Flexible coordination network exhibiting water vapor−induced reversible switching between closed and open phases
That physisorbents can reduce the energy footprint of water vapor capture and release has attracted interest because of potential applications such as moisture harvesting, dehumidification, and heat pumps. In this context, sorbents exhibiting an S-shaped single-step water sorption isotherm are desirable, most of which are structurally rigid sorbents that undergo pore-filling at low relative humidity (RH), ideally below 30% RH. Here, we report that a new flexible one-dimensional (1D) coordination network, [Cu(HQS)(TMBP)] (H2HQS = 8-hydroxyquinoline-5-sulfonic acid and TMBP = 4,4′-trimethylenedipyridine), exhibits at least five phases: two as-synthesized open phases, α ⊃ H2O and β ⊃ MeOH; an activated closed phase (γ); CO2 (δ ⊃ CO2) and C2H2 (ϵ ⊃ C2H2) loaded phases. The γ phase underwent a reversible structural transformation to α ⊃ H2O with a stepped sorption profile (Type F-IV) when exposed to water vapor at <30% RH at 300 K. The hydrolytic stability of [Cu(HQS)(TMBP)] was confirmed by powder X-ray diffraction (PXRD) after immersion in boiling water for 6 months. Temperature-humidity swing cycling measurements demonstrated that working capacity is retained for >100 cycles and only mild heating (<323 K) is required for regeneration. Unexpectedly, the kinetics of loading and unloading of [Cu(HQS)(TMBP)] compares favorably with well-studied rigid water sorbents such as Al-fumarate, MOF-303, and CAU-10-H. Furthermore, a polymer composite of [Cu(HQS)(TMBP)] was prepared and its water sorption retained its stepped profile and uptake capacity over multiple cycles.
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ACS Applied Materials and Interfaces, 2022, 14, (34), pp. 39560–39566Publisher
American Chemical SocietyOther Funding information
M.J.Z. thanks the Science Foundation Ireland (16/IA/4624), the Irish Research Council (IRCLA/2019/167), and the European Research Council (ADG 885695). S.K. and K.O. gratefully acknowledge a KAKENHI Grant-in-Aid for Scientific Research (S) (JP18H05262, JP22H05005)), and (C) (22K05128) from the Japan Society for the Promotion of Science (JSPS) for supporting this research. We thank the Japan Synchrotron Radiation Research Institute (JASRI) (Proposal Nos. 2020A0649, 2021A1104, 2021A1682) for support of synchrotron XRD measurements. We also thank Dr. Naveen Kumar for synthesis of Al-fumarate and CAU-10-H and Dr. Kawaguchi of JASRI for experimental help at SPring-8.Also affiliated with
- Bernal Institute
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- Chemical Sciences