Organic anion-intercalation boosting intrinsic Cl− capture capability of layered double hydroxide anode for enhanced capacitive deionization

Layered double hydroxides (LDH) hold great promise as capacitive deionization (CDI) anode owing to high Cl - capture capacity and abundant interlamellar ions transport channels. However, their narrow interlayer spacing results in sluggish ions diffusion and huge volume variation during Cl - adsorption/desorption, which become worse owing to large ionic radius of Cl - . Herein, we reveal the significant effectiveness of organic anions intercalation on boosting intrinsic Cl - capture capabilities of LDH anode. Compared with traditional inorganic anions-intercalated LDH anode, organic anion-intercalated LDH possess expanded interlayer spacing and increased proportion of highly active divalent metal ions in the host layer. Theoretical calculations unveil that organic anion intercalation endow LDH with stronger Cl - capture ability, faster ions diffusion behaviors, and stronger bonding strength with positively charged host layers. As expected, the prepared seven kinds of organic anion-intercalated LDH anodes all manifest fast pseudocapacitive reaction kinetics and enhanced desalination performance; particularly, sodium dodecyl sulfate (SDS) intercalated LDH (LDH-SDS) anode exhibits large desalination capacity of 58.6 mg g -1 and excellent cyclic stability (76.9% retention ratio over 300 cycles), surpassing most of previously reported LDH-based CDI anodes. A series of in-situ/ex-situ characterizations further reveal outstanding structural stability and electrochemical reversibility of LDH-SDS anode. This work demonstrates great potential of crystal modulation on improving intrinsic ions capture capability of LDH and pave new insights for developing advanced CDI electrode. An organic anions intercalation strategy is proposed on the LDH anode for capacitive deionization, which demonstrate great effectiveness on boosting the intrinsic Cl - capture capabilities of LDH. • Organic anions-intercalation is applied for boosting intrinsic Cl - capture of LDH. • Enlarged interlayer spacing improves the electrochemical stability and Cl - transfer. • Increased proportion of divalent metal ions enhances electrochemical activity of LDH. • LDH-SDS manifest large SAC of 58.6 mg g -1 and high retention of 76.9% for 300 cycles.