<p>Nanoporous anion-conducting membranes have gained considerable interest for their potential to reduce resistance in electrochemical devices<sup><CitationRef AdditionalCitationIDS="CR2 CR3" CitationID="CR1">1</CitationRef>–<CitationRef CitationID="CR4">4</CitationRef></sup>. Current pore-forming methods, such as backbone engineering through polymers of intrinsic microporosity<sup><CitationRef CitationID="CR5">5</CitationRef>,<CitationRef CitationID="CR6">6</CitationRef></sup> or covalent organic and metal–organic frameworks<sup><CitationRef CitationID="CR7">7</CitationRef>,<CitationRef CitationID="CR8">8</CitationRef></sup>, however, suffer from limited structural control, mechanical fragility or demanding synthesis. Here we establish a supramolecular strategy that overcomes these limitations by constructing uniform, dynamic nanopores. Co-assembly of the rigid macrocyclic host cucurbit[7]uril with the cationic polymer guest quaternized poly(piperidinium-terphenyl) yields a robust network of nanometre-scale channels while simultaneously enhancing mechanical and chemical stability. The dynamic host–guest interactions allow the pore structure to fluctuate on picosecond and angstrom scales. This transient environment supports low-friction hydroxide migration through a Grotthuss mechanism, producing a marked enhancement in ionic conductivity. This bottom-up design principle provides a versatile new tool for molecularly engineering transport pathways and promises to advance electrochemical reactors with respect to energy efficiency, operational stability and the production of high-purity products.</p>

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Cucurbituril-based anion-conducting membranes with supramolecular nanopores

  • Ziang Xu,
  • Dongcheng Lin,
  • Haoyu Yin,
  • Qingqing Feng,
  • Fabrizia Foglia,
  • Yihan Zhen,
  • Adam Morris,
  • Quentin Berrod,
  • Maobin Pang,
  • Lida Huang,
  • Jing Liu,
  • Jiekang Tian,
  • Xiaonan Wang,
  • Chunming Yang,
  • Xingchen Tang,
  • Xi Zhang,
  • Baoguo Wang,
  • Haotian Wang,
  • Kai Liu

摘要

Nanoporous anion-conducting membranes have gained considerable interest for their potential to reduce resistance in electrochemical devices14. Current pore-forming methods, such as backbone engineering through polymers of intrinsic microporosity5,6 or covalent organic and metal–organic frameworks7,8, however, suffer from limited structural control, mechanical fragility or demanding synthesis. Here we establish a supramolecular strategy that overcomes these limitations by constructing uniform, dynamic nanopores. Co-assembly of the rigid macrocyclic host cucurbit[7]uril with the cationic polymer guest quaternized poly(piperidinium-terphenyl) yields a robust network of nanometre-scale channels while simultaneously enhancing mechanical and chemical stability. The dynamic host–guest interactions allow the pore structure to fluctuate on picosecond and angstrom scales. This transient environment supports low-friction hydroxide migration through a Grotthuss mechanism, producing a marked enhancement in ionic conductivity. This bottom-up design principle provides a versatile new tool for molecularly engineering transport pathways and promises to advance electrochemical reactors with respect to energy efficiency, operational stability and the production of high-purity products.