Department of Physics, Bilkent University, Ankara 06800, Turkey.
J Phys Condens Matter. 2012 Aug 1;24(30):305301. doi: 10.1088/0953-8984/24/30/305301. Epub 2012 Jul 4.
We have systematically investigated the growth behavior and stability of small stoichiometric (TiO(2))(n) (n = 1-10) clusters as well as their structural, electronic and magnetic properties by using the first-principles plane wave pseudopotential method within density functional theory. In order to find out the ground state geometries, a large number of initial cluster structures for each n has been searched via total energy calculations. Generally, the ground state structures for the case of n = 1-9 clusters have at least one monovalent O atom, which only binds to a single Ti atom. However, the most stable structure of the n = 10 cluster does not have any monovalent O atom. On the other hand, Ti atoms are at least fourfold coordinated for the ground state structures for n ≥ 4 clusters. Our calculations have revealed that clusters prefer to form three-dimensional structures. Furthermore, all these stoichiometric clusters have nonmagnetic ground state. The formation energy and the highest occupied molecular orbital (HOMO)-lowest unoccupied molecular orbital (LUMO) gap for the most stable structure of (TiO(2))(n) clusters for each n have also been calculated. The formation energy and hence the stability increases as the cluster size grows. In addition, the interactions between the ground state structure of the (TiO(2))(n) cluster and a single water molecule have been studied. The binding energy (E(b)) of the H(2)O molecule exhibits an oscillatory behavior with the size of the clusters. A single water molecule preferably binds to the cluster Ti atom through its oxygen atom, resulting an average binding energy of 1.1 eV. We have also reported the interaction of the selected clusters (n = 3, 4, 10) with multiple water molecules. We have found that additional water molecules lead to a decrease in the binding energy of these molecules to the (TiO(2))(n) clusters. Finally, the adsorption of transition metal (TM) atoms (V, Co and Pt) on the n = 10 cluster has been investigated for possible functionalization. All these elements interact strongly with this cluster, and a permanent magnetic moment is induced upon adsorption of Co and V atoms. We have observed gap localized TM states leading to significant HOMO-LUMO gap narrowing, which is essential to achieve visible light response for the efficient use of TiO(2) based materials. In this way, electronic and optical as well as magnetic properties of TiO(2) materials can be modulated by using the appropriate adsorbate atoms.
我们使用第一性原理平面波赝势方法在密度泛函理论中系统地研究了小化学计量比(TiO 2 )(n)(n=1-10)团簇的生长行为和稳定性,以及它们的结构、电子和磁性质。为了找出基态几何形状,我们通过总能量计算搜索了每个 n 的大量初始团簇结构。通常,对于 n=1-9 团簇的基态结构,至少有一个单价 O 原子,该原子仅与单个 Ti 原子结合。然而,n=10 团簇的最稳定结构没有任何单价 O 原子。另一方面,对于 n≥4 团簇的基态结构,Ti 原子至少是四配位的。我们的计算表明,团簇倾向于形成三维结构。此外,所有这些化学计量团簇都具有非磁性基态。还计算了每个 n 的(TiO 2 )(n)团簇的最稳定结构的形成能和最高占据分子轨道(HOMO)-最低未占据分子轨道(LUMO)间隙。形成能随着团簇尺寸的增加而增加,因此稳定性也增加。此外,还研究了(TiO 2 )(n)团簇的基态结构与单个水分子之间的相互作用。H 2 O 分子的结合能(E b )随团簇尺寸呈振荡变化。单个水分子优选通过其氧原子与团簇 Ti 原子结合,导致平均结合能为 1.1 eV。我们还报告了选定团簇(n=3、4、10)与多个水分子的相互作用。我们发现,额外的水分子会降低这些分子与(TiO 2 )(n)团簇的结合能。最后,研究了过渡金属(TM)原子(V、Co 和 Pt)在 n=10 团簇上的吸附,以实现可能的功能化。所有这些元素都与这个团簇强烈相互作用,并且 Co 和 V 原子的吸附会诱导出永久磁矩。我们观察到局域在间隙中的 TM 态导致 HOMO-LUMO 间隙明显变窄,这对于实现 TiO 2 基材料的可见光响应至关重要。通过使用适当的吸附原子,可以调节 TiO 2 材料的电子、光学和磁性性质。
