The structural and electronic properties of bulk and (001) plane of TiC were investigated by the first-principles total-energy pseudopotential method based on density functional theory.The calculated bulk properties i...The structural and electronic properties of bulk and (001) plane of TiC were investigated by the first-principles total-energy pseudopotential method based on density functional theory.The calculated bulk properties indicate that bonding nature in TiC is a combination of ionicity,covalency and metallicity,in which the Ti-C covalent bonding is the predominate one.The calculated results of structural relaxation and surface energy for TiC(001) slab indicate that slab with 7 layers shows bulk-like characteristic interiors,and the changes of slab occur on the outmost three layers,which shows that the relaxation only influences the top three layers.Meanwhile,the strong Ti-C covalent bonding can be found in the distribution of charge density on the (110) and (001) planes.Ti-C covalent bonding is enhanced by the charge depletion and accumulation in the vacuum and the interlayer region between top two atomic layers.展开更多
Ion specificity of Na+ and C1- ions for NaCI solution confined in silicon nanochannels is investigated with molecular dynamics (MD) simulations. The MD simulation results demonstrate that ion specificity for Na+ a...Ion specificity of Na+ and C1- ions for NaCI solution confined in silicon nanochannels is investigated with molecular dynamics (MD) simulations. The MD simulation results demonstrate that ion specificity for Na+ and C1- ions exhibits clearly in na- nochannels with high surface charge density. The two types of ions show different density distributions perpendicular to the channel surface due to the ion specificity when they act as countefions near negatively and positively charged surfaces, respec- tively. Both the two counterion distributions cannot be predicted by Poisson-Boltzmann equation within 0.75 nm near the sur- face. In addition, the ion specificity is also demonstrated through affecting the water density distributions. In the nanochannel with negatively charged surfaces, the presence of the Na+ ions reduces the number of water peaks in water density distribution profile. In comparison, when the C1- ions act as counterions near positively charged surfaces, they do not affect the number of the water peaks. Besides the influence on the water density distribution, ion specificity also exhibits through affecting the wa- ter molecule orientation in the adsorbed layer. It is found that C1- ions make the water molecules in the adsorbed layer align more orderly than Na~ ions do when the two types of ions act as the counterions near the positively and negatively charged surfaces with the same surface charge density.展开更多
基金Project(200802015) supported by Post-doctoral Foundation of Shandong Province,ChinaProject(50625101) supported by the National Natural Science Foundation for Distinguished Young Scholars of China
文摘The structural and electronic properties of bulk and (001) plane of TiC were investigated by the first-principles total-energy pseudopotential method based on density functional theory.The calculated bulk properties indicate that bonding nature in TiC is a combination of ionicity,covalency and metallicity,in which the Ti-C covalent bonding is the predominate one.The calculated results of structural relaxation and surface energy for TiC(001) slab indicate that slab with 7 layers shows bulk-like characteristic interiors,and the changes of slab occur on the outmost three layers,which shows that the relaxation only influences the top three layers.Meanwhile,the strong Ti-C covalent bonding can be found in the distribution of charge density on the (110) and (001) planes.Ti-C covalent bonding is enhanced by the charge depletion and accumulation in the vacuum and the interlayer region between top two atomic layers.
基金supported by the National Basic Research Program of Chi-na(Grant Nos.2011CB707601,2011CB707605)the National Natural Science Foundation of China(Grant No.50925519)+3 种基金the Research Funding for the Doctor Program from China Educational Ministry(Grant No.20100092110051)the Innovative Project for Graduate Students of Jiangsu Province(Grant No.CXZZ13_0087)the Scientific Research Founda-tion of Graduate School of Southeast University(Grant No.YBJJ1322)The calculations were performed on Tianhe-1A at National Supercomputing Center in Tianjin,China
文摘Ion specificity of Na+ and C1- ions for NaCI solution confined in silicon nanochannels is investigated with molecular dynamics (MD) simulations. The MD simulation results demonstrate that ion specificity for Na+ and C1- ions exhibits clearly in na- nochannels with high surface charge density. The two types of ions show different density distributions perpendicular to the channel surface due to the ion specificity when they act as countefions near negatively and positively charged surfaces, respec- tively. Both the two counterion distributions cannot be predicted by Poisson-Boltzmann equation within 0.75 nm near the sur- face. In addition, the ion specificity is also demonstrated through affecting the water density distributions. In the nanochannel with negatively charged surfaces, the presence of the Na+ ions reduces the number of water peaks in water density distribution profile. In comparison, when the C1- ions act as counterions near positively charged surfaces, they do not affect the number of the water peaks. Besides the influence on the water density distribution, ion specificity also exhibits through affecting the wa- ter molecule orientation in the adsorbed layer. It is found that C1- ions make the water molecules in the adsorbed layer align more orderly than Na~ ions do when the two types of ions act as the counterions near the positively and negatively charged surfaces with the same surface charge density.
