Optimization framework for redox flow battery electrodes with improved microstructural characteristics

IF 3.2 Q2 CHEMISTRY, PHYSICAL
Energy advances Pub Date : 2024-07-03 DOI:10.1039/D4YA00248B
Alina Berkowitz, Ashley A. Caiado, Sundar Rajan Aravamuthan, Aaron Roy, Ertan Agar and Murat Inalpolat
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Abstract

This research aims to advance the field of vanadium redox flow batteries (VRFBs) by introducing a pioneering approach to optimize the microstructural characteristics of carbon cloth electrodes. Addressing the traditional challenge of developing high-performance electrode materials for VRFBs, this study employs a robust, generalizable, and cost-effective data-driven modeling and optimization framework. A novel sampling strategy using low-discrepancy Latin Hypercube and quasi-Monte Carlo methods generates a small-scale, high-fidelity dataset with essential space-filling qualities for training supervised machine learning models. This study goes beyond conventional methods by constructing two surrogate models: a random forest regressor and a gradient boosting regressor as objective functions for optimization. The integration of a non-dominated sorting genetic algorithm II (NSGA-II) for multi-objective optimization facilitates exhaustive exploration of the surrogate models, leading to the identification of electrode designs that yield enhanced energy efficiencies (EEs) under specific operating conditions. The application of NSGA-II in exploring surrogate models not only facilitates the discovery of realistic design combinations but also adeptly manages trade-offs between features. The mean pore diameter was reduced compared to the tested carbon cloth electrodes while maintaining a similar permeability value based on the results obtained using the developed algorithms. Based on this suggestion, a new type of carbon cloth electrode has been fabricated by introducing a carbonaceous binder into the woven fabric to make carbon cloths with more complex pore structures and reduced mean pore diameter. The new electrode demonstrates 24% and 66% reduction in average ohmic and mass transport resistances, respectively, validating the machine-learning recommendations. This research highlights the critical role of improved electrical conductivity and porosity in carbon materials, showing their direct correlation with increased EE. Overall, this study represents a significant step forward in developing more efficient and practical VRFBs, offering a valuable contribution to the renewable energy storage landscape.

Abstract Image

具有更佳微结构特性的氧化还原液流电池电极优化框架
这项研究通过引入一种优化碳电极微结构特性的开创性方法,极大地推动了钒氧化还原液流电池(VRFB)领域的发展。为了应对为钒氧化还原液流电池开发高性能电极材料这一传统挑战,本研究采用了一种稳健、可推广且经济高效的数据驱动建模和优化框架。采用低差异拉丁超立方和准蒙特卡罗方法的新型采样策略生成了一个小规模、高保真的数据集,该数据集具有重要的空间填充特性,可用于训练有监督的机器学习模型。这项研究超越了传统方法,构建了两个代理模型:一个随机森林回归模型和一个梯度提升回归模型,作为优化的目标函数。将非支配排序遗传算法 II (NSGA-II) 集成到多目标优化中,有助于对代理模型进行详尽的探索,从而确定在特定操作条件下可提高能效 (EE) 的电极设计。在探索代用模型时应用 NSGA-II 不仅有助于发现现实的设计组合,还能巧妙地管理特征之间的权衡。根据从优化框架中获得的洞察力,制造出了新的电极类型,显示出 EE 的明显改善,并验证了机器学习的建议。这项研究强调了提高碳材料导电性和孔隙率的关键作用,显示了它们与提高 EE 的直接相关性。总之,这项研究在开发更高效、更实用的 VRFB 方面迈出了重要一步,为可再生能源存储领域做出了宝贵贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
1.80
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0.00%
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