Structure Elucidation and Computationally Guided Synthesis of SSZ‐43: A One‐Dimensional 12‐Ring Zeolite with Unique Sinusoidal Channels Article Swipe

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Stacking Orthorhombic crystal system Crystallography Zeolite Ring (chemistry) Monoclinic crystal system Chemistry Transmission electron microscopy Powder diffraction Electron diffraction Diffraction Materials science Crystal structure Nanotechnology Optics Organic chemistry Catalysis Physics

Maria Roslova , Viktor J. Cybulskis , Mark E. Davis , Stacey I. Zones , Xiaodong Zou , Dan Xie ·

YOU? · · 2022 · Open Access · · DOI: https://doi.org/10.1002/ange.202115087 · OA: W4210262959

The structure of zeolite SSZ‐43 was determined by 3D electron diffraction, synchrotron X‐ray powder diffraction, and high‐resolution transmission electron microscopy. The SSZ‐43 framework forms one‐dimensional, sinusoidal 12‐ring channels from 5 4 6 1 butterfly units commonly found in other zeolites, but with unique 6.5×6.5 Å apertures and 12‐ring 6.5×8.9 Å windows perpendicular to the channels. SSZ‐43 crystals are intergrowths of two polytypes: ≈ 90 % orthorhombic polytype A with ABAB stacking of the 12‐rings, and ≈10 % monoclinic polytype B with ABCABC stacking. Molecular modeling performed on the idealized Si‐SSZ‐43 structure along with empirical relationships for zeolite selectivity in boron‐ and aluminum‐containing synthesis gels were used in a combined approach to design new di‐quaternary ammonium organic structure‐directing agents (OSDAs). Experimental trials demonstrated that the new OSDAs produced SSZ‐43 over a broader range of compositions than previous mono‐quaternary OSDAs.