Li-Ions Pre-intercalation Strategy of Manganese Oxides for Capacitive Deionization-Based Selective Lithium Extraction From Low-grade Brine
Article
Overview
Research
Identity
Additional Document Info
View All
Overview
abstract
In this work, Li preintercalated λ-LixMnO2 with tunable lithium content is synthesized, which exhibited excellent electrochemical performance and dual-mode electrochemical storage behavior. Double-layer capacitive and diffusion-controlled Faradaic processes play a role in the charge–discharge process, leading to an enhanced lithium selective adsorption capacity. When employed in hybrid capacitive deionization (HCDI), the λ-Li1.5MnO2 obtains a Li adsorption capacity of 33.68 mg g−1 in 32.74 mg L−1 Li ion solution and low energy consumption of 0.19 Wh g−1. Moreover, the λ-Li1.5MnO2 electrode exhibited outstanding cycling stability, with a significant capacity retention rate of 80%25 and a manganese mass dissolution rate of 1.2%25 over 100 intercalation/deintercalation cycles. λ-Li1.5MnO2 achieved outstanding lithium selectivity with a separation factor ≈32.7 at a Mg2 /Li molar ratio of 30 in synthetic brine. Importantly, λ-Li1.5MnO2 achieved a high Li adsorption capacity and good selectivity in Lop Nor, the low-grade original brine of the XieLi salt flats, making it a candidate electrode for lithium extraction from low-grade original brine. The pre-intercalation strategy offers a viable option for rationalizing other intercalation electrode materials for electrochemical lithium extraction from low-grade original brine.
