Replacing the AMOR with the miniDOAS in the ammonia monitoring network in the Netherlands

Berkhout, Stijn; Swart, D. P. J.; Volten, H.; Gast, L. F. L.; Haaima, Marty; Verboom, Hans; Stefess, Guus; Hafkenscheid, T.L.; Hoogerbrugge, R

doi:10.5194/amt-10-4099-2017

Cited by 22 publications

(24 citation statements)

References 29 publications

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“…By dividing the integrated concentration by the length of the absorption path, the average NH 3 concentration (in µg/m 3 ) is obtained over the optical path [54]. The mini-DOAS system was evaluated during dedicated field campaigns, which demonstrated its reliability for measuring NH 3 concentrations over an urban area [55] and NH 3 vertical profiles [56] as well as its adequacy for long-term monitoring of NH 3 in an air quality network [57].…”

Section: Mini-doasmentioning

confidence: 99%

Ammonia and PM2.5 Air Pollution in Paris during the 2020 COVID Lockdown

et al. 2021

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During the COVID-19 pandemic, the lockdown reduced anthropogenic emissions of NO2 in Paris. NO2 concentrations recorded in 2020 were the lowest they have been in the past 5 years. Despite these low-NO2 levels, Paris experienced PM2.5 pollution episodes, which were investigated here based on multi-species and multi-platform measurements. Ammonia (NH3) measurements over Paris, derived from a mini-DOAS (differential optical absorption spectroscopy) instrument and the Infrared Atmospheric Sounding Interferometer (IASI) satellite, revealed simultaneous enhancements during the spring PM2.5 pollution episodes. Using the IASI maps and the FLEXPART model, we show that long-range transport had a statistically significant influence on the degradation of air quality in Paris. In addition, concentrations of ammonium (NH4+) and PM2.5 were strongly correlated for all episodes observed in springtime 2020, suggesting that transport of NH3 drove a large component of the PM2.5 pollution over Paris. We found that NH3 was not the limiting factor for the formation of ammonium nitrate (NH4NO3), and we suggest that the conversion of ammonia to ammonium may have been the essential driver.

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Section: Mini-doasmentioning

confidence: 99%

Ammonia and PM2.5 Air Pollution in Paris during the 2020 COVID Lockdown

et al. 2021

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“…In the Netherlands, the Dutch National Air Quality Monitoring Network (LML: Landelijk Meetnet Luchtkwaliteit) and the Measuring Ammonia in Nature Network (MAN) have been making measurements of [NH 3 ] across the Netherlands since 1993 and 2005, respectively. The LML reports hourly [NH 3 ] since 1993 at eight sites and since 2014 at six sites using continuous-flow denuders (AMORs: Amanda for MOnitoring RIVM; Wyers et al [54]) and currently miniDOAS [59], and in two sites, triplets of passive samplers [60] for monthly mean values. While the LML provides a high temporal resolution, its low spatial distribution is compensated by over 300 sites of MAN that provide monthly passive sampling measurements of [NH 3 ].…”

Section: In Situ Measurementsmentioning

confidence: 99%

Quantification of Atmospheric Ammonia Concentrations: A Review of Its Measurement and Modeling

Nair

2020

Atmosphere

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Ammonia (NH3), the most prevalent alkaline gas in the atmosphere, plays a significant role in PM2.5 formation, atmospheric chemistry, and new particle formation. This paper reviews quantification of [NH3] through measurements, satellite-remote-sensing, and modeling reported in over 500 publications towards synthesizing the current knowledge of [NH3], focusing on spatiotemporal variations, controlling processes, and quantification issues. Most measurements are through regional passive sampler networks. [NH3] hotspots are typically over agricultural regions, such as the Midwest US and the North China Plain, with elevated concentrations reaching monthly averages of 20 and 74 ppbv, respectively. Topographical effects dramatically increase [NH3] over the Indo-Gangetic Plains, North India and San Joaquin Valley, US. Measurements are sparse over oceans, where [NH3] ≈ a few tens of pptv, variations of which can affect aerosol formation. Satellite remote-sensing (AIRS, CrIS, IASI, TANSO-FTS, TES) provides global [NH3] quantification in the column and at the surface since 2002. Modeling is crucial for improving understanding of NH3 chemistry and transport, its spatiotemporal variations, source apportionment, exploring physicochemical mechanisms, and predicting future scenarios. GEOS-Chem (global) and FRAME (UK) models are commonly applied for this. A synergistic approach of measurements↔satellite-inference↔modeling is needed towards improved understanding of atmospheric ammonia, which is of concern from the standpoint of human health and the ecosystem.

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“…Initially, continuous flow denuders from AMOR were used, which have a reported uncertainty of at least 9 % for hourly concentrations (Blank et al, 2001). Around 2016, the AMOR instruments were replaced by miniDOAS instruments (Berkhout et al, 2017), which are active differential optical absorption spectroscopes. For evaluation of the wet deposition fields, observations from wetonly samplers from the Dutch Landelijk Meetnet Regenwatersamenstelling (LMRe) network (van Zanten et al, 2017), whose locations largely overlap with the LML network, and the UBA network (Schaap et al, 2018) are used.…”

Section: In Situ Observationsmentioning

confidence: 99%

Data assimilation of CrIS NH<sub>3</sub> satellite observations for improving spatiotemporal NH<sub>3</sub> distributions in LOTOS-EUROS

et al. 2022

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Abstract. Atmospheric levels of ammonia (NH3) have substantially increased during the last century, posing a hazard to both human health and environmental quality. The atmospheric budget of NH3, however, is still highly uncertain due to an overall lack of observations. Satellite observations of atmospheric NH3 may help us in the current observational and knowledge gaps. Recent observations of the Cross-track Infrared Sounder (CrIS) provide us with daily, global distributions of NH3. In this study, the CrIS NH3 product is assimilated into the LOTOS-EUROS chemistry transport model using two different methods aimed at improving the modeled spatiotemporal NH3 distributions. In the first method NH3 surface concentrations from CrIS are used to fit spatially varying NH3 emission time factors to redistribute model input NH3 emissions over the year. The second method uses the CrIS NH3 profile to adjust the NH3 emissions using a local ensemble transform Kalman filter (LETKF) in a top-down approach. The two methods are tested separately and combined, focusing on a region in western Europe (Germany, Belgium and the Netherlands). In this region, the mean CrIS NH3 total columns were up to a factor 2 higher than the simulated NH3 columns between 2014 and 2018, which, after assimilating the CrIS NH3 columns using the LETKF algorithm, led to an increase in the total NH3 emissions of up to approximately 30 %. Our results illustrate that CrIS NH3 observations can be used successfully to estimate spatially variable NH3 time factors and improve NH3 emission distributions temporally, especially in spring (March to May). Moreover, the use of the CrIS-based NH3 time factors resulted in an improved comparison with the onset and duration of the NH3 spring peak observed at observation sites at hourly resolution in the Netherlands. Assimilation of the CrIS NH3 columns with the LETKF algorithm is mainly advantageous for improving the spatial concentration distribution of the modeled NH3 fields. Compared to in situ observations, a combination of both methods led to the most significant improvements in modeled monthly NH3 surface concentration and NH4+ wet deposition fields, illustrating the usefulness of the CrIS NH3 products to improve the temporal representativity of the model and better constrain the budget in agricultural areas.

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Replacing the AMOR with the miniDOAS in the ammonia monitoring network in the Netherlands

Cited by 22 publications

References 29 publications

Ammonia and PM2.5 Air Pollution in Paris during the 2020 COVID Lockdown

Ammonia and PM2.5 Air Pollution in Paris during the 2020 COVID Lockdown

Quantification of Atmospheric Ammonia Concentrations: A Review of Its Measurement and Modeling

Data assimilation of CrIS NH<sub>3</sub> satellite observations for improving spatiotemporal NH<sub>3</sub> distributions in LOTOS-EUROS

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Replacing the AMOR with the miniDOAS in the ammonia monitoring network in the Netherlands

Cited by 22 publications

References 29 publications

Ammonia and PM2.5 Air Pollution in Paris during the 2020 COVID Lockdown

Ammonia and PM2.5 Air Pollution in Paris during the 2020 COVID Lockdown

Quantification of Atmospheric Ammonia Concentrations: A Review of Its Measurement and Modeling

Data assimilation of CrIS NH&lt;sub&gt;3&lt;/sub&gt; satellite observations for improving spatiotemporal NH&lt;sub&gt;3&lt;/sub&gt; distributions in LOTOS-EUROS

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Data assimilation of CrIS NH<sub>3</sub> satellite observations for improving spatiotemporal NH<sub>3</sub> distributions in LOTOS-EUROS