Spatiotemporal Design of the Metal-Organic Framework DUT-8(M)

Switchable metal-organic frameworks (MOFs) change their structure in time and selectively open their pores adsorbing guest molecules, leading to highly selective separation, pressure amplification, sensing, and actuation applications. The 3D engineering of MOFs has reached a high level of maturity, but spatiotemporal evolution opens a new perspective toward engineering materials in the 4th dimension (time) by t-axis design, in essence exploiting the deliberate tuning of activation barriers. This work demonstrates the first example in which an explicit temporal engineering of a switchable MOF (DUT-8, [M1M2(2,6-ndc)(2)dabco](n), 2,6-ndc = 2,6-naphthalene dicarboxylate, dabco = 1,4diazabicyclo[2.2.2]octane, M-1 = Ni, M-2 = Co) is presented. The temporal response is deliberately tuned by variations in cobalt content. A spectrum of advanced analytical methods is presented for analyzing the switching kinetics stimulated by vapor adsorption using in situ time-resolved techniques ranging from ensemble adsorption and advanced synchrotron X-ray diffraction experiments to individual crystal analysis. A novel analysis technique based on microscopic observation of individual crystals in a microfluidic channel reveals the lowest limit for adsorption switching reported so far. Differences in the spatiotemporal response of crystal ensembles originate from an induction time that varies statistically and widens characteristically with increasing cobalt content reflecting increasing activation barriers.

Automated summary

Switchable metal-organic frameworks (MOFs) have applications in selective separation, pressure amplification, sensing, and actuation. This study demonstrates the temporal engineering of a switchable MOF (DUT-8) by deliberately tuning its temporal response through variations in cobalt content. Advanced analytical methods, including in situ time-resolved techniques, were used to analyze the switching kinetics stimulated by vapor adsorption. The spatiotemporal response of crystal ensembles showed differences due to variations in induction time and cobalt content, reflecting changes in activation barriers.