应用机器学习和遗传算法加速优化乙醇生产。

IF 8.2 1区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Science of the Total Environment Pub Date : 2024-12-10 Epub Date: 2024-10-20 DOI:10.1016/j.scitotenv.2024.177027
Xu Yang, Nianhua Chen, Hui Yu, Xinyue Liu, Yujie Feng, Defeng Xing, Yushi Tian
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引用次数: 0

摘要

玉米秸秆可通过同步糖化和共发酵(SSCF)生产生物乙醇。然而,通过一种经济有效的策略从众多可能性中确定最佳操作参数组合,以提高 SSCF 的效率和产量,仍然具有挑战性。我们构建了极梯度提升(XGB)和深度神经网络(DNN)模型,仅通过五个输入变量就能准确预测乙醇产量,准确率大于 83%。随后,XGB 和 DNN 模型与遗传算法(GA)相结合,成为新的优化策略。实验验证表明,新策略能快速、准确地优化 SSCF 乙醇生产系统的效率和产量。此外,通过对 XGB 的综合可解释性分析和微生物生态学分析,研究了潜在的优化机制。其中,酶溶液体积(61.7%)占主导地位,其次是时间(12.9%)、底物浓度(10.4%)、温度(7.7%)和接种物体积(7.3%)。这种高效、精确的算法设计策略可以大大减少优化生化系统所需的时间。
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Applying machine learning and genetic algorithms accelerated for optimizing ethanol production.

Corn straws can produce bioethanol via simultaneous saccharification and co-fermentation (SSCF). However, identifying optimal combinations of operating parameters from numerous possibilities through a cost-effective strategy to improve SSCF efficiency and yield remains challenging. The eXtreme Gradient Boost (XGB) and deep neural network (DNN) models were constructed to accurately predict ethanol yield from only five input variables, achieving >83 % accuracy. Subsequently, the XGB and the DNN models were merged with the genetic algorithm (GA) as the new optimization strategies. Experimental validation showed that the new strategy optimize the efficiency and yield of the SSCF ethanol production system quickly and accurately. Moreover, the potential optimization mechanism was investigated through the comprehensive interpretability analysis for XGB and the microbial ecology analysis. Enzyme Solution Volume (61.7 %) dominated, followed by time (12.9 %), substrate concentration (10.4 %), temperature (7.7 %), and inoculum volume (7.3 %). This efficient and accurate algorithm design strategy can significantly reduce the time required to optimize biochemical systems.

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来源期刊
Science of the Total Environment
Science of the Total Environment 环境科学-环境科学
CiteScore
17.60
自引率
10.20%
发文量
8726
审稿时长
2.4 months
期刊介绍: The Science of the Total Environment is an international journal dedicated to scientific research on the environment and its interaction with humanity. It covers a wide range of disciplines and seeks to publish innovative, hypothesis-driven, and impactful research that explores the entire environment, including the atmosphere, lithosphere, hydrosphere, biosphere, and anthroposphere. The journal's updated Aims & Scope emphasizes the importance of interdisciplinary environmental research with broad impact. Priority is given to studies that advance fundamental understanding and explore the interconnectedness of multiple environmental spheres. Field studies are preferred, while laboratory experiments must demonstrate significant methodological advancements or mechanistic insights with direct relevance to the environment.
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