Comparative Computational Study on Molecular Structure, Electronic and Vibrational Analysis of Vinyl Bromide based on HF and DFT Approach

Himalayan Journal of Science and Technology Pub Date : 2023-12-31 DOI:10.3126/hijost.v7i1.61128

Tulsi Ojha, Susmita Limbu, Prakash Man Shrestha, Suresh Prasad Gupta, Krishna Bahadur Rai

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Abstract

In this study, we have used the Hartree-Fock and Density Functional Theory method of calculation and compared the equilibrium configuration, electronic and vibrational mode of Vinyl Bromide molecule. The molecule is geometrically optimized initially by using 6-31G basis set with B3LYP functional and then bond angles, bond lengths, dihedral angles and IR spectra are compared respectively. Various groups of atoms in Vinyl Bromide molecule by DFT has more accurate bond length, bond angle values rather than by HF computation when comparing with the experimental values. The ground state energies are found at angle 10° or 180° or 360° using HF and DFT method of calculation for the H4-C1-C2-Br6 position. Values of the carbon-hydrogen, carbon-carbon and carbon-bromine bond lengths and bond angles for optimization state of C2H3Br molecule using Hartree-Fock and Density Functional Theory methods with respect to the basis set 6-31G have been analyzed. The C−H in-plane bending vibration and C−H out-of-plane bending vibrations occur in the region 1400–1050 cm-1 and 1000–675 cm-1 respectively. The electronic properties, such as Highest Occupied Molecular Orbital and Lowest Unoccupied Molecular Orbital energies are performed by HF and DFT approach and the difference in Highest Occupied Molecular Orbital and Lowest Unoccupied Molecular Orbital energy gap for HF and DFT method are 14.0847 eV and 6.8994 eV respectively

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基于 HF 和 DFT 方法的溴化乙烯分子结构、电子和振动分析的比较计算研究

在本研究中，我们采用哈特里-福克和密度泛函理论计算方法，比较了溴化乙烯分子的平衡构型、电子和振动模式。首先使用 6-31G 基集和 B3LYP 函数对分子进行几何优化，然后分别比较键角、键长、二面角和红外光谱。与实验值相比，通过 DFT 计算出的溴化乙烯分子中各原子组的键长、键角值比通过高频计算出的更精确。使用高频和 DFT 方法计算 H4-C1-C2-Br6 位置的基态能量时，发现其角度为 10°、180° 或 360°。使用哈特里-福克（Hartree-Fock）和密度泛函理论（Density Functional Theory）方法，以 6-31G 为基集，分析了 C2H3Br 分子优化态的碳-氢、碳-碳和碳-溴键长度和键角值。C-H 面内弯曲振动和 C-H 面外弯曲振动分别发生在 1400-1050 cm-1 和 1000-675 cm-1 区域。通过高频和 DFT 方法分析了最高占位分子轨道和最低未占位分子轨道能量等电子特性，高频和 DFT 方法的最高占位分子轨道和最低未占位分子轨道能隙分别为 14.0847 eV 和 6.8994 eV。

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Himalayan Journal of Science and Technology

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