IntelliO3-ts v1.0: a neural network approach to predict near-surface ozone concentrations in Germany

Kleinert, Felix; Leufen, Lukas Hubert; Schultz, Martin

doi:10.5194/gmd-14-1-2021

Cited by 29 publications

(41 citation statements)

References 46 publications

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“…Meteorological and atmospheric chemistry information at each of the air quality observation sites is obtained from the NASA Goddard Earth Observing System Composition Forecast (GEOS-CF) model (Keller et al, 2020). GEOS-CF integrates the GEOS-Chem atmospheric chemistry model (v12-01) into the GEOS Earth System Model (Long et al, 2015;Hu et al, 2018) and provides global hourly analyses of atmospheric composition at 25 × 25 km 2 spatial resolution, available in near-real time at https://gmao.gsfc.nasa.gov/weather_ prediction/GEOS-CF/data_access/, last access: 5 July 2020 (Knowland et al, 2020). Anthropogenic emissions are prescribed using monthly Hemispheric Transport of Air Pollution (HTAP) bottom-up emissions (Janssens-Maenhout et al, 2015), with imposed weekly and diurnal scale factors as described in Keller et al (2020).…”

Section: Modelmentioning

confidence: 99%

Global impact of COVID-19 restrictions on the surface concentrations of nitrogen dioxide and ozone

et al. 2021

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Abstract. Social distancing to combat the COVID-19 pandemic has led to widespread reductions in air pollutant emissions. Quantifying these changes requires a business-as-usual counterfactual that accounts for the synoptic and seasonal variability of air pollutants. We use a machine learning algorithm driven by information from the NASA GEOS-CF model to assess changes in nitrogen dioxide (NO2) and ozone (O3) at 5756 observation sites in 46 countries from January through June 2020. Reductions in NO2 coincide with the timing and intensity of COVID-19 restrictions, ranging from 60 % in severely affected cities (e.g., Wuhan, Milan) to little change (e.g., Rio de Janeiro, Taipei). On average, NO2 concentrations were 18 (13–23) % lower than business as usual from February 2020 onward. China experienced the earliest and steepest decline, but concentrations since April have mostly recovered and remained within 5 % of the business-as-usual estimate. NO2 reductions in Europe and the US have been more gradual, with a halting recovery starting in late March. We estimate that the global NOx (NO + NO2) emission reduction during the first 6 months of 2020 amounted to 3.1 (2.6–3.6) TgN, equivalent to 5.5 (4.7–6.4) % of the annual anthropogenic total. The response of surface O3 is complicated by competing influences of nonlinear atmospheric chemistry. While surface O3 increased by up to 50 % in some locations, we find the overall net impact on daily average O3 between February–June 2020 to be small. However, our analysis indicates a flattening of the O3 diurnal cycle with an increase in nighttime ozone due to reduced titration and a decrease in daytime ozone, reflecting a reduction in photochemical production. The O3 response is dependent on season, timescale, and environment, with declines in surface O3 forecasted if NOx emission reductions continue.

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Section: Modelmentioning

confidence: 99%

Global impact of COVID-19 restrictions on the surface concentrations of nitrogen dioxide and ozone

et al. 2021

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“…A very simple Python script (e.g. written in a Jupyter Notebook (Kluyver et al, 2016) or Python file) calling the MLAir package without any modification. Selected parts of the corresponding logging of the running code are shown underneath.…”

Section: Running First Experiments With Mlairmentioning

confidence: 99%

“…A more elaborate example is described in Kleinert et al (2021), who used extensions to the standard Keras library in their workflow. So-called inception blocks (Szegedy et al, 2015) and a modification of the two-dimensional padding layers were implemented as Keras layers and could be used in the model afterwards.…”

Section: Defining a Model Classmentioning

confidence: 99%

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MLAir (v1.0) – a tool to enable fast and flexible machine learning on air data time series

Leufen

Kleinert

Schultz³

2021

Geosci. Model Dev.

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Abstract. With MLAir (Machine Learning on Air data) we created a software environment that simplifies and accelerates the exploration of new machine learning (ML) models, specifically shallow and deep neural networks, for the analysis and forecasting of meteorological and air quality time series. Thereby MLAir is not developed as an abstract workflow, but hand in hand with actual scientific questions. It thus addresses scientists with either a meteorological or an ML background. Due to their relative ease of use and spectacular results in other application areas, neural networks and other ML methods are also gaining enormous momentum in the weather and air quality research communities. Even though there are already many books and tutorials describing how to conduct an ML experiment, there are many stumbling blocks for a newcomer. In contrast, people familiar with ML concepts and technology often have difficulties understanding the nature of atmospheric data. With MLAir we have addressed a number of these pitfalls so that it becomes easier for scientists of both domains to rapidly start off their ML application. MLAir has been developed in such a way that it is easy to use and is designed from the very beginning as a stand-alone, fully functional experiment. Due to its flexible, modular code base, code modifications are easy and personal experiment schedules can be quickly derived. The package also includes a set of validation tools to facilitate the evaluation of ML results using standard meteorological statistics. MLAir can easily be ported onto different computing environments from desktop workstations to high-end supercomputers with or without graphics processing units (GPUs).

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“…The principle behind recent machine learning applications in ozone research is often a similar principle to the one Schultz et al (2021) described for weather data: the input data are directly mapped to a specific data product, e.g., from meteorological and past ozone measurements to the next day's maximum ozone value. In recent studies, Sayeed et al (2020) and Kleinert et al (2021) predicted regional ozone time series with convolutional neural networks and meteorological input data. Furthermore, Silva et al (2019) trained a feed-forward neural network to output ozone dry deposition at two forest measurement sites.…”

Section: Introductionmentioning

confidence: 99%

AQ-Bench: a benchmark dataset for machine learning on global air quality metrics

Betancourt¹,

Stomberg

Roscher

et al. 2021

Earth Syst. Sci. Data

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Abstract. With the AQ-Bench dataset, we contribute to the recent developments towards shared data usage and machine learning methods in the field of environmental science. The dataset presented here enables researchers to relate global air quality metrics to easy-access metadata and to explore different machine learning methods for obtaining estimates of air quality based on this metadata. AQ-Bench contains a unique collection of aggregated air quality data from the years 2010–2014 and metadata at more than 5500 air quality monitoring stations all over the world, provided by the first Tropospheric Ozone Assessment Report (TOAR). It focuses in particular on metrics of tropospheric ozone, which has a detrimental effect on climate, human morbidity and mortality, as well as crop yields. The purpose of this dataset is to produce estimates of various long-term ozone metrics based on time-independent local site conditions. We combine this task with a suitable evaluation metric. Baseline scores obtained from a linear regression method, a fully connected neural network and random forest are provided for reference and validation. AQ-Bench offers a low-threshold entrance for all machine learners with an interest in environmental science and for atmospheric scientists who are interested in applying machine learning techniques. It enables them to start with a real-world problem relevant to humans and nature. The dataset and introductory machine learning code are available at https://doi.org/10.23728/b2share.30d42b5a87344e82855a486bf2123e9f (Betancourt et al., 2020) and https://gitlab.version.fz-juelich.de/esde/machine-learning/aq-bench (Betancourt et al., 2021). AQ-Bench thus provides a blueprint for environmental benchmark datasets as well as an example for data re-use according to the FAIR principles.

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IntelliO3-ts v1.0: a neural network approach to predict near-surface ozone concentrations in Germany

Cited by 29 publications

References 46 publications

Global impact of COVID-19 restrictions on the surface concentrations of nitrogen dioxide and ozone

Global impact of COVID-19 restrictions on the surface concentrations of nitrogen dioxide and ozone

MLAir (v1.0) – a tool to enable fast and flexible machine learning on air data time series

AQ-Bench: a benchmark dataset for machine learning on global air quality metrics

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