{"title":"A New Mononuclear Complex: Structure, Vibrational (FT-IR and Raman),Hirshfeld Surfaces Analysis, Electrical Properties and Equivalent Circuit","authors":"N. Chihaoui, B. Hamdi, A. B. Salah, R. Zouari","doi":"10.4172/2161-0398.1000216","DOIUrl":null,"url":null,"abstract":"The present paper aims to develop the synthesis, crystal structure, and properties of Zn(C7H5NO4)Cl2.H2O compound investigated by vibrational study, thermal analysis and dielectric measurements. The single crystal X-ray diffraction investigation reveals that the studied compound crystallizes in the orthorhombic system with space group Pnna according to the following lattice parameters: a=13.8816(4) A, b=10.3602(3) A, c=7.8967(2) A and Z=4. The presence of the key functional groups in the molecule has already been confirmed by Fourier transform infrared (FT-IR) analysis. Thermal behaviour of this sample, studied by TGA and DSC exhibit two anomalies at 345 and 386K. The hydrogen bonding plays a significant role in the stabilization of the structure. Such a parallel displaced structure has also a contribution from π-σ non-covalent interactions (C-H…π and C-O…π stacking between the C-H groups and C-O groups with the benzene rings). The dipicolonic acid (2,6-pyridinedicarboxylic acid) ligand coordinated to the Zn(II) ions through a nitrogen atom of pyridine ring, two oxygen atom of carboxylic group and two chloride atoms as a tridentate ligand. Hirshfeld surface analysis of the intermolecular interactions in crystal structures have been used to scrutinize molecular shapes. The characteristic features of 13C solid state CP/MAS-NMR applications showed five isotropic resonances, confirming the structure determined by XRD. Its dielectric properties as a function of temperature and frequency in the ranges 298-418 K and 209 Hz-5 MHz are measured. The Cole-Cole (Z’ versus Z’’) plots are analyzed by fitting to an equivalent electrical circuit model, consisting of a circuit elements; grain, grain boundary, electrode-solid interface polarization and Warburg resistance. Each circuit elements is formed by a parallel combination resistance (R) and constant phase elements (CPE). The grain conductivity as well as the activation energy depending to of temperature, via impedance technique, besides the activation energy due to relaxation time as function of temperature, have been studied showing two anomalies, which are also detected by the TGA and DSC. They could be explained by not only a phase transition and reorientation hopping between equivalent sites at 343K but also the disappearance of the water molecule of the structure at 388K.","PeriodicalId":94103,"journal":{"name":"Journal of physical chemistry & biophysics","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2016-05-08","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"9","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of physical chemistry & biophysics","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.4172/2161-0398.1000216","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 9
Abstract
The present paper aims to develop the synthesis, crystal structure, and properties of Zn(C7H5NO4)Cl2.H2O compound investigated by vibrational study, thermal analysis and dielectric measurements. The single crystal X-ray diffraction investigation reveals that the studied compound crystallizes in the orthorhombic system with space group Pnna according to the following lattice parameters: a=13.8816(4) A, b=10.3602(3) A, c=7.8967(2) A and Z=4. The presence of the key functional groups in the molecule has already been confirmed by Fourier transform infrared (FT-IR) analysis. Thermal behaviour of this sample, studied by TGA and DSC exhibit two anomalies at 345 and 386K. The hydrogen bonding plays a significant role in the stabilization of the structure. Such a parallel displaced structure has also a contribution from π-σ non-covalent interactions (C-H…π and C-O…π stacking between the C-H groups and C-O groups with the benzene rings). The dipicolonic acid (2,6-pyridinedicarboxylic acid) ligand coordinated to the Zn(II) ions through a nitrogen atom of pyridine ring, two oxygen atom of carboxylic group and two chloride atoms as a tridentate ligand. Hirshfeld surface analysis of the intermolecular interactions in crystal structures have been used to scrutinize molecular shapes. The characteristic features of 13C solid state CP/MAS-NMR applications showed five isotropic resonances, confirming the structure determined by XRD. Its dielectric properties as a function of temperature and frequency in the ranges 298-418 K and 209 Hz-5 MHz are measured. The Cole-Cole (Z’ versus Z’’) plots are analyzed by fitting to an equivalent electrical circuit model, consisting of a circuit elements; grain, grain boundary, electrode-solid interface polarization and Warburg resistance. Each circuit elements is formed by a parallel combination resistance (R) and constant phase elements (CPE). The grain conductivity as well as the activation energy depending to of temperature, via impedance technique, besides the activation energy due to relaxation time as function of temperature, have been studied showing two anomalies, which are also detected by the TGA and DSC. They could be explained by not only a phase transition and reorientation hopping between equivalent sites at 343K but also the disappearance of the water molecule of the structure at 388K.
本文旨在研究Zn(C7H5NO4)Cl2的合成、晶体结构和性能。通过振动研究、热分析和介电测量对H2O化合物进行了研究。单晶x射线衍射研究表明,化合物在具有空间群Pnna的正交晶系中结晶,晶格参数为:a=13.8816(4) a, b=10.3602(3) a, c=7.8967(2) a, Z=4。分子中关键官能团的存在已经被傅里叶变换红外(FT-IR)分析证实。通过热重分析和差热分析,样品的热行为在345和386K处出现了两个异常。氢键对结构的稳定起着重要的作用。这种平行位移结构也是π-σ非共价相互作用(C-H和C-O基团与苯环之间的C-H…π和C-O…π堆积)的贡献。二吡啶酸(2,6-吡啶二羧酸)配体通过吡啶环上的一个氮原子、羧基上的两个氧原子和两个氯原子作为三齿配体与Zn(II)离子配位。赫希菲尔德表面分析的分子间相互作用的晶体结构已被用于审查分子的形状。13C固态CP/MAS-NMR应用的特征表现为5个各向同性共振,证实了XRD测定的结构。在298 ~ 418k和209 hz ~ 5mhz范围内测量了其介电特性与温度和频率的关系。通过拟合等效电路模型来分析Cole-Cole (Z ' vs . Z ")图,该电路模型由一个电路元件组成;晶粒、晶界、电极-固体界面极化和Warburg电阻。每个电路元件由并联组合电阻(R)和恒相元件(CPE)组成。通过阻抗技术研究了晶粒电导率和随温度变化的活化能,以及弛豫时间随温度变化的活化能,并通过热重分析和差热分析发现了两个异常现象。它们不仅可以用343K时等效位之间的相变和重定向跳跃来解释,而且可以用388K时结构中的水分子的消失来解释。