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New Material Could Slash Lithium Separation Costs by Orders of Magnitude

Researchers have developed a nanochannel material that separates lithium from other alkali metals 30-45 times more efficiently than existing methods. The breakthrough could significantly reduce processing costs for battery makers and ease supply constraints as global lithium demand surges.

Originaltitel: Friction-differentiated separation of alkali ions through two-dimensional nanochannels based on niobate perovskite

Abstrakt

The separation of alkali ions holds profound fundamental significance and immense application potential, particularly driven by the increasing demand for lithium in the era of sustainable energy. Previous approaches relying on the static factor (e.g., size, charge, solubility, adsorption affinities) prove inadequate in the separation of alkali ions due to their highly similar physicochemical properties. By leveraging the difference of friction-an intrinsic factor that incorporates the effects of ion-media correlation with channel or interlayer species during the migration, this work presents a nanofluidic tribology strategy utilizing a platform based on two-dimensional niobate perovskite nanochannels to achieve alkali ions separation. By generating ~42% difference of transport friction at nanonewton-scale, our channels amplify the separation factor between Li+/Na+ and K+/Na+ up to 33.1 ~ 45.9, surpassing the state-of-the-art artificial nanochannels by over an order of magnitude. Tuning the channel structural symmetry from herringbone to zigzag type modulates friction-differentiation, achieving a Li+ recognized selectivity (Li+/K+ ~ 28.0). This work establishes a paradigm for separation science through the lens of friction-differentiation and will inspire more advancing technology to secure strategic alkali ion resources critical for a sustainable future. A 2D nanochannel based on niobate perovskite enables alkali ion separation through a friction-differentiation strategy, offering a potential approach for lithium extraction relevant to renewable energy technologies.

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