Hierarchical isoporous membrane filters for simultaneous reduction of pressure drop and efficient removal of nanoscale airborne contaminants

Applied materials today Pub Date : 2023-08-01 DOI:10.1016/j.apmt.2023.101856

Him Cheng Wong, Shi Ke Ong, Erik Birgersson, Mei Chee Tan, Hong Yee Low

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Abstract

Isoporous membranes with well-defined pore architectures offer a unique design approach to achieve a multi-scale porous network. For instance, isoporous membranes with progressively smaller pore sizes can be stacked to create a hierarchical pore network in which each length scale and the gradient of the pore network are deterministic by design. In this paper, we introduce a hierarchically-arranged multilayer isoporous air filter that comprises an ultrathin (thickness <1μm) nanoporous active filtration layer and a microporous support layer. To maximize airflow and thereby reduce pressure drop across the membrane, we engineered a gap between the nanoporous and microporous membranes by designing and fabricating microscale spacer structures akin to feed spacers used in spiral wound reverse osmosis membranes. We demonstrated that such hierarchical isoporous membranes with integrated spacers (HIM-S) can retain high filtration efficiency (>95%) for ultrafine, most penetrating particle size (MPPS) while simultaneously reducing the pressure drop across the membrane (by ∼86%).

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分级等孔膜过滤器同时减少压力降和有效去除纳米级空气污染物

具有明确孔隙结构的等孔膜提供了一种独特的设计方法来实现多尺度多孔网络。例如，孔径逐渐变小的等孔膜可以堆叠起来，形成分层的孔隙网络，其中每个长度尺度和孔隙网络的梯度都是设计确定的。在本文中，我们介绍了一种分层排列的多层等孔空气过滤器，该过滤器包括超薄(厚度95%)，用于超细，穿透性最强的粒径(MPPS)，同时降低了膜上的压降(约86%)。

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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Applied materials today

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