刘勇   Associate professor

研究方向:功能纳米材料的设计合成及其在海水淡化、杀菌、能量储存方面的应用。承担项目:国家自然科学基金青年项目(24万) 山东省自然科学基金青年项目(15万) 青岛市原创探索项目(20万) 无锡新吴区“飞凤人才”(100万) 无锡“太湖人才”(100万)获奖情况:中国石油和化工科技进步三等奖论文情况:以第一作者或通讯作者发表高水平SCI论文30余篇,包括Adv. Funct. Mater.、ACS Nano...Detials

Up-shifting the desalination rate limit of capacitive deionization via integrating chloride-capturing Bi nanocluster with flow-through cell architecture

Release time:2023-10-19  Hits:

  • Key Words:PERFORMANCE; ELECTRODES
  • Abstract:Faradic electrode-directed capacitive deionization (faradic-based CDI) as a green and eco-friendly technique is particularly promising in addressing the freshwater crisis, but its practical applications are plagued by the sluggish desalination kinetic. After deciphering its dynamic desalination process, two rate-determine steps (RDS) are identified, i.e., the ion diffusion inside the faradic electrode (RDS #1) and mass transfer process in the electrolyte (RDS #2). Therefore, we propose a synergetic strategy to upshift the desalination rate limit of faradic-based CDI through the integration of delicate material design with rational cell architecture. Specifically, deploying ultrasmall Bi nanoclusters impregnated carbon nanofibers (Bi NCs@CNF) as chloride-capturing electrodes and constructing a flow-through CDI (FT-CDI) system to accelerate the diffusion process (RDS #1) and shorten the mass transfer pathway (RDS #2), respectively. As expected, Bi NCs@CNF-based FT-CDI performs super-fast desalinization (0.56 mg g-1 s- 1) and excellent cyclic stability. Taken together, our study opens an avenue in upshifting the desalination kinetics of faradic-based CDI based on the joint power of both "material design" and "cell architecture", which may motivate the development of highly-efficient desalination systems.
  • Volume:460
  • Issue:
  • Translation or Not:no