Nature Communications (Jul 2024)

High-efficiency dysprosium-ion extraction enabled by a biomimetic nanofluidic channel

  • Weiwen Xin,
  • Yanglansen Cui,
  • Yongchao Qian,
  • Tianchi Liu,
  • Xiang-Yu Kong,
  • Haoyang Ling,
  • Weipeng Chen,
  • Zhehua Zhang,
  • Yuhao Hu,
  • Lei Jiang,
  • Liping Wen

DOI
https://doi.org/10.1038/s41467-024-50237-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract Biological ion channels exhibit high selectivity and permeability of ions because of their asymmetrical pore structures and surface chemistries. Here, we demonstrate a biomimetic nanofluidic channel (BNC) with an asymmetrical structure and glycyl-L-proline (GLP) -functionalization for ultrafast, selective, and unidirectional Dy3+ extraction over other lanthanide (Ln3+) ions with very similar electronic configurations. The selective extraction mainly depends on the amplified chemical affinity differences between the Ln3+ ions and GLPs in nanoconfinement. In particular, the conductivities of Ln3+ ions across the BNC even reach up to two orders of magnitude higher than in a bulk solution, and a high Dy3+/Nd3+ selectivity of approximately 60 could be achieved. The designed BNC can effectively extract Dy3+ ions with ultralow concentrations and thereby purify Nd3+ ions to an ultimate content of 99.8 wt.%, which contribute to the recycling of rare earth resources and environmental protection. Theoretical simulations reveal that the BNC preferentially binds to Dy3+ ion due to its highest affinity among Ln3+ ions in nanoconfinement, which attributes to the coupling of ion radius and coordination matching. These findings suggest that BNC-based ion selectivity system provides alternative routes to achieving highly efficient lanthanide separation.