Synthesis and Conformational Features of Luminescent Phosphoguanidine with a Phenylbenzothiazole Substituent

IF 1.2 4区化学 Q4 CHEMISTRY, INORGANIC & NUCLEAR

Journal of Structural Chemistry Pub Date : 2024-07-26 DOI:10.1134/S0022476624070138

M. Y. Afonin, S. N. Konchenko, T. S. Sukhikh

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引用次数: 0

Abstract

We report a three-stage scheme (1) Pbt–NH₂ + CS₂ → (Pbt–NH)₂C=S (1) (Pbt = 4-(1′,3′-benzothiazole-2′-yl)phenyl), (2) 1 + PPh₃ + I₂ → Pbt–N=C=N–Pbt (2), (3) 2 + Ph₂PH → (Pbt–N)(Pbt–NH)CPPh₂ (3) for the synthesis of a novel luminescent phosphoguanidine 3 with an unprecedentedly high yield (90%) at the last catalyst-free stage. It is demonstrated by the density functional theory (DFT) method that high reactivity of 2, leading to such an yield, is explained by a high electrostatic potential at the central carbon atom. For 3, two polymorphs 3α, 3β and a solvatomorph 3γ·THF are prepared. The structures of 2, 3α, 3β, and 3γ·THF are determined by single-crystal XRD. The tendency of crystals of different phenylbenzothiazole derivatives to form different conformations is explained by the computational (DFT) data indicating that the energy change of the molecule of 3 considered as a function of the torsion angle between phenyl and benzothiazole fragments does not exceed 2 kJ/mol in the –15…30° range. Photophysical properties of 3β and 3γ·THF phases are studied. It is shown that these compounds exhibit photoluminescence with an emission maximum at 510 nm.

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具有苯基苯并噻唑取代基的发光磷胍的合成与构象特征

摘要我们报告了一个三阶段方案：(1) Pbt-NH2 + CS2 → (Pbt-NH)2C=S (1) (Pbt = 4-(1′,3′-苯并噻唑-2′-基)苯基)；(2) 1 + PPh3 + I2 → Pbt-N=C=N-Pbt (2)、(3) 2 + Ph2PH → (Pbt-N)(Pbt-NH)CPPh2 (3)，用于合成新型发光膦胍 3，在最后的无催化剂阶段获得了前所未有的高产率（90%）。密度泛函理论（DFT）方法证明，中心碳原子上的高静电势解释了 2 的高反应性导致如此高的产率。对于 3，制备了两种多晶型 3α、3β 和一种溶胶多晶型 3γ-THF。通过单晶 XRD 确定了 2、3α、3β 和 3γ-THF 的结构。计算（DFT）数据表明，在-15...30°范围内，作为苯基和苯并噻唑片段之间扭转角函数的 3 分子能量变化不超过 2 kJ/mol，这解释了不同苯基苯并噻唑衍生物晶体形成不同构象的趋势。研究了 3β 和 3γ-THF 相的光物理特性。研究表明，这些化合物在 510 纳米波长处具有最大发射光。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Structural Chemistry 化学-无机化学与核化学

CiteScore

1.60

自引率

12.50%

发文量

142

审稿时长

8.3 months

期刊介绍： Journal is an interdisciplinary publication covering all aspects of structural chemistry, including the theory of molecular structure and chemical bond; the use of physical methods to study the electronic and spatial structure of chemical species; structural features of liquids, solutions, surfaces, supramolecular systems, nano- and solid materials; and the crystal structure of solids.