Evaluating Anthropogenic CO2 Bottom-Up Emission Inventories Using Satellite Observations from GOSAT and OCO-2

Zhang, Shaoqing; Lei, Liping; Sheng, Mengya; Song, Hao; Li, Luman; Guo, Ke; Ma, Cui; Liu, Liangyun; Zeng, Zhao‐Cheng

doi:10.3390/rs14195024

Cited by 7 publications

(3 citation statements)

References 46 publications

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“…We would extend the study areas, such as the American land area, to validate our proposed approach in the future. Another additional study built the grid-based prediction model by generalized regression neural network (GRNN) algorithm using a long time series of data from 2010 to 2019, each grid including XCO 2 and SIF, where the predicted ACE was 4% lower than ODIAC in 2019 for the Chinese region and indicated that larger predicting biases were mainly located around the big cities [28]. This GRNN model needs long-term series data that are difficult to collect when using multiple parameters, which could not further improve the prediction accuracy of the model.…”

Section: Discussionmentioning

confidence: 99%

“…Consequently, the values of emissions have a regional non-normal distribution, which affects the unbiased modeling and accurate estimation of ACEs. Several studies have attempted to reduce this effect using the sampling methods of training data (e.g., by segmenting the emission intensity into two parts and then constructing an estimation model on a segment basis [27,28]) and demonstrated better validation results for predicting anthropogenic CO 2 emissions at the national scale. However, these previous studies used few predictor variables and insufficiently evaluated the prediction results.…”

Section: Introductionmentioning

confidence: 99%

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A Novel Approach for Predicting Anthropogenic CO2 Emissions Using Machine Learning Based on Clustering of the CO2 Concentration

Ji,

Song,

Lei

et al. 2024

Atmosphere

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The monitoring of anthropogenic CO2 emissions, which increase the atmospheric CO2 concentration, plays the most important role in the management of emission reduction and control. With the massive increase in satellite-based observation data related to carbon emissions, a data-driven machine learning method has great prospects for predicting anthropogenic CO2 emissions. Training samples, which are used to model predictions of anthropogenic CO2 emissions through machine learning algorithms, play a key role in obtaining accurate predictions for the spatial heterogeneity of anthropogenic CO2 emissions. We propose an approach for predicting anthropogenic CO2 emissions using the training datasets derived from the clustering of the atmospheric CO2 concentration and the segmentation of emissions to resolve the issue of the spatial heterogeneity of anthropogenic CO2 emissions in machine learning modeling. We assessed machine learning algorithms based on decision trees and gradient boosting (GBDT), including LightGBM, XGBoost, and CatBoost. We used multiple parameters related to anthropogenic CO2-emitting activities as predictor variables and emission inventory data from 2019 to 2021, and we compared and verified the accuracy and effectiveness of different prediction models based on the different sampling methods of training datasets combined with machine learning algorithms. As a result, the anthropogenic CO2 emissions predicted by CatBoost modeling from the training dataset derived from the clustering analysis and segmentation method demonstrated optimal prediction accuracy and performance for revealing anthropogenic CO2 emissions. Based on a machine learning algorithm using observation data, this approach for predicting anthropogenic CO2 emissions could help us quickly obtain up-to-date information on anthropogenic CO2 emissions as one of the emission monitoring tools.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Novel Approach for Predicting Anthropogenic CO2 Emissions Using Machine Learning Based on Clustering of the CO2 Concentration

Ji,

Song,

Lei

et al. 2024

Atmosphere

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“…These estimates at the urban scale have widely been obtained by top-down inversion approaches (more details in supplementary note 1) based on atmospheric CO 2 measurements (e.g. Lauvaux et al 2020 for Indianapolis; Breon et al 2015 for Paris; Verhulst et al 2017 for Los Angeles; Mueller et al 2021 for Baltimore-Washington area; Basu et al 2020 for the United States), which allows independent evaluation and identification of potential quality issues of GHG inventories (Zhang et al 2022). Its applications in the estimation of anthropogenic GHG were reported by Manning et al (2011), Lauvaux et al (2020), andNASEM (2022).…”

Section: Introductionmentioning

confidence: 99%

A top-down estimation of subnational CO₂ budget using a global high-resolution inverse model with data from regional surface networks

Nayagam,

Maksyutov,

Oda

et al. 2023

Environ. Res. Lett.

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Top-down approaches, such as atmospheric inversions, are a promising tool for evaluating emission estimates based on activity-data. In particular, there is a need to examine carbon budgets at subnational scales (e.g. state/province), since this is where the climate mitigation policies occur. In this study, the subnational scale anthropogenic CO2 emissions are estimated using a high-resolution global CO2 inverse model. The approach is distinctive with the use of continuous atmospheric measurements from regional/urban networks along with background monitoring data for the period 2015–2019 in global inversion. The measurements from several urban areas of the U.S., Europe and Japan, together with recent high-resolution emission inventories and data-driven flux datasets were utilized to estimate the fossil emissions across the urban areas of the world. By jointly optimizing fossil fuel and natural fluxes, the model is able to contribute additional information to the evaluation of province–scale emissions, provided that sufficient regional network observations are available. The fossil CO2 emission estimates over the U.S. states such as Indiana, Massachusetts, Connecticut, New York, Virginia and Maryland were found to have a reasonable agreement with the Environmental Protection Agency (EPA) inventory, and the model corrects the emissions substantially towards the EPA estimates for California and Indiana. The emission estimates over the United Kingdom, France and Germany are comparable with the regional inventory TNO–CAMS. We evaluated model estimates using independent aircraft observations, while comparison with the CarbonTracker model fluxes confirms ability to represent the biospheric fluxes. This study highlights the potential of the newly developed inverse modeling system to utilize the atmospheric data collected from the regional networks and other observation platforms for further enhancing the ability to perform top-down carbon budget assessment at subnational scales and support the monitoring and mitigation of greenhouse gas emissions.

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High‐resolution atmospheric CO₂ concentration data simulated in WRF‐Chem over East Asia for 10 years

Seo,

Kim,

Kim

2024

Geoscience Data Journal

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In this study, high‐resolution CO2 concentration data were generated for East Asia to analyse long‐term changes in atmospheric CO2 concentrations, as East Asia is an important region for understanding the global carbon cycle. Using the Weather Research and Forecasting model coupled with Chemistry (WRF‐Chem), atmospheric CO2 concentrations were simulated in East Asia at a resolution of 9 km for a period of 10 years (2009–2018). The generated CO2 concentration data include CO2 concentrations, biogenic CO2 concentrations, anthropogenic CO2 concentrations, oceanic CO2 concentrations, biospheric CO2 uptake, biospheric CO2 release and meteorological variables at 3‐h intervals. The simulated high‐resolution CO2 concentrations, biogenic CO2 concentrations and anthropogenic CO2 concentrations are stored in NetCDF‐4 (Network Common Data Form, version 4) format and are available for download at https://doi.org/10.7910/DVN/PJTBF3. The simulated annual mean surface CO2 concentrations in East Asia were 391.027 ppm in 2009 and 412.949 ppm in 2018, indicating an increase of 21.922 ppm over the 10‐year period with appropriate seasonal variabilities. The monthly mean CO2 concentrations in East Asia were verified using surface CO2 observations and satellite column‐averaged CO2 mole fraction (XCO2) from Orbiting Carbon Observatory 2 (OCO‐2). Based on surface CO2 observations and OCO‐2 XCO2 concentrations, the average root‐mean‐square error (RMSE) of the simulated CO2 concentrations in WRF‐Chem was 2.474 and 0.374 ppm, respectively, which is smaller than the average RMSE of the low‐resolution CarbonTracker 2019B (CT2019B) simulation. Therefore, the simulated high‐resolution atmospheric CO2 concentrations in East Asia in WRF‐Chem over 10 years are reliable data that resemble the observed values and could be highly valuable in understanding the carbon cycle in East Asia.

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Evaluating Anthropogenic CO2 Bottom-Up Emission Inventories Using Satellite Observations from GOSAT and OCO-2

Cited by 7 publications

References 46 publications

A Novel Approach for Predicting Anthropogenic CO2 Emissions Using Machine Learning Based on Clustering of the CO2 Concentration

A Novel Approach for Predicting Anthropogenic CO2 Emissions Using Machine Learning Based on Clustering of the CO2 Concentration

A top-down estimation of subnational CO₂ budget using a global high-resolution inverse model with data from regional surface networks

High‐resolution atmospheric CO₂ concentration data simulated in WRF‐Chem over East Asia for 10 years

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Evaluating Anthropogenic CO2 Bottom-Up Emission Inventories Using Satellite Observations from GOSAT and OCO-2

Cited by 7 publications

References 46 publications

A Novel Approach for Predicting Anthropogenic CO2 Emissions Using Machine Learning Based on Clustering of the CO2 Concentration

A Novel Approach for Predicting Anthropogenic CO2 Emissions Using Machine Learning Based on Clustering of the CO2 Concentration

A top-down estimation of subnational CO2 budget using a global high-resolution inverse model with data from regional surface networks

High‐resolution atmospheric CO2 concentration data simulated in WRF‐Chem over East Asia for 10 years

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A top-down estimation of subnational CO₂ budget using a global high-resolution inverse model with data from regional surface networks

High‐resolution atmospheric CO₂ concentration data simulated in WRF‐Chem over East Asia for 10 years