电子密度
化学
结晶学
氢键
晶体结构
两性离子
分子
密度泛函理论
分子间力
晶体工程
邻苯三酚
之字形的
计算化学
电子
物理
超分子化学
几何学
数学
有机化学
量子力学
作者
Alia Iqbal,Arshad Mehmood,Sajida Noureen,Claude Lecomte,Maqsood Ahmed
标识
DOI:10.1107/s2052520621009124
摘要
Experimental electron density analysis by means of high-resolution X-ray diffraction data up to sinθ/λ max = 1.11 Å −1 at 100 (1) K has been performed to analyze the detailed structure and the strength of intermolecular interactions responsible for the formation of a new solid form of nicotinic acid (NA), cocrystallized with pyrogallol (PY). There are two NA–PY units in the asymmetric unit. The experimental results are compared with the results obtained from theoretical structure factors modeled using periodic boundary DFT calculations. Both refinements were carried out using the Hansen and Coppens multipolar formalism (in MoPro program). The non-centrosymmetric and polar nature of the crystal system rendered the multipolar refinement challenging which was addressed by involving the transferability principle. This study highlights the significance of the transferability principle in electron density modeling in non-routine situations. The 2:2 cocrystal of NA–PY exhibits a zigzag, brickwall and sheet-like layered structure in three dimensions and is stabilized by strong intra- and inter-molecular hydrogen bonding through N—H...O and O—H...O bonds, some of them due to the zwitterion nature of NA as well as weak interactions between the PY molecules. Ranking these interactions via topological analysis of the electron density shows the leading role of the NA–NA substructure which drives the organization of the cocrystals. These strong interactions between the NA zwitterions may explain why Z ′ = 2.
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