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提高卤水开采中的锂回收率:整合下一代情感人工智能和可解释机器学习以预测基于冠醚的分级纳米材料中的吸附能。

Enhancing Li recovery in brine mining: integrating next-gen emotional AI and explainable ML to predict adsorption energy in crown ether-based hierarchical nanomaterials.

作者信息

Abba Sani I, Usman Jamilu, Abdulazeez Ismail, Yogarathinam Lukka Thuyavan, Usman A G, Lawal Dahiru, Salhi Billel, Baig Nadeem, Aljundi Isam H

机构信息

Interdisciplinary Research Centre for Membranes and Water Security, King Fahd University of Petroleum and Minerals Dhahran 31261 Saudi Arabia

Operational Research Centre in Healthcare, Near East University TRNC Mersin 10 99138 Nicosia Turkey.

出版信息

RSC Adv. 2024 May 8;14(21):15129-15142. doi: 10.1039/d4ra02385d. eCollection 2024 May 2.

DOI:10.1039/d4ra02385d
PMID:38720979
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11078271/
Abstract

Artificial intelligence (AI) is being employed in brine mining to enhance the extraction of lithium, vital for the manufacturing of lithium-ion batteries, through improved recovery efficiencies and the reduction of energy consumption. An innovative approach was proposed combining Emotional Neural Networks (ENN) and Random Forest (RF) algorithms to elucidate the adsorption energy (AE) (kcal mol) of Li ions by utilizing crown ether (CE)-incorporated honeycomb 2D nanomaterials. The screening and feature engineering analysis of honeycomb-patterned 2D materials and individual CE were conducted through Density Functional Theory (DFT) and Gaussian 16 simulations. The selected honeycomb-patterned 2D materials encompass graphene, silicene, and hexagonal boron nitride, while the specific CEs evaluated are 15-crown-5 and 18-crown-6. The crown-passivated 2D surfaces held a significant adsorption site through van der Waals forces for efficient recovery of Li ions. ENN predicted the targeted adsorption sites with high precision and minimal deviation. The eTAI (XAI) based Shapley Additive exPlanations (SHAP) was also explored for insight into the feature importance of CE embedded 2D nanomaterials for the recovery of Li ions. The extreme gradient boosting algorithm (XGBoost) model demonstrated a RT-2-MAPE = 0.4618% and ENN-2-MAPE = 0.4839% for the feature engineering analysis. This research would be an insight into the AI-driven nanotechnology that presents a viable and sustainable approach for the extraction of natural resources through the application of brine mining.

摘要

人工智能(AI)正被应用于盐水采矿中,通过提高回收效率和降低能源消耗,来加强对锂离子电池制造至关重要的锂的提取。提出了一种创新方法,将情感神经网络(ENN)和随机森林(RF)算法相结合,以利用掺入冠醚(CE)的蜂窝状二维纳米材料阐明锂离子的吸附能(AE)(千卡/摩尔)。通过密度泛函理论(DFT)和高斯16模拟对蜂窝状二维材料和单个CE进行了筛选和特征工程分析。选定的蜂窝状二维材料包括石墨烯、硅烯和六方氮化硼,而评估的特定CE是15-冠-5和18-冠-6。冠钝化的二维表面通过范德华力拥有一个重要的吸附位点,用于高效回收锂离子。ENN以高精度和最小偏差预测了目标吸附位点。还探索了基于eTAI(XAI)的Shapley加法解释(SHAP),以深入了解嵌入CE的二维纳米材料对锂离子回收的特征重要性。极端梯度提升算法(XGBoost)模型在特征工程分析中显示出RT-2-MAPE = 0.4618%和ENN-2-MAPE = 0.4839%。这项研究将为人工智能驱动的纳米技术提供见解,该技术通过应用盐水采矿为自然资源的提取提供了一种可行且可持续的方法。

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