优质碳化硅(β-SiC)前驱物1,4-二(三甲基硅基)苯晶体结构和分子能量学的理论研究

Anant Babu Marahatta
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引用次数: 0

摘要

在过去的几十年里,快速发展的理论方法已经彻底改变了整个科学范式,发展了最先进的分析,并通过杰出的数学算法的巨大支持创建了大量的计算平台。基于自一致电荷密度功能的紧密结合(SCC-DFTB)方案是其中之一,它提供了通用和高效的量子力学计算,即使在低计算资源下也具有一些独特的特性,特别是与晶体固体兼容。它的有效参数化和计算实现在高斯标准化接口下通过用户脚本作为“外部程序”(高斯-外部方法论;GEM)增加了一个额外的值,因为它可以直接访问各种内置的高级高斯计算。在此基础上,通过GEM对高斯提供的几何优化算法和收敛准则以及ModRedundant型松弛势能面(PES)扫描技术进行了评价,并对实验合成的1,4-二(三甲基硅基)苯(1,4- btmsb)化合物的晶体结构进行了表征。是高质量碳化硅(β-SiC)涂层颗粒的潜在前驱体,也是定量光谱分析的理想“内标”。总体结果表明,1,4- BTMSB分子在其单胞和晶格中经历了显著的非键相互作用,诱导它们获得具有可识别的环、角、扭转和空间应变的明确分子几何形状。其PES的定量分析表明,苯环必须克服多个不相同的能垒,最高的能垒Ea1= 5.3 kcal/mol,才能绕1,4-(C-Si)轴进行2π内角旋转。并且,由于该化合物广泛应用于涂层高温反应器和高能运行光谱设备中定量分析物,其苯环表现出这种类型的内旋在能量上是极有可能的。为了强调在设计/合成两动力型晶体自由分子陀螺及其原型时采用完全封闭的拓扑分子结构的重要性,这里引用了相同的量化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Theoretical Investigations of the Crystal Structures and Molecular Energetics of High Quality Silicon Carbide (β-SiC) Precursor Compound 1,4-bis(trimethylsilyl)benzene
Over the last decades, the rapidly growing theoretical methods have revolutionized whole scientific paradigm, developed state-of-art analyses, and created substantial computational platforms through the huge support of outstanding mathematical algorithms. The self-consistent-charge density-functional based tight-binding (SCC-DFTB) scheme is one of them that offers versatile and efficient quantum mechanical calculations with some unique features compatible especially to the crystalline solid even at low computational resources. Its effective parametrizations and computational implementations under the Gaussian standardized interface as an "External program" via the users' script (Gaussian- External methodology; GEM) has added an additional value because of which various in-built high-level Gaussian computations are directly accessible. Herewith, the Gaussian offered geometry optimization algorithms and convergence criteria plus the ModRedundant type relaxed potential energy surface (PES) scanning techniques are assessed through the GEM, and characterized the crystal structures with concerned molecular energetics and PES of the experimentally synthesized 1,4-bis (trimethylsilyl) benzene (1,4-BTMSB) compound; a potential precursor for the high quality Silicon Carbide (β-SiC) coating particles, and an ideal "Internal Standard" for the quantitative spectroscopic analyses. The general results reveal that the 1,4- BTMSB molecules in its unit-cell and crystal lattice experience significant non-bonding interactions that induces them to attain the definite molecular geometry with recognizable ring, angle, torsional, and steric strains. The quantitative analyses of its PES depict that the phenylene ring has to overcome multiple yet unidentical energy barriers with the tallest Ea1= 5.3 kcal/mol in order to undergo internal 2π angular rotation around the 1,4-(C-Si) axes. And, exhibiting such type internal rotation of its phenylene ring is energetically highly probable as this compound is widely employed in coating high temperature reactors, and in quantizing analyte in high energy run spectroscopic facilities. The same quantification is referred here in order to underscore the significance of adopting perfectly closed topological molecular architectures while designing/synthesizing amphidynamic type crystalline free molecular gyrotops and their prototypes.
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