Intelligent prediction models based on machine learning for CO2 capture performance by graphene oxide-based adsorbents

Fathalian, Farnoush; Aarabi, Sepehr; Ghaemi, Ahad; Hemmati, Alireza

doi:10.1038/s41598-022-26138-6

Cited by 18 publications

(9 citation statements)

References 57 publications

(49 reference statements)

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“…By this method, the cost of experimental screening is greatly reduced. Fathalian et al used machine learning to predict the performance of CO 2 adsorbents, which was in general agreement with the experimental results. Takahashi et al used machine learning to screen the design of methane oxidation coupling catalysts, resulting in a high-performance catalyst; machine learning has good expertise in predicting the performance of materials.…”

Section: Introductionmentioning

confidence: 57%

Screening of Natural Oxygen Carriers for Chemical Looping Combustion Based on a Machine Learning Method

Song

Wang

et al. 2023

Energy Fuels

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The screening of high-quality oxygen carriers is a key focus in the field of chemical looping combustion. However, the existing screening methods have the problems of being high cost and having long material design cycles. Here, a machine learning model has been established which successfully predicted the effect of composition, porosity, specific surface area, and other physicochemical properties on the redox performance. A database consisting of 190 samples was used to train the BP-ANN algorithm and the SVM algorithm. The SVM algorithm triumphs over the BP-ANN algorithm in that the best model by the SVM algorithm makes predictions with a high coefficient of determination (R 2 = 0.961) and a low root mean square error (RMSE = 0.014).According to the obtained model, the copper ore was estimated to exhibit high reaction performance in terms of 68% CH 4 conversion and 96% CO conversion at 950 °C. We anticipate the machine learning method can be extended to predict the performance of oxygen carriers for other chemical looping applications.

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Section: Introductionmentioning

confidence: 57%

Screening of Natural Oxygen Carriers for Chemical Looping Combustion Based on a Machine Learning Method

Song

Wang

et al. 2023

Energy Fuels

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“…The better the estimates are based on the experimental data, the closer the R 2 is to 1. The calculation for R 2 is as follows 55 : where Y mean refers to the average value.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Modeling based on machine learning to investigate flue gas desulfurization performance by calcium silicate absorbent in a sand bed reactor

Naderi,

Kalami Yazdi,

Jafarabadi

et al. 2024

Sci Rep

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Flue gas desulfurization (FGD) is a critical process for reducing sulfur dioxide (SO2) emissions from industrial sources, particularly power plants. This research uses calcium silicate absorbent in combination with machine learning (ML) to predict SO2 concentration within an FGD process. The collected dataset encompasses four input parameters, specifically relative humidity, absorbent weight, temperature, and time, and incorporates one output parameter, which pertains to the concentration of SO2. Six ML models were developed to estimate the output parameters. Statistical metrics such as the coefficient of determination (R2) and mean squared error (MSE) were employed to identify the most suitable model and assess its fitting effectiveness. The random forest (RF) model emerged as the top-performing model, boasting an R2 of 0.9902 and an MSE of 0.0008. The model's predictions aligned closely with experimental results, confirming its high accuracy. The most suitable hyperparameter values for RF model were found to be 74 for n_estimators, 41 for max_depth, false for bootstrap, sqrt for max_features, 1 for min_samples_leaf, absolute_error for criterion, and 3 for min_samples_split. Three-dimensional surface plots were generated to explore the impact of input variables on SO2 concentration. Global sensitivity analysis (GSA) revealed absorbent weight and time significantly influence SO2 concentration. The integration of ML into FGD modeling offers a novel approach to optimizing the efficiency and effectiveness of this environmentally crucial process.

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“…Molecular simulations are used to screen different composites, and the results are used to develop machine learning models that accurately predict the adsorption and separation performances of the composites. [24] Graph-based convolutional neural networks are also utilized to predict and rank gas adsorption properties of MOF adsorbents, solely based on structural input les. [25] This study aims to develop and rigorously validate machine learning-based QSPR models, enabling precise predictions of CO 2 uptake in MOFs that outperform the existing models and give better insights on the mechanism that drives this capture.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning-driven models for predicting CO2 Uptake in Metal-Organic Frameworks (MOFs)

Achour,

Hosni

2024

Preprint

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This study advances the discourse on the application of machine learning (ML) algorithms for the predictive analysis of CO2 uptake in Metal-Organic Frameworks (MOFs), with a nuanced focus on the CATBoost model's capability to navigate the complexities inherent in MOFs' heterogeneous landscape. Building upon and extending the comparative analysis, our investigation underscores the CATBoost model's remarkable predictive prowess, characterized by a significant reduction in root mean square error (RMSE) and an enhanced R-squared (R²) value, thereby affirming its superior accuracy and reliability in forecasting CO2 adsorption. A pivotal aspect of our research is the integration of SHAP values for a detailed assessment of feature importance, which not only corroborated 'Pressure' and 'Surface Area' as pivotal determinants of CO2 uptake but also illuminated the model's advanced analytical capabilities in handling categorical features and mitigating overfitting, even within a dataset marked by intricate and non-linear patterns. Our quantitative and conceptual analysis, showcasing up to a 15% improvement in (RMSE) over previous models, reveals the CATBoost model’s unparalleled efficiency in discerning the multifaceted interplay of factors influencing CO2 adsorption. This is crucial for the strategic engineering of MOFs with optimized properties. Beyond 'Pressure' and 'Surface Area', our SHAP analysis highlighted other descriptors with substantial values, elucidating their nuanced contributions to CO2 uptake and providing invaluable insights for the MOF design process.

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Intelligent prediction models based on machine learning for CO2 capture performance by graphene oxide-based adsorbents

Cited by 18 publications

References 57 publications

Screening of Natural Oxygen Carriers for Chemical Looping Combustion Based on a Machine Learning Method

Screening of Natural Oxygen Carriers for Chemical Looping Combustion Based on a Machine Learning Method

Modeling based on machine learning to investigate flue gas desulfurization performance by calcium silicate absorbent in a sand bed reactor

Machine Learning-driven models for predicting CO2 Uptake in Metal-Organic Frameworks (MOFs)

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