Understanding and Designing a High-Performance Ultrafiltration Membrane Using Machine Learning

Gao, Haiping; Zhong, Shifa; Dangayach, Raghav; Chen, Yongsheng

doi:10.1021/acs.est.2c05404

Cited by 12 publications

(7 citation statements)

References 63 publications

(78 reference statements)

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“…Data-driven research has received wide attention in the scientific community and has great potential in improving the design of materials. − This study serves as a proof-of-concept for applying a meta-analytical approach to synthesize pre-existing data to determine patterns and make predictions, thereby obtaining a better understanding of the property–aggregation relationships of nanomaterials, which will be required for the development of accurate predictive models to estimate nanomaterial aggregation. This meta-analysis focused on carbon nanomaterials, and future analysis can include more types of nanomaterials (e.g., metal nanoparticles and nanoplastics) to evaluate the generalizability of the findings in this analysis.…”

Section: Discussionmentioning

confidence: 99%

“…Other than the aggregation behavior of nanomaterials, their electronic structure and chemical activity are also property-dependent, and leveraging a meta-analytic approach to discover and define such relationships is well-suited . Also, with more data being generated, future studies could utilize more advanced meta-analytic techniques, such as machine learning , to better understand the interplay of multiple properties on the aggregation of nanomaterials and to provide potential practical aid in the design of nanomaterials.…”

Section: Discussionmentioning

confidence: 99%

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A Meta-Analysis to Revisit the Property–Aggregation Relationships of Carbon Nanomaterials: Experimental Observations versus Predictions of the DLVO Theory

Peng,

Liao,

Jiang

2024

Langmuir

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Contradicting relationships between physicochemical properties of nanomaterials (e.g., size and ζ-potential) and their aggregation behavior have been constantly reported in previous literature, and such contradictions deviate from the predictions of the classic Derjaguin−Landau−Verwey−Overbeek (DLVO) theory. To resolve such controversies, in this work, we employed a meta-analytic approach to synthesize the data from 46 individual studies reporting the critical coagulation concentration (CCC) of two carbon nanomaterials, namely, graphene oxide (GO) and carbon nanotube (CNT). The correlations between CCC and material physicochemical properties (i.e., size, ζ-potential, and surface functionalities) were examined and compared to the theoretical predictions. Results showed that the CCC of electrostatically stabilized carbon nanomaterials increased with decreasing nanomaterial size when their hydrodynamic sizes were smaller than ca. 200 nm. This is qualitatively consistent with the prediction of the DLVO theory but with a smaller threshold size than the predicted 2 μm. Above the threshold size, the material ζ-potential can be correlated to CCC for nanomaterials with moderate/low surface charge, in agreement with the DLVO theory. The correlation was not observed for highly charged nanomaterials because of their underestimated surface potential by the ζ-potential. Furthermore, a correlation between the C/O ratio and CCC was observed, where a lower C/O ratio resulted in a higher CCC. Overall, our findings rationalized the inconsistency between experimental observation and theoretical prediction and provided essential insights into the aggregation behavior of nanomaterials in water, which could facilitate their rational design.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

A Meta-Analysis to Revisit the Property–Aggregation Relationships of Carbon Nanomaterials: Experimental Observations versus Predictions of the DLVO Theory

Peng,

Liao,

Jiang

2024

Langmuir

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“…After a ML model is trained to predict membrane properties in the supervised manner, the SHAP package can be used to quantitatively analyze the correlation between the properties and membrane features. 36 In the work of Yang et al 33 (Figure 3), the SHAP value was used to interpret the multitask gas permeability prediction by a random forest (RF) and deep neural network (DNN) ensemble model. The models were trained to predict the permeability of 6 different gases (He, H 2 , O 2 , N 2 , CO 2 , and CH 4 ) through polymeric membranes.…”

Section: Membranes Using Xaimentioning

confidence: 99%

“…The SHapley Additive exPlanations (SHAP) package is a unified framework built on the basis of Shapley value to interpret ML predictions. After a ML model is trained to predict membrane properties in the supervised manner, the SHAP package can be used to quantitatively analyze the correlation between the properties and membrane features . In the work of Yang et al (Figure ), the SHAP value was used to interpret the multitask gas permeability prediction by a random forest (RF) and deep neural network (DNN) ensemble model.…”

Section: Data-driven Understanding Of Membranes Using Xaimentioning

confidence: 99%

Machine Learning in Membrane Design: From Property Prediction to AI-Guided Optimization

Cao,

Barati Farimani,

Ock

et al. 2024

Nano Lett.

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Porous membranes, either polymeric or two-dimensional materials, have been extensively studied because of their outstanding performance in many applications such as water filtration. Recently, inspired by the significant success of machine learning (ML) in many areas of scientific discovery, researchers have started to tackle the problem in the field of membrane design using data-driven ML tools. In this Mini Review, we summarize research efforts on three types of applications of machine learning in membrane design, including (1) membrane property prediction using ML, (2) gaining physical insight and drawing quantitative relationships between membrane properties and performance using explainable artificial intelligence, and (3) ML-guided design, optimization, or virtual screening of membranes. On top of the review of previous research, we discuss the challenges associated with applying ML for membrane design and potential future directions.

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“…Sensitivity analysis revealed that simulated permeability was more sensitive to changes in pore diameter than pore density (Figure 7b,c). Further studies, perhaps involving machine learning (ML) [46], could help elucidate how fabrication conditions and other structural parameters (e.g., pore connectivity, macrovoids in the substructure, and separation layer thickness) contribute to the experimentally observed property profiles, bringing us one step closer to realizing inverted designer cycles in the making of SNIPS-based UF membranes.…”

Section: Perspectives On Single-component Isv Snips: the Inverted Des...mentioning

confidence: 99%

Non-Equilibrium Block Copolymer Self-Assembly Based Porous Membrane Formation Processes Employing Multicomponent Systems

Tsaur

Wiesner

2023

Polymers

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Porous polymer-derived membranes are useful for applications ranging from filtration and separation technologies to energy storage and conversion. Combining block copolymer (BCP) self-assembly with the industrially scalable, non-equilibrium phase inversion technique (SNIPS) yields membranes comprising periodically ordered top surface structures supported by asymmetric, hierarchical substructures that together overcome performance tradeoffs typically faced by materials derived from equilibrium approaches. This review first reports on recent advances in understanding the top surface structural evolution of a model SNIPS-derived system during standard membrane formation. Subsequently, the application of SNIPS to multicomponent systems is described, enabling pore size modulation, chemical modification, and transformation to non-polymeric materials classes without compromising the structural features that define SNIPS membranes. Perspectives on future directions of both single-component and multicomponent membrane materials are provided. This points to a rich and fertile ground for the study of fundamental as well as applied problems using non-equilibrium-derived asymmetric porous materials with tunable chemistry, composition, and structure.

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Understanding and Designing a High-Performance Ultrafiltration Membrane Using Machine Learning

Cited by 12 publications

References 63 publications

A Meta-Analysis to Revisit the Property–Aggregation Relationships of Carbon Nanomaterials: Experimental Observations versus Predictions of the DLVO Theory

A Meta-Analysis to Revisit the Property–Aggregation Relationships of Carbon Nanomaterials: Experimental Observations versus Predictions of the DLVO Theory

Machine Learning in Membrane Design: From Property Prediction to AI-Guided Optimization

Non-Equilibrium Block Copolymer Self-Assembly Based Porous Membrane Formation Processes Employing Multicomponent Systems

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