Overcoming Synthetic Challenges: Solvent-Free Construction of a Cr–Phosphonate Framework with High Stability and Proton Conductivity
Fan Yang, Zhiwen Shi, Lipeng Si, Zhengqing Zhang, Jing Ju, Junliang Sun, Xiaoge Wang, Chongli Zhong
Abstract
The sustainable, green, solvent-free synthesis offers new pathways for constructing high-performance metal–organic frameworks (MOFs) that are challenging to access via conventional solution chemistry. Herein, using this approach, we synthesize a highly stable crystalline chromium–phosphonate MOF, TGU-20, while a different counterpart, TGU-30, was obtained in the solution with the same ligand and Cr 3+ ion. Interestingly, the three-dimensional electron diffraction technique reveals that TGU-20 adopts a monodeprotonated bidentate phosphonate coordination mode, forming ultranarrow channels densely lined with proton-donating acid P–OH groups. In contrast, TGU-30 features a mixed mono/dideprotonated coordination, resulting in large channels with sparse P–OH sites. As a result, TGU-20 displays exceptional proton conductivity of over 10 –2 S cm –1 at 100% RH with a very low activation energy of 0.10 eV, reaching record-high room-temperature proton conductivity among phosphonate MOFs and 2 orders of magnitude higher than that of TGU-30. Additionally, both MOFs exhibit high stability in harsh conditions, including highly concentrated strong acid. The solvent-free synthesis not only directly yields a chromium–phosphonate MOF for the first time but also opens a mild and green avenue for selectively tuning metal–ligand coordination in reticular chemistry.