Predictive modeling for hydrogen storage in functionalized carbonaceous nanomaterials using machine learning

文献类型: 外文期刊

第一作者: Wang, Yajing

作者: Wang, Yajing;Li, Mengtong;Pan, Junting;Shahbeik, Hossein;Tabatabaei, Meisam;Moradi, Aysooda;Rafiee, Shahin;Shafizadeh, Alireza;Nia, Seyyed Alireza Ghafarian;Aghbashlo, Mortaza;Khoshnevisan, Benyamin;Nadian, Mohammad Hossein

作者机构:

关键词: Hydrogen storage; Machine learning; Carbonaceous nanomaterials; Solid-state materials; Gradient boosting regression; Hydrogen adsorption/desorption

期刊名称:JOURNAL OF ENERGY STORAGE ( 影响因子:8.9; 五年影响因子:9.0 )

ISSN: 2352-152X

年卷期: 2024 年 97 卷

页码:

收录情况: SCI

摘要: Hydrogen, valued for its high energy density and environmental friendliness, stands out as a promising energy carrier. Traditional storage methods, such as high-pressure gas cylinders and cryogenic liquid tanks, face challenges related to transportation risks, low energy efficiency, and economic feasibility. In this context, solid-state materials, particularly carbonaceous nanomaterials, have gained prominence as alternatives for hydrogen storage due to their notable capacity, cost-effectiveness, and reliability. However, the identification of efficient carbonaceous adsorbents presents challenges, requiring expensive and time-consuming experimental efforts. This study introduces a machine learning (ML) model designed to predict hydrogen storage capacity in functionalized carbonaceous nanomaterials. Leveraging the ability of ML technology to unravel complex relationships within extensive datasets, the collected comprehensive dataset undergoes rigorous statistical analysis and mechanistic discussions. Feature importance analysis is used to provide insights into the influence of input features on hydrogen storage capacity. The Gaussian process regression model emerges as a standout performer, achieving impressive metrics with an R-2 > 0.955, RMSE < 0.121, and MAE < 0.064 for hydrogen adsorption/desorption during the testing phase. The impact of pressure and temperature on hydrogen adsorption, along with pressure and sorbent average crystal size for hydrogen desorption, is elucidated. This ML model has the potential to revolutionize the identification of optimal material properties and processing conditions for hydrogen adsorption in carbonaceous nanomaterials, offering significant time and cost savings.

分类号:

  • 相关文献
作者其他论文 更多>>

微信小程序