Efficient Lithium Recovery from Water Using Polyamide Thin-Film Nanocomposite (TFN) Membrane Modified with Positively Charged Silica Nanoparticles

IF 8.3 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

ACS Applied Materials & Interfaces Pub Date : 2024-11-20 DOI:10.1021/acsami.4c15939

Amir Aghaei, Muhammad Amirul Islam, Elham Jashni, Aria Khalili, Jae-Young Cho, Mohtada Sadrzadeh

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Abstract

The separation of Li⁺ from Mg²⁺ in salt-lake brines using nanofiltration (NF) has become the most popular solution to meet the rising demand for lithium, particularly driven by the extensive use of lithium-ion batteries. This study presents the fabrication of a uniquely designed polyamide (PA) thin-film nanocomposite (TFN) membranes with ultrahigh Li⁺/Mg²⁺ selectivity and enhanced water flux by covalently incorporating mixed ligands functionalized silica nanoparticles (F-SiO₂NPs) into the selective PA layer and covalently bonding them to the membrane surface. In this strategy, bare silica nanoparticles (SiO₂NPs) were functionalized with mixed superhydrophilic ligands, including primary amine and quaternary ammonium groups, resulting in a highly positive surface charge primarily from the quaternary ammonium groups and enabling covalent conjugation via amine groups. Among the F-SiO₂NP-incorporated membranes, M500 containing 500 ppm of F-SiO₂NPs exhibited the best performance. In a solution with 2000 ppm salt concentration (Li⁺/Mg²⁺ ratio of 1:20), the M500 membrane showed an improved Li⁺/Mg²⁺ selectivity of 7.41 compared to the nonmodified TFC membrane, which had a selectivity of 5.05. Further surface conjugation of the M500 sample with 1500 ppm of F-SiO₂NPs resulted in the C1500 membrane, demonstrating the best performance among all of the surface-modified membranes. C1500 showed an outstanding Li⁺/Mg²⁺ selectivity of 37.95, with a Mg²⁺ rejection of 95.7% and a Li⁺ rejection of −63.2%, and a water flux of 56.0 L m^–2 h^–1 at 70 psi. Notably, a 7.5-fold improvement in Li⁺/Mg²⁺ selectivity over the TFC membrane was achieved without compromising the water flux. This is evident from the nearly identical water flux values of the TFC, M500, and C1500 membranes, which were 57.1, 54.8, and 56.0 L m^–2 h^–1, respectively. Considering key factors for large-scale applications, such as cost-effectiveness, environmental impact, the abundance of synthetic precursors, and the maturity of synthesis and tailoring technologies, SiO₂NP-based modifications outperform all other reported approaches to date.

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使用带正电荷的二氧化硅纳米颗粒改性的聚酰胺薄膜纳米复合材料 (TFN) 膜从水中高效回收锂

使用纳滤（NF）分离盐湖卤水中的 Li+ 与 Mg2+，已成为满足日益增长的锂需求最受欢迎的解决方案，尤其是在锂离子电池广泛使用的推动下。本研究介绍了一种设计独特的聚酰胺（PA）薄膜纳米复合材料（TFN）膜的制备方法，这种膜具有超高的 Li+/Mg2+ 选择性，并能提高水通量。制备方法是将混合配体功能化的二氧化硅纳米颗粒（F-SiO2NPs）共价键合到选择性 PA 层，并将其共价键合到膜表面。在这一策略中，裸二氧化硅纳米粒子（SiO2NPs）被混合超亲水配体（包括伯胺基团和季铵基团）功能化，从而主要由季铵基团产生高度正表面电荷，并通过胺基团实现共价键合。在加入 F-SiO2NP 的膜中，含有 500 ppm F-SiO2NPs 的 M500 性能最好。在盐浓度为 2000 ppm 的溶液中（Li+/Mg2+ 比为 1:20），M500 膜对 Li+/Mg2+ 的选择性为 7.41，而未改性的 TFC 膜的选择性为 5.05。将 M500 样品与 1500 ppm 的 F-SiO2NPs 进一步表面共轭后，得到了 C1500 膜，在所有表面改性膜中表现出最佳性能。C1500 对 Li+/Mg2+ 的选择性高达 37.95，对 Mg2+ 的抑制率为 95.7%，对 Li+ 的抑制率为 -63.2%，在 70 psi 压力下的水通量为 56.0 L m-2 h-1。值得注意的是，与 TFC 膜相比，Li+/Mg2+ 选择性提高了 7.5 倍，而水通量却没有受到影响。这一点从 TFC、M500 和 C1500 膜几乎相同的水通量值（分别为 57.1、54.8 和 56.0 L m-2 h-1）中可见一斑。考虑到大规模应用的关键因素，如成本效益、环境影响、合成前体的丰富性以及合成和定制技术的成熟度，基于 SiO2NP 的改性方法优于迄今为止报道的所有其他方法。

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来源期刊

ACS Applied Materials & Interfaces 工程技术-材料科学：综合

CiteScore

16.00

自引率

6.30%

发文量

4978

审稿时长

1.8 months

期刊介绍： ACS Applied Materials & Interfaces is a leading interdisciplinary journal that brings together chemists, engineers, physicists, and biologists to explore the development and utilization of newly-discovered materials and interfacial processes for specific applications. Our journal has experienced remarkable growth since its establishment in 2009, both in terms of the number of articles published and the impact of the research showcased. We are proud to foster a truly global community, with the majority of published articles originating from outside the United States, reflecting the rapid growth of applied research worldwide.