Calculation of anharmonic vibrational spectroscopy of small biological molecules

PhysChemComm Pub Date : 2002-01-01 DOI:10.1039/B208000A
R. Gerber, B. Brauer, S. Gregurick, G. Chaban
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引用次数: 36

Abstract

The role of anharmonic effects in the vibrational spectroscopy of small biological molecules and their 1 ∶ 1 complexes with water is discussed. The strengths and limitations of the vibrational self-consistent field (VSCF) method and its extensions as a computational tool for this purpose are examined. Anharmonic coupling between different vibrational modes is found to be very important for these systems, even for fundamental transitions, and incorporation of these effects seems essential for quantitative interpretation of experimental data. Both analytical, empirical force fields, and potential surfaces computed from electronic structure methods are used in VSCF calculations of several benchmark systems and compared with experimental spectroscopic data. Glycine in several conformers, the glycine–water complex, and N-methylacetamide are among the systems discussed. The main conclusions are: (1) Electronic structure methods such as MP2/DZP and density functional B97, give very good agreement with experimental data. Thus, MP2 and B97 clearly provide an accurate description of the anharmonic interactions. VSCF calculations, including all modes, with MP2, B97 and other successful methods are presently feasible for molecules with up to 15-20 atoms. (2) The electronic structure methods seem to give spectroscopic predictions in much better accord with experiment than standard empirical force fields such as AMBER or OPLS. The anharmonic couplings provided by these methods differ greatly, in the cases tested to date, from the ab initio ones. The implications of these results for future modeling of small biomolecules are discussed. Comments are provided on future directions in this subject, including extensions to large biomolecules.
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小生物分子的非谐振动谱计算
讨论了非调和效应在生物小分子及其与水的1∶1配合物的振动光谱中的作用。研究了振动自洽场(VSCF)方法的优点和局限性,以及它作为一种计算工具的扩展。发现不同振动模式之间的非谐波耦合对于这些系统非常重要,甚至对于基本转变也是如此,并且这些效应的合并对于实验数据的定量解释似乎是必不可少的。利用电子结构方法计算的解析力场、经验力场和势面分别用于几个基准系统的VSCF计算,并与实验光谱数据进行了比较。几种构象中的甘氨酸、甘氨酸-水络合物和n -甲基乙酰胺是讨论的体系之一。主要结论有:(1)MP2/DZP和密度泛函B97等电子结构方法与实验数据吻合较好。因此,MP2和B97清楚地提供了非调和相互作用的准确描述。用MP2、B97和其他成功的方法计算VSCF,包括所有模式,目前对于含有15-20个原子的分子是可行的。(2)与AMBER或ops等标准经验力场相比,电子结构方法给出的光谱预测似乎更符合实验结果。在迄今为止测试的情况下,这些方法提供的非谐波耦合与从头开始的情况有很大不同。讨论了这些结果对未来小生物分子建模的意义。对这一课题的未来发展方向,包括扩展到大的生物分子提供了意见。
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