Meyer Ralf, Hauser Andreas W
Institute of Experimental Physics, Graz University of Technology, Petersgasse 16, 8010 Graz, Austria.
J Chem Phys. 2020 Feb 28;152(8):084112. doi: 10.1063/1.5144603.
Locating the minimum energy structure of molecules, typically referred to as geometry optimization, is one of the first steps of any computational chemistry calculation. Earlier research was mostly dedicated to finding convenient sets of molecule-specific coordinates for a suitable representation of the potential energy surface, where a faster convergence toward the minimum structure can be achieved. More recent approaches, on the other hand, are based on various machine learning techniques and seem to revert to Cartesian coordinates instead for practical reasons. We show that the combination of Gaussian process regression with those coordinate systems employed by state-of-the-art geometry optimizers can significantly improve the performance of this powerful machine learning technique. This is demonstrated on a benchmark set of 30 small covalently bonded molecules.
确定分子的最低能量结构,通常称为几何优化,是任何计算化学计算的首要步骤之一。早期的研究主要致力于找到方便的分子特定坐标集,以合适地表示势能面,从而能够更快地收敛到最低结构。另一方面,最近的方法基于各种机器学习技术,并且出于实际原因似乎转而使用笛卡尔坐标。我们表明,将高斯过程回归与最先进的几何优化器所采用的那些坐标系相结合,可以显著提高这种强大的机器学习技术的性能。这在一组由30个小的共价键合分子组成的基准数据集上得到了证明。