Nondestructive In Operando Imaging of Thin Film Composite Membrane Compaction Enhanced by AI-Based Segmentation

Jishan Wu; Yara Suleiman; Jinlong He; Minhao Xiao; Parisa Mahyari; Mingzhe Li; Lin Zhou; Yuanmiaoliang Chen; Hanqing Fan; N. A. Sreejith; Hariswaran Sitaraman; Marc Day; Ying Li; Jeffrey McCutcheon; Menachem Elimelech; Sina Shahbazmohamadi; Eric Hoek

doi:10.1021/acs.estlett.5c00529

Nondestructive In Operando Imaging of Thin Film Composite Membrane Compaction Enhanced by AI-Based Segmentation

Jishan Wu
, Yara Suleiman
, Jinlong He
, Minhao Xiao
, Parisa Mahyari
, Mingzhe Li
, Lin Zhou
, Yuanmiaoliang Chen
, Hanqing Fan
, N. A. Sreejith
, Hariswaran Sitaraman
, Marc Day
, Ying Li
, Jeffrey McCutcheon
, Menachem Elimelech
, Sina Shahbazmohamadi
, Eric Hoek

Computational Science

Research output: Contribution to journal › Article › peer-review

4 Scopus Citations

Abstract

Reverse osmosis (RO) membranes are essential for desalination and water reuse, yet their permeability declines in high-pressure applications due to membrane compaction. This study investigates the structural and functional responses of commercial brackish, seawater, and high-pressure RO membranes at applied pressures up to 120 bar using a multiscale, nondestructive in operando scanning electron microscopy (iSEM) imaging platform. The iSEM technique reveals progressive densification across the composite membrane structure, which correlates with observed declines in water and solute permeance. To quantify these structural changes with greater fidelity, we combined X-ray computed tomography with AI-based segmentation enabling precise analysis of pore size distribution and thickness of the polysulfone support layer. Compared to traditional thresholding, AI segmentation accurately delineates material phases and void spaces, enhancing the reproducibility and resolution of morphological assessments. The results demonstrate that compaction-induced reductions in porosity and thickness strongly impact membrane transport properties. These findings provide mechanistic insights into the compaction behavior of RO membranes and underscore the potential for advanced imaging and AI-driven data analysis to guide the design of next-generation membranes with improved mechanical resilience and operational longevity.

Original language	American English
Pages (from-to)	1069-1074
Number of pages	6
Journal	Environmental Science and Technology Letters
Volume	12
Issue number	8
DOIs	https://doi.org/10.1021/acs.estlett.5c00529
State	Published - 2025

NLR Publication Number

NREL/JA-2C00-96748

Keywords

AI segmentation
desalination
in operando imaging
reverse osmosis
SEM
XCT

Access to Document

10.1021/acs.estlett.5c00529

Cite this

Wu, J., Suleiman, Y., He, J., Xiao, M., Mahyari, P., Li, M., Zhou, L., Chen, Y., Fan, H., Sreejith, N. A., Sitaraman, H., Day, M., Li, Y., McCutcheon, J., Elimelech, M., Shahbazmohamadi, S., & Hoek, E. (2025). Nondestructive In Operando Imaging of Thin Film Composite Membrane Compaction Enhanced by AI-Based Segmentation. Environmental Science and Technology Letters, 12(8), 1069-1074. https://doi.org/10.1021/acs.estlett.5c00529

@article{198c7bba03a549429b9b773801709059,

title = "Nondestructive In Operando Imaging of Thin Film Composite Membrane Compaction Enhanced by AI-Based Segmentation",

abstract = "Reverse osmosis (RO) membranes are essential for desalination and water reuse, yet their permeability declines in high-pressure applications due to membrane compaction. This study investigates the structural and functional responses of commercial brackish, seawater, and high-pressure RO membranes at applied pressures up to 120 bar using a multiscale, nondestructive in operando scanning electron microscopy (iSEM) imaging platform. The iSEM technique reveals progressive densification across the composite membrane structure, which correlates with observed declines in water and solute permeance. To quantify these structural changes with greater fidelity, we combined X-ray computed tomography with AI-based segmentation enabling precise analysis of pore size distribution and thickness of the polysulfone support layer. Compared to traditional thresholding, AI segmentation accurately delineates material phases and void spaces, enhancing the reproducibility and resolution of morphological assessments. The results demonstrate that compaction-induced reductions in porosity and thickness strongly impact membrane transport properties. These findings provide mechanistic insights into the compaction behavior of RO membranes and underscore the potential for advanced imaging and AI-driven data analysis to guide the design of next-generation membranes with improved mechanical resilience and operational longevity.",

keywords = "AI segmentation, desalination, in operando imaging, reverse osmosis, SEM, XCT",

author = "Jishan Wu and Yara Suleiman and Jinlong He and Minhao Xiao and Parisa Mahyari and Mingzhe Li and Lin Zhou and Yuanmiaoliang Chen and Hanqing Fan and Sreejith, \{N. A.\} and Hariswaran Sitaraman and Marc Day and Ying Li and Jeffrey McCutcheon and Menachem Elimelech and Sina Shahbazmohamadi and Eric Hoek",

year = "2025",

doi = "10.1021/acs.estlett.5c00529",

language = "American English",

volume = "12",

pages = "1069--1074",

journal = "Environmental Science and Technology Letters",

issn = "2328-8930",

publisher = "American Chemical Society",

number = "8",

}

Wu, J, Suleiman, Y, He, J, Xiao, M, Mahyari, P, Li, M, Zhou, L, Chen, Y, Fan, H, Sreejith, NA , Sitaraman, H , Day, M, Li, Y, McCutcheon, J, Elimelech, M, Shahbazmohamadi, S & Hoek, E 2025, 'Nondestructive In Operando Imaging of Thin Film Composite Membrane Compaction Enhanced by AI-Based Segmentation', Environmental Science and Technology Letters, vol. 12, no. 8, pp. 1069-1074. https://doi.org/10.1021/acs.estlett.5c00529

TY - JOUR

T1 - Nondestructive In Operando Imaging of Thin Film Composite Membrane Compaction Enhanced by AI-Based Segmentation

AU - Wu, Jishan

AU - Suleiman, Yara

AU - He, Jinlong

AU - Xiao, Minhao

AU - Mahyari, Parisa

AU - Li, Mingzhe

AU - Zhou, Lin

AU - Chen, Yuanmiaoliang

AU - Fan, Hanqing

AU - Sreejith, N. A.

AU - Sitaraman, Hariswaran

AU - Day, Marc

AU - Li, Ying

AU - McCutcheon, Jeffrey

AU - Elimelech, Menachem

AU - Shahbazmohamadi, Sina

AU - Hoek, Eric

PY - 2025

Y1 - 2025

N2 - Reverse osmosis (RO) membranes are essential for desalination and water reuse, yet their permeability declines in high-pressure applications due to membrane compaction. This study investigates the structural and functional responses of commercial brackish, seawater, and high-pressure RO membranes at applied pressures up to 120 bar using a multiscale, nondestructive in operando scanning electron microscopy (iSEM) imaging platform. The iSEM technique reveals progressive densification across the composite membrane structure, which correlates with observed declines in water and solute permeance. To quantify these structural changes with greater fidelity, we combined X-ray computed tomography with AI-based segmentation enabling precise analysis of pore size distribution and thickness of the polysulfone support layer. Compared to traditional thresholding, AI segmentation accurately delineates material phases and void spaces, enhancing the reproducibility and resolution of morphological assessments. The results demonstrate that compaction-induced reductions in porosity and thickness strongly impact membrane transport properties. These findings provide mechanistic insights into the compaction behavior of RO membranes and underscore the potential for advanced imaging and AI-driven data analysis to guide the design of next-generation membranes with improved mechanical resilience and operational longevity.

AB - Reverse osmosis (RO) membranes are essential for desalination and water reuse, yet their permeability declines in high-pressure applications due to membrane compaction. This study investigates the structural and functional responses of commercial brackish, seawater, and high-pressure RO membranes at applied pressures up to 120 bar using a multiscale, nondestructive in operando scanning electron microscopy (iSEM) imaging platform. The iSEM technique reveals progressive densification across the composite membrane structure, which correlates with observed declines in water and solute permeance. To quantify these structural changes with greater fidelity, we combined X-ray computed tomography with AI-based segmentation enabling precise analysis of pore size distribution and thickness of the polysulfone support layer. Compared to traditional thresholding, AI segmentation accurately delineates material phases and void spaces, enhancing the reproducibility and resolution of morphological assessments. The results demonstrate that compaction-induced reductions in porosity and thickness strongly impact membrane transport properties. These findings provide mechanistic insights into the compaction behavior of RO membranes and underscore the potential for advanced imaging and AI-driven data analysis to guide the design of next-generation membranes with improved mechanical resilience and operational longevity.

KW - AI segmentation

KW - desalination

KW - in operando imaging

KW - reverse osmosis

KW - SEM

KW - XCT

U2 - 10.1021/acs.estlett.5c00529

DO - 10.1021/acs.estlett.5c00529

M3 - Article

SN - 2328-8930

VL - 12

SP - 1069

EP - 1074

JO - Environmental Science and Technology Letters

JF - Environmental Science and Technology Letters

IS - 8

ER -

Nondestructive In Operando Imaging of Thin Film Composite Membrane Compaction Enhanced by AI-Based Segmentation

Abstract

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Keywords

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