowest emissions on warm weekend days in spring 2018. The new measurements provide information on the spatio-temporal distribution of emissions within a large city, and suggest that Paris emissions in 2018 are only 5–15% below inventory estimates for 2011–2012, reflecting the difficulty of meeting NOx emission reduction targets.
Abstract. This paper reports on consolidated ground-based validation results of the atmospheric NO2 data produced operationally since April 2018 by the TROPOspheric Monitoring Instrument (TROPOMI) on board of the ESA/EU Copernicus Sentinel-5 Precursor (S5P) satellite. Tropospheric, stratospheric, and total NO2 column data from S5P are compared to correlative measurements collected from, respectively, 19 Multi-Axis Differential Optical Absorption Spectroscopy (MAX-DOAS), 26 Network for the Detection of Atmospheric Composition Change (NDACC) Zenith-Scattered-Light DOAS (ZSL-DOAS), and 25 Pandonia Global Network (PGN)/Pandora instruments distributed globally. The validation methodology gives special care to minimizing mismatch errors due to imperfect spatio-temporal co-location of the satellite and correlative data, e.g. by using tailored observation operators to account for differences in smoothing and in sampling of atmospheric structures and variability and photochemical modelling to reduce diurnal cycle effects. Compared to the ground-based measurements, S5P data show, on average, (i) a negative bias for the tropospheric column data, of typically −23 % to −37 % in clean to slightly polluted conditions but reaching values as high as −51 % over highly polluted areas; (ii) a slight negative median difference for the stratospheric column data, of about −0.2 Pmolec cm−2, i.e. approx. −2 % in summer to −15 % in winter; and (iii) a bias ranging from zero to −50 % for the total column data, found to depend on the amplitude of the total NO2 column, with small to slightly positive bias values for columns below 6 Pmolec cm−2 and negative values above. The dispersion between S5P and correlative measurements contains mostly random components, which remain within mission requirements for the stratospheric column data (0.5 Pmolec cm−2) but exceed those for the tropospheric column data (0.7 Pmolec cm−2). While a part of the biases and dispersion may be due to representativeness differences such as different area averaging and measurement times, it is known that errors in the S5P tropospheric columns exist due to shortcomings in the (horizontally coarse) a priori profile representation in the TM5-MP chemical transport model used in the S5P retrieval and, to a lesser extent, to the treatment of cloud effects and aerosols. Although considerable differences (up to 2 Pmolec cm−2 and more) are observed at single ground-pixel level, the near-real-time (NRTI) and offline (OFFL) versions of the S5P NO2 operational data processor provide similar NO2 column values and validation results when globally averaged, with the NRTI values being on average 0.79 % larger than the OFFL values.
Global multiconstituent concentration and emission fields obtained from the assimilation of the satellite retrievals of ozone, CO, NO
2
, HNO
3
, and SO
2
from the Ozone Monitoring Instrument (OMI), Global Ozone Monitoring Experiment 2, Measurements of Pollution in the Troposphere, Microwave Limb Sounder, and Atmospheric Infrared Sounder (AIRS)/OMI are used to understand the processes controlling air pollution during the Korea‐United States Air Quality (KORUS‐AQ) campaign. Estimated emissions in South Korea were 0.42 Tg N for NO
x
and 1.1 Tg CO for CO, which were 40% and 83% higher, respectively, than the a priori bottom‐up inventories, and increased mean ozone concentration by up to 7.5 ± 1.6 ppbv. The observed boundary layer ozone exceeded 90 ppbv over Seoul under stagnant phases, whereas it was approximately 60 ppbv during dynamical conditions given equivalent emissions. Chemical reanalysis showed that mean ozone concentration was persistently higher over Seoul (75.10 ± 7.6 ppbv) than the broader KORUS‐AQ domain (70.5 ± 9.2 ppbv) at 700 hPa. Large bias reductions (>75%) in the free tropospheric OH show that multiple‐species assimilation is critical for balanced tropospheric chemistry analysis and emissions. The assimilation performance was dependent on the particular phase. While the evaluation of data assimilation fields shows an improved agreement with aircraft measurements in ozone (to less than 5 ppbv biases), CO, NO
2
, SO
2
, PAN, and OH profiles, lower tropospheric ozone analysis error was largest at stagnant conditions, whereas the model errors were mostly removed by data assimilation under dynamic weather conditions. Assimilation of new AIRS/OMI ozone profiles allowed for additional error reductions, especially under dynamic weather conditions. Our results show the important balance of dynamics and emissions both on pollution and the chemical assimilation system performance.
Nitrogen dioxide
(NO
2
) at the ground level poses a serious threat to environmental
quality and public health. This study developed a novel, artificial
intelligence approach by integrating spatiotemporally weighted information
into the missing extra-trees and deep forest models to first fill
the satellite data gaps and increase data availability by 49% and
then derive daily 1 km surface NO
2
concentrations over
mainland China with full spatial coverage (100%) for the period 2019–2020
by combining surface NO
2
measurements, satellite tropospheric
NO
2
columns derived from TROPOMI and OMI, atmospheric reanalysis,
and model simulations. Our daily surface NO
2
estimates
have an average out-of-sample (out-of-city) cross-validation coefficient
of determination of 0.93 (0.71) and root-mean-square error of 4.89
(9.95) μg/m
3
. The daily seamless high-resolution
and high-quality dataset “ChinaHighNO
2
” allows
us to examine spatial patterns at fine scales such as the urban–rural
contrast. We observed systematic large differences between urban and
rural areas (28% on average) in surface NO
2
, especially
in provincial capitals. Strong holiday effects were found, with average
declines of 22 and 14% during the Spring Festival and the National
Day in China, respectively. Unlike North America and Europe, there
is little difference between weekdays and weekends (within ±1
μg/m
3
). During the COVID-19 pandemic, surface NO
2
concentrations decreased considerably and then gradually
returned to normal levels around the 72nd day after the Lunar New
Year in China, which is about 3 weeks longer than the tropospheric
NO
2
column, implying that the former can better represent
the changes in NO
x
emissions.
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