The Crystal Structure of a Benzyltriethylammonium Bromide Complex with rac-1,1′-Binaphthalene-2,2′-diol: The Inclusion of an Arylammonium Salt by an Assembly of Binaphthol Groups
IF 0.1
Q4 CRYSTALLOGRAPHY
E. Marfo-owusu, A. Thompson
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Abstract
The concepts of crystal engineering and molecular recognition are exceedingly similar; both fields are concerned with the manipulation of intermolecular interactions in the architecture of supramolecular assemblies. In such studies, both strong and weak interactions are considered both independently and jointly concerning the molecular design strategy.1 Recently, many efforts have been focused on controlling H-bonds in supramolecular and crystal structures of complexes involving phenol derivatives and quaternary alkyl ammonium salts to achieve molecular recognition phenomena.2 This knowledge has had pharmaceutical significance, as well as applications in separation science and biomembrane studies.3 Our search of the Cambridge Structure Database Ver. 5.34, 2013, recently revealed to us that no studies have been conducted concerning molecular recognition between a quaternary arylammonium halide and a phenol derivative since such a study could reveal the suitability of quaternary arylammonium halides that bind with phenol derivatives, as observed in quaternary alkylammonium halides, as well as to employ this knowledge into crystal engineering and supramolecular studies. Gratifingly, our group found that benzyltrimethylammonium chloride, (hereafter, BTMAC) binds with rac-1,1′-binaphthalene-2,2′-diol (hereafter, BNP) to form BTMAC/BNP complex4 in a molecular recognition phenomenom. This revealed how the benzyl group influences a crystal packing mode favorable for the generation of C–H···π, C–H···O, and O–H···Cl intermolecular interactions, and indicating the relevance of these kind of weak H–bonds (C–H···π, C–H···O) in the binding phenomena. Thus, we also found it is important to investigate the binding phenomena between benzyltriethylammonium bromide (hereafter, BTEAB) and BNP through crystal structure studies in order to understand how alteration of the halide anion from Cl– to Br–, as well as to change in the trialkyl group from trimethyl to triethyl group on the ammonium cation could also enhance similar crystal packing modes and weak interactions through the influence of the benzyl group or not. Thus, the revelations from the crystal structure studies of BTEAB/BNP complex are discussed in this manuscript. Suitable crystals for X-ray diffraction studies were obtained within 8 days by slow evaporation of a warmed acetone/ ethylacetate (20 mL) mixture in which BTEAB (0.27 g, 1 mmol), and BNP (0.29 g, 1 mmol) were dissolved. Crystal 2021 © The Japan Society for Analytical Chemistry
苯三乙基溴化铵与rac-1,1′-联萘-2,2′-二醇配合物的晶体结构:联萘酚基团组装包合芳胺盐
晶体工程和分子识别的概念非常相似;这两个领域都关注超分子组装体系结构中分子间相互作用的操纵。在这些研究中,强相互作用和弱相互作用在分子设计策略中既单独又共同地被考虑近年来,人们致力于控制苯酚衍生物与季烷基铵盐配合物的超分子和晶体结构中的氢键,以实现分子识别现象这些知识具有药学意义,在分离科学和生物膜研究中也有应用我们检索了剑桥结构数据库2013年版本5.34,最近发现没有关于季芳卤化铵和苯酚衍生物之间分子识别的研究,因为这样的研究可以揭示季芳卤化铵与苯酚衍生物结合的适用性,正如在季烷基卤化铵中观察到的那样,以及将这些知识应用于晶体工程和超分子研究。令人欣慰的是,我们的研究小组发现苄基三甲基氯化铵(以下简称BTMAC)在分子识别现象中与rac-1,1 ' -联萘-2,2 ' -二醇(以下简称BNP)结合形成BTMAC/BNP复合物4。这揭示了苯基如何影响有利于生成C-H··π、C-H··O和O - h··Cl分子间相互作用的晶体堆积模式,并表明了这类弱氢键(C-H··π、C-H··O)在结合现象中的相关性。因此,我们也发现,通过晶体结构研究苯三乙基溴化铵(以下简称BTEAB)与BNP之间的结合现象,以了解卤化物阴离子从Cl -变为Br -的变化,以及铵离子上三烷基从三甲基变为三乙基的变化如何也能通过苯基的影响或不影响增强类似的晶体堆积模式和弱相互作用。因此,本文讨论了BTEAB/BNP复合物晶体结构研究的启示。通过缓慢蒸发加热的丙酮/乙酸乙酯(20 mL)混合物,其中溶解BTEAB (0.27 g, 1 mmol)和BNP (0.29 g, 1 mmol),在8天内获得适合x射线衍射研究的晶体。水晶2021©日本分析化学学会
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