Probing Self-Diffusion of Guest Molecules in a Covalent Organic Framework: Simulation and Experiment
Lars Grunenberg, Christopher Keßler, Tiong Wei Teh, Robin Schuldt, Fabian Heck, Johannes Kästner, Joachim Groß, Niels Hansen, Bettina V. Lotsch
Abstract
High Resolution Image Download MS PowerPoint Slide Covalent organic frameworks (COFs) are a class of porous materials whose sorption properties have so far been studied primarily by physisorption. Quantifying the self-diffusion of guest molecules inside their nanometer-sized pores allows for a better understanding of confinement effects or transport limitations and is thus essential for various applications ranging from molecular separation to catalysis. Using a combination of pulsed field gradient nuclear magnetic resonance measurements and molecular dynamics simulations, we have studied the self-diffusion of acetonitrile and chloroform in the 1D pore channels of two imine-linked COFs (PI-3-COF) with different levels of crystallinity and porosity. The higher crystallinity and porosity sample exhibited anisotropic diffusion for MeCN parallel to the pore direction, with a diffusion coefficient of D par = 6.1(3) × 10 –10 m 2 s –1 at 300 K, indicating 1D transport and a 7.4-fold reduction in self-diffusion compared to the bulk liquid. This finding aligns with molecular dynamics simulations predicting 5.4-fold reduction, assuming an offset-stacked COF layer arrangement. In the low-porosity sample, more frequent diffusion barriers result in isotropic, yet significantly reduced diffusivities ( D B = 1.4(1) × 10 –11 m 2 s –1 ). Diffusion coefficients for chloroform at 300 K in the pores of the high- ( D par = 1.1(2) × 10 –10 m 2 s –1 ) and low-porosity ( D B = 4.5(1) × 10 –12 m 2 s –1 ) samples reproduce these trends. Our multimodal study thus highlights the significant influence of real structure effects such as stacking faults and grain boundaries on the long-range diffusivity of molecular guest species while suggesting efficient intracrystalline transport at short diffusion times.