Bioinspired interlaced wetting surfaces for continuous on-demand emulsion separation

Maintaining high separation performance during continuous emulsion separation remains a challenge. Herein, based on biomimetic coupling ideas, hole array interlaced wetting surfaces (HAIWSs) and mastoid array interlaced wetting surfaces (MAIWSs) were prepared by laser processing, electroless silver...

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Veröffentlicht in:	Journal of hazardous materials 2024-12, Vol.480, p.136011, Article 136011
Hauptverfasser:	Gao, Hanpeng, Qian, Haiyu, Meng, Zong, Chang, Siyu, Wang, Xi, Han, Zhiwu, Liu, Yan
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Sprache:	eng
Schlagworte:	Biomimetic biomimetics Emulsion separation emulsions filter cake industry Interface behavior Interlaced wettability Multi-hierarchical structure silver thiols wastewater treatment wettability
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creator	Gao, Hanpeng Qian, Haiyu Meng, Zong Chang, Siyu Wang, Xi Han, Zhiwu Liu, Yan
description	Maintaining high separation performance during continuous emulsion separation remains a challenge. Herein, based on biomimetic coupling ideas, hole array interlaced wetting surfaces (HAIWSs) and mastoid array interlaced wetting surfaces (MAIWSs) were prepared by laser processing, electroless silver deposition, thiol modification, and spraying for on-demand emulsion separation. When the separation is going on, randomly moving emulsion droplets are prone to being captured by holes or mastoids due to interlaced wettability. Under this unique interface behavior, the occurrence of filter cake and pore clogging is reduced, thus achieving both high efficiency (∼99.5 and ∼99.3 %). Meanwhile, the high flux can also be maintained (∼3212 and ∼3458 L m−2 h−1). Significantly better than surfaces without pores or mastoid structures. Further, the as-prepared surfaces also exhibit excellent recyclability. After 50 separation cycles, optimized HAIWS and MAIWS still maintained high efficiency (∼96.2 and ∼95.8 %) and high flux (∼3042 and ∼3164 L m−2 h−1), exceeding other surfaces without hole or mastoid structure. Notably, complex physical/chemical cleaning processes are avoided. Besides, even in harsh conditions, HAIWS and MAIWS still maintain excellent stability. The above strategy provides a novel mechanism for effective on-demand emulsion separation and is expected to encourage the creation of new-class separation devices for oily wastewater treatment in industry. [Display omitted] •Biomimetic multi-hierarchical structure surfaces.•Effective emulsion separation on demand.•Mechanism analysis of droplet movement.•Interlaced wettability for droplet capture,aggregation, and separation.•Provides a novel mechanism for effective emulsion separation.
doi_str_mv	10.1016/j.jhazmat.2024.136011
format	Article
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Herein, based on biomimetic coupling ideas, hole array interlaced wetting surfaces (HAIWSs) and mastoid array interlaced wetting surfaces (MAIWSs) were prepared by laser processing, electroless silver deposition, thiol modification, and spraying for on-demand emulsion separation. When the separation is going on, randomly moving emulsion droplets are prone to being captured by holes or mastoids due to interlaced wettability. Under this unique interface behavior, the occurrence of filter cake and pore clogging is reduced, thus achieving both high efficiency (∼99.5 and ∼99.3 %). Meanwhile, the high flux can also be maintained (∼3212 and ∼3458 L m−2 h−1). Significantly better than surfaces without pores or mastoid structures. Further, the as-prepared surfaces also exhibit excellent recyclability. After 50 separation cycles, optimized HAIWS and MAIWS still maintained high efficiency (∼96.2 and ∼95.8 %) and high flux (∼3042 and ∼3164 L m−2 h−1), exceeding other surfaces without hole or mastoid structure. Notably, complex physical/chemical cleaning processes are avoided. Besides, even in harsh conditions, HAIWS and MAIWS still maintain excellent stability. The above strategy provides a novel mechanism for effective on-demand emulsion separation and is expected to encourage the creation of new-class separation devices for oily wastewater treatment in industry. [Display omitted] •Biomimetic multi-hierarchical structure surfaces.•Effective emulsion separation on demand.•Mechanism analysis of droplet movement.•Interlaced wettability for droplet capture,aggregation, and separation.•Provides a novel mechanism for effective emulsion separation.</description><identifier>ISSN: 0304-3894</identifier><identifier>ISSN: 1873-3336</identifier><identifier>EISSN: 1873-3336</identifier><identifier>DOI: 10.1016/j.jhazmat.2024.136011</identifier><identifier>PMID: 39393316</identifier><language>eng</language><publisher>Netherlands: Elsevier B.V</publisher><subject>Biomimetic ; biomimetics ; Emulsion separation ; emulsions ; filter cake ; industry ; Interface behavior ; Interlaced wettability ; Multi-hierarchical structure ; silver ; thiols ; wastewater treatment ; wettability</subject><ispartof>Journal of hazardous materials, 2024-12, Vol.480, p.136011, Article 136011</ispartof><rights>2024</rights><rights>Copyright © 2024. 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Herein, based on biomimetic coupling ideas, hole array interlaced wetting surfaces (HAIWSs) and mastoid array interlaced wetting surfaces (MAIWSs) were prepared by laser processing, electroless silver deposition, thiol modification, and spraying for on-demand emulsion separation. When the separation is going on, randomly moving emulsion droplets are prone to being captured by holes or mastoids due to interlaced wettability. Under this unique interface behavior, the occurrence of filter cake and pore clogging is reduced, thus achieving both high efficiency (∼99.5 and ∼99.3 %). Meanwhile, the high flux can also be maintained (∼3212 and ∼3458 L m−2 h−1). Significantly better than surfaces without pores or mastoid structures. Further, the as-prepared surfaces also exhibit excellent recyclability. After 50 separation cycles, optimized HAIWS and MAIWS still maintained high efficiency (∼96.2 and ∼95.8 %) and high flux (∼3042 and ∼3164 L m−2 h−1), exceeding other surfaces without hole or mastoid structure. Notably, complex physical/chemical cleaning processes are avoided. Besides, even in harsh conditions, HAIWS and MAIWS still maintain excellent stability. The above strategy provides a novel mechanism for effective on-demand emulsion separation and is expected to encourage the creation of new-class separation devices for oily wastewater treatment in industry. 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subjects	Biomimetic biomimetics Emulsion separation emulsions filter cake industry Interface behavior Interlaced wettability Multi-hierarchical structure silver thiols wastewater treatment wettability
title	Bioinspired interlaced wetting surfaces for continuous on-demand emulsion separation
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