Defect-Healed Carbon Nanomembranes for Enhanced Salt Separation: Scalable Synthesis and Performance.

Yao Z, Li P, Chen K, Yang Y, Beyer A, Westphal M, Niu QJ, Gölzhäuser A (2024)
ACS applied materials & interfaces 16(17): 22614–22621.

Zeitschriftenaufsatz | Veröffentlicht | Englisch
 
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Abstract / Bemerkung
Carbon nanomembranes (CNMs), with a high density of subnanometer channels, enable superior salt separation performance compared to conventional membranes. However, defects that occur during the synthesis and transfer processes impede their technical realization on a macroscopic scale. Here, we introduce a practical and scalable interfacial polymerization method to effectively heal defects while preserving the subnanometer pores within CNMs. The defect-healed freestanding CNMs show an exceptional performance in forward osmosis (FO), achieving a water flux of 105 L m-2 h-1 and a specific reverse salt flux of 0.1 g L-1 when measured with 1 M NaCl as draw solution. This water flux is 10 times higher than that of commercially available FO membranes, and the reverse salt flux is 70% lower. Through successful implementation of the defect-healing method and support optimization, we demonstrate the synthesis of fully functional, centimeter-scale CNM-based composite membranes showing high water permeance and a high salt rejection. Our defect-healing method presents a promising pathway to overcome limitations in CNM synthesis, advancing their potential for practical salt separation applications.
Erscheinungsjahr
2024
Zeitschriftentitel
ACS applied materials & interfaces
Band
16
Ausgabe
17
Seite(n)
22614–22621
eISSN
1944-8252
Page URI
https://pub.uni-bielefeld.de/record/2989108

Zitieren

Yao Z, Li P, Chen K, et al. Defect-Healed Carbon Nanomembranes for Enhanced Salt Separation: Scalable Synthesis and Performance. ACS applied materials & interfaces. 2024;16(17):22614–22621.
Yao, Z., Li, P., Chen, K., Yang, Y., Beyer, A., Westphal, M., Niu, Q. J., et al. (2024). Defect-Healed Carbon Nanomembranes for Enhanced Salt Separation: Scalable Synthesis and Performance. ACS applied materials & interfaces, 16(17), 22614–22621. https://doi.org/10.1021/acsami.4c00252
Yao, Zhen, Li, Pengfei, Chen, Kuo, Yang, Yang, Beyer, André, Westphal, Michael, Niu, Qingshan Jason, and Gölzhäuser, Armin. 2024. “Defect-Healed Carbon Nanomembranes for Enhanced Salt Separation: Scalable Synthesis and Performance.”. ACS applied materials & interfaces 16 (17): 22614–22621.
Yao, Z., Li, P., Chen, K., Yang, Y., Beyer, A., Westphal, M., Niu, Q. J., and Gölzhäuser, A. (2024). Defect-Healed Carbon Nanomembranes for Enhanced Salt Separation: Scalable Synthesis and Performance. ACS applied materials & interfaces 16, 22614–22621.
Yao, Z., et al., 2024. Defect-Healed Carbon Nanomembranes for Enhanced Salt Separation: Scalable Synthesis and Performance. ACS applied materials & interfaces, 16(17), p 22614–22621.
Z. Yao, et al., “Defect-Healed Carbon Nanomembranes for Enhanced Salt Separation: Scalable Synthesis and Performance.”, ACS applied materials & interfaces, vol. 16, 2024, pp. 22614–22621.
Yao, Z., Li, P., Chen, K., Yang, Y., Beyer, A., Westphal, M., Niu, Q.J., Gölzhäuser, A.: Defect-Healed Carbon Nanomembranes for Enhanced Salt Separation: Scalable Synthesis and Performance. ACS applied materials & interfaces. 16, 22614–22621 (2024).
Yao, Zhen, Li, Pengfei, Chen, Kuo, Yang, Yang, Beyer, André, Westphal, Michael, Niu, Qingshan Jason, and Gölzhäuser, Armin. “Defect-Healed Carbon Nanomembranes for Enhanced Salt Separation: Scalable Synthesis and Performance.”. ACS applied materials & interfaces 16.17 (2024): 22614–22621.

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