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Abstract
Covalent organic frameworks (COFs) are among the fastest growing classes of materials with an almost unlimited number of achievable structures, topologies, and functionalities. The exact structure of layered COFs is, however, hard to determine due to often significant mismatch between experimental powder X-ray diffraction pattern (PXRD) and predicted geometries. We attribute these discrepancies to an inherent disorder in the stacking of layered COFs, invalidating standard theoretical 3D models. We have represented structure of COF-1, COF-5 and ZnPc-pz by stacking layers following the Maxwell-Boltzmann energy distribution of their stacking modes. Simulated PXRD patterns of the statistical COF models are close to the experiment, featuring an agreement in peak intensity, width and asymmetry never obtained before. The rarely considered ABC stacking mode proved to be important in layered COFs, as well as including solvent molecules. Our model also shows several general features in PXRD originating from the stacking disorder.
Supplementary materials
Title
A Statistical Representation of Stacking Disorder in Layered Covalent Organic Frameworks
Description
Details of the DFTB and DFT calculations, stacking modes and corresponding relative energies, details of the statistical model, more results of PXRD patterns and electronic properties.
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