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Main Authors: Mishra, Sachit, Srivastava, Rajat, Muhammad, Atta, Amit, Amit, Chiavazzo, Eliodoro, Fasano, Matteo, Asinari, Pietro
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2208.04172
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author Mishra, Sachit
Srivastava, Rajat
Muhammad, Atta
Amit, Amit
Chiavazzo, Eliodoro
Fasano, Matteo
Asinari, Pietro
author_facet Mishra, Sachit
Srivastava, Rajat
Muhammad, Atta
Amit, Amit
Chiavazzo, Eliodoro
Fasano, Matteo
Asinari, Pietro
contents Hybrid electric vehicles and portable electronic systems use supercapacitors for energy storage owing to their fast charging discharging rates, long life cycle, and low maintenance. Specific capacitance is regarded as one of the most important performance-related characteristics of a supercapacitor's electrode. In the current study, Machine Learning (ML) algorithms were used to determine the impact of various physicochemical properties of carbon-based materials on the capacitive performance of electric double-layer capacitors. Published experimental datasets from 147 references (4899 data entries) were extracted and then used to train and test the ML models, to determine the relative importance of electrode material features on specific capacitance. These features include current density, pore volume, pore size, presence of defects, potential window, specific surface area, oxygen, and nitrogen content of the carbon-based electrode material. Additionally, categorical variables as the testing method, electrolyte, and carbon structure of the electrodes are considered as well. Among five applied regression models, an extreme gradient boosting model was found to best correlate those features with the capacitive performance, highlighting that the specific surface area, the presence of nitrogen doping, and the potential window are the most significant descriptors for the specific capacitance. These findings are summarized in a modular and open-source application for estimating the capacitance of supercapacitors given, as only inputs, the features of their carbon-based electrodes, the electrolyte and testing method. In perspective, this work introduces a new wide dataset of carbon electrodes for supercapacitors extracted from the experimental literature, also giving an instance of how electrochemical technology can benefit from ML models.
format Preprint
id arxiv_https___arxiv_org_abs_2208_04172
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle The impact of physicochemical features of carbon electrodes on the capacitive performance of supercapacitors: A machine learning approach
Mishra, Sachit
Srivastava, Rajat
Muhammad, Atta
Amit, Amit
Chiavazzo, Eliodoro
Fasano, Matteo
Asinari, Pietro
Materials Science
Disordered Systems and Neural Networks
Hybrid electric vehicles and portable electronic systems use supercapacitors for energy storage owing to their fast charging discharging rates, long life cycle, and low maintenance. Specific capacitance is regarded as one of the most important performance-related characteristics of a supercapacitor's electrode. In the current study, Machine Learning (ML) algorithms were used to determine the impact of various physicochemical properties of carbon-based materials on the capacitive performance of electric double-layer capacitors. Published experimental datasets from 147 references (4899 data entries) were extracted and then used to train and test the ML models, to determine the relative importance of electrode material features on specific capacitance. These features include current density, pore volume, pore size, presence of defects, potential window, specific surface area, oxygen, and nitrogen content of the carbon-based electrode material. Additionally, categorical variables as the testing method, electrolyte, and carbon structure of the electrodes are considered as well. Among five applied regression models, an extreme gradient boosting model was found to best correlate those features with the capacitive performance, highlighting that the specific surface area, the presence of nitrogen doping, and the potential window are the most significant descriptors for the specific capacitance. These findings are summarized in a modular and open-source application for estimating the capacitance of supercapacitors given, as only inputs, the features of their carbon-based electrodes, the electrolyte and testing method. In perspective, this work introduces a new wide dataset of carbon electrodes for supercapacitors extracted from the experimental literature, also giving an instance of how electrochemical technology can benefit from ML models.
title The impact of physicochemical features of carbon electrodes on the capacitive performance of supercapacitors: A machine learning approach
topic Materials Science
Disordered Systems and Neural Networks
url https://arxiv.org/abs/2208.04172