Bandura A V, Sofo J O, Kubicki J D
St. Petersburg State University, St. Petersburg, Russia.
J Phys Chem B. 2006 Apr 27;110(16):8386-97. doi: 10.1021/jp0523423.
Plane-wave density functional theory (DFT-PW) calculations were performed on bulk SnO2 (cassiterite) and the (100), (110), (001), and (101) surfaces with and without H2O present. A classical interatomic force field has been developed to describe bulk SnO2 and SnO2-H2O surface interactions. Periodic density functional theory calculations using the program VASP (Kresse et al., 1996) and molecular cluster calculations using Gaussian 03 (Frisch et al., 2003) were used to derive the parametrization of the force field. The program GULP (Gale, 1997) was used to optimize parameters to reproduce experimental and ab initio results. The experimental crystal structure and elastic constants of SnO2 are reproduced reasonably well with the force field. Furthermore, surface atom relaxations and structures of adsorbed H2O molecules agree well between the ab initio and force field predictions. H2O addition above that required to form a monolayer results in consistent structures between the DFT-PW and classical force field results as well.
采用平面波密度泛函理论(DFT-PW)对块状SnO₂(锡石)以及存在和不存在H₂O时的(100)、(110)、(001)和(101)表面进行了计算。已开发出一种经典的原子间力场来描述块状SnO₂和SnO₂-H₂O表面相互作用。使用VASP程序(Kresse等人,1996年)进行周期性密度泛函理论计算,并使用Gaussian 03(Frisch等人,2003年)进行分子簇计算,以推导力场的参数化。使用GULP程序(Gale,1997年)优化参数以重现实验结果和从头算结果。该力场能够较好地重现SnO₂的实验晶体结构和弹性常数。此外,表面原子弛豫和吸附的H₂O分子结构在从头算和力场预测之间吻合良好。添加超过形成单层所需量的H₂O后,DFT-PW和经典力场结果之间的结构也保持一致。