Shawn X. Yin

The crystallization problem is an outstanding challenge in the chemistry of porous covalent organic frameworks (COFs). Their structural characterization has been limited to modeling and solutions based on powder x-ray or electron diffraction data. Single crystals of COFs amenable to x-ray diffraction characterization have not been reported. Here, we developed a general procedure to grow large single crystals of three-dimensional imine-based COFs (COF-300, hydrated form of COF-300, COF-303, LZU-79, and LZU-111). The high quality of the crystals allowed collection of single-crystal x-ray diffraction data of up to 0.83-angstrom resolution, leading to unambiguous solution and precise anisotropic refinement. Characteristics such as degree of interpenetration, arrangement of water guests, the reversed imine connectivity, linker disorder, and uncommon topology were deciphered with atomic precision-aspects impossible to determine without single crystals.

Abstract Crystal size effect is of vital importance in materials science by exerting significant influence on various properties of materials and furthermore their functions. Crystal size effect of covalent organic frameworks (COFs) has never been reported because their controllable synthesis is difficult, despite their promising properties have been exhibited in many aspects. Here, we report the diverse crystal size effects of two representative COFs based on the successful realization of crystal-size-controlled synthesis. For LZU-111 with rigid spiral channels, size effect reflects in pore surface area by influencing the pore integrity, while for flexible COF-300 with straight channels, crystal size controls structural flexibility by altering the number of repeating units, which eventually changes sorption selectivity. With the understanding and insight of the structure-property correlation not only at microscale but also at mesoscale for COFs, this research will push the COF field step forward to a significant advancement in practical applications.

The characterization of crystalline polymorphs of drug molecules is an area of great interest since these variations in solid-state structure directly influence the physical properties of such substances. Terahertz spectroscopy provides a powerful analytical tool for these investigations and has been used here to study tautomeric polymorphism and conformational disorder in crystallized irbesartan, an antihypertensive medication. The low-frequency (<90 cm–1) terahertz spectra of both irbesartan Form A and Form B were measured and interpreted using solid-state density functional theory. The spectra reveal distinct identifying features for each polymorph and are indicative of the variations in the packing arrangements of the solids. The computational analyses of the solid-state forms also provide new insights into the origins and temperature dependence of the conformational disorder found in Form B. The results indicate that the disorder present in this crystal structure arises from a competition between internal conformational strain and external cohesive binding.