Intermediate Temperature Superprotonic Conductivity beyond 10<sup>–2</sup> S cm<sup>–1</sup> with Low Proton Transfer Energy Barrier in a Metal–Organic Framework
Debolina Mukherjee, Shyam Chand Pal, Yasaswini Oruganti, Byoung Gwan Lee, Arun K. Manna, Dae‐Woon Lim, Madhab C. Das
Abstract
Design of solid-state proton conductors (SSPCs) operating at low to intermediate temperatures (25–60 °C) is desirable to address the thermal-management issue in proton-exchange membrane fuel cells (PEMFCs). Among the various approaches in designing SSPCs, “ orthophosphate coordination ” is highly unexplored in MOFs. Herein, a new MOF: IITKGP-103 {[Ag(hmta)H 2 PO 4 ]·2H 2 O} n with orthophosphate coordinated to Ag(I) center, is rationally designed. Synchronous alignments of two amphiprotic proton sources/carriers (H 2 PO 4 – and water) resulted in highly extended H-bonded networks that eased the fastest protonic relay (σ = 2.92 × 10 –2 S cm –1 ) at intermediate temperature (60 °C) with smaller proton transfer (PT) energy barriers for both the identified conducting channels (∼5.6 kcal mol –1 for intralayer and ∼2.2 kcal mol –1 for interlayer ), making MOF: IITKGP-103 the best performing intermediate temperature SSPC material. In contrast, nonsynchronous alignments of proton carriers in another orthophosphate coordinated framework Ag-bpy (1) resulted in 100 times lower conductivity with higher barriers (∼6.2 and ∼10.9 kcal mol –1 ) as validated through quantum-tunneling analysis.