Synthesis, crystal structure study, thermal, Hirshfeld surface, optical and photoluminescence properties of new organic-inorganic hybrid material: (C6H5CH2N(C2H5)3)[Cd3Cl7

Abstract

This work describes a new two-dimensional chlorocadmate (II) compound formulated us (C6H5CH2N(C2H5)3)[Cd3Cl7] has been synthesized by slow evaporation method at room temperature and characterized by single-crystal X-ray diffraction. Structural analysis reveals that this compound crystallizes in the triclinic system with centrosymetric P−1 space group. The molecular arrangement of the crystal displays a two-dimensional (2D) structure which consist in one (C6H5CH2N(C2H5)3)+cation and one anionic layers [Cd3Cl7]‒. The various components are interconnected through non-classical C–H…Cl hydrogen bonds, Coulombic attractions, and van der Waals interactions, which collectively secure the unity and stability of the crystal arrangement. This interaction ensemble contributes to the formation of a three-dimensional (3D) supramolecular network. The examination of the crystal structure provides a new interesting example of covalent polymeric layers of [Cd3Cl7]n. The intermolecular interactions were identified using Hirshfeld surfaces as well 2D-fingerprint plots. Furthermore, Infrared (IR) spectrum was analyzed, confirming the presence of the organic cation. Thermogravimetric analysis (TGA) reveals that the studied compound remains stable up to 266 °C. DSC thermogram shows that it undergoes two endothermic anomalies around 79.6 °C and 139 °C. Diffuse reflectance spectra (DRS) method was used to study the optical properties and shows that there is a strong absorption in the UV region for Cd hybrid. Kubelka–Munk equation has been used to calculate the band gap energy indicating that the material is a direct type (4.25 eV). Photoluminescence spectroscopy (PL) proves that the title material was well structured.