Preparation of polyacrylonitrile-based nanofiber mats by electrospinning for uranium recovery

IF 2.4 4区生物学 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Journal of chemical technology and biotechnology Pub Date : 2025-08-19 DOI:10.1002/jctb.70042

Sündüz Alemdar, Nursel Pekel Bayramgil

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Abstract

BACKGROUND

Seawater mining of uranium in a sustainable manner is an emerging approach to meet long-term nuclear energy requirements. Amidoxime-functionalized polymers are of particular interest because of their high binding affinity for uranyl ions. Nevertheless, their low reusability and low mechanical stability make them impractical. This study discusses the preparation and performance evaluation of amidoxime-functionalized electrospun polyacrylonitrile (PAN) and polyurethane (PU) nanofiber mats as adsorbents for uranium (VI) adsorption.

RESULTS

PAN and PU blends were electrospun into composite nanofiber mats, which were amidoximated for nitrile groups. Structural, morphological, and thermal analyses were carried out by FT-IR, SEM, XRD, TGA, and DSC analyses. Amidoxime conversion was established by FT-IR with 94% efficiency. Uranium adsorption experiments in pH 4.1 and 25 °C conditions showed the maximum capacity of 435 mg g⁻¹ for PU-PAO nanofibers. Although pure PAO mats had a slightly higher capacity (495 mg g⁻¹), they could not be recycled easily. This contrasts with PU-PAO mats, which did not lose their integrity and could be cycled up to six times without losing their performance substantially.

CONCLUSION

PU addition improved mechanical stability and handleability without compromising the high adsorption capability of amidoxime-functionalized nanofibers. These findings validate the use of PU-PAO composite nanofibers as efficient and sustainable adsorbents for uranium recovery from aqueous systems, like seawater. Their performance vs. durability ratio presents a promising direction towards industrially viable and scalable uranium recovery technologies. © 2025 Society of Chemical Industry (SCI).

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静电纺丝法制备用于铀回收的聚丙烯腈基纳米纤维垫

以可持续的方式海水开采铀是满足长期核能需求的一种新兴方法。偕胺肟功能化聚合物因其对铀酰离子的高结合亲和力而受到特别关注。然而，它们的低可重用性和低机械稳定性使它们不切实际。研究了偕胺肟功能化聚丙烯腈（PAN）和聚氨酯（PU）纳米纤维毡的制备及其吸附铀（VI）的性能评价。结果PAN和PU共混物经静电纺丝制成复合纳米纤维垫，并对其腈基进行氨基肟化处理。通过FT-IR、SEM、XRD、TGA和DSC对其进行了结构、形态和热分析。红外光谱法测定偕胺肟的转化率为94%。在pH 4.1和25℃条件下，PU-PAO纳米纤维吸附铀的最大容量为435 mg g−1。虽然纯PAO垫具有略高的容量（495 mg g−1），但它们不容易回收。这与PU-PAO垫形成对比，PU-PAO垫不会失去其完整性，并且可以循环多达六次而不会大大降低其性能。结论PU的加入在不影响偕胺肟功能化纳米纤维高吸附性能的前提下，提高了纳米纤维的力学稳定性和可操作性。这些发现验证了PU-PAO复合纳米纤维作为有效和可持续的吸附剂从水系统（如海水）中回收铀。它们的性能与耐久性比为工业上可行和可扩展的铀回收技术提供了一个有希望的方向。©2025化学工业学会（SCI）。

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来源期刊

Journal of chemical technology and biotechnology 工程技术-工程：化工

CiteScore

7.00

自引率

5.90%

发文量

268

审稿时长

1.7 months

期刊介绍： Journal of Chemical Technology and Biotechnology(JCTB) is an international, inter-disciplinary peer-reviewed journal concerned with the application of scientific discoveries and advancements in chemical and biological technology that aim towards economically and environmentally sustainable industrial processes.