State Key Laboratory of Rare Earth Resource Utilization, Changchun Institute of Applied Chemistry, Chinese Academy of Sciences, Changchun 130022, China.
Phys Chem Chem Phys. 2013 Sep 14;15(34):14414-9. doi: 10.1039/c3cp51959g. Epub 2013 Jul 25.
We thermodynamically studied the size-dependent oxygen storage ability of nano-sized ceria by tracing the surface Ce/O ratio of octahedral particles with different diameters, from the viewpoint of lattice Ce and O in a CeO2 crystallographic structure. The high surface Ce/O ratio with small scale particle size has more excess surface Ce(4+) ions, which allows ceria to have an increasing oxygen storage ability in a crystalline lattice. For the perfect octahedron growth shape of ceria, the nonstoichiometric surfaces can produce excess Ce(4+) ions, Ce(4+) ions can be stabilized by bonding with lattice oxygen, leading to an enhanced oxygen storage ability of ceria. With the increasing particle size, the surface Ce/O ratio approaches to 0.5 owing to the decreased contributions of atoms located at the edges and corners. When the octahedron diameter D = 0.55 nm, the surface Ce/O ratio can reach 0.75. When D = 7.58 nm, the surface Ce/O ratio decreases down to 0.51. If D≥ 14.61 nm, the surface Ce/O ratios are equal to 0.5. The present study deepens the insight of the size-dependent oxygen storage ability of nano-sized ceria, focusing on the size-dependent excess Ce(4+) on nonstoichiometric surfaces of ceria in thermodynamics.
我们从 CeO2 晶体结构中的晶格 Ce 和 O 的角度出发,通过追踪不同直径的八面体颗粒的表面 Ce/O 比,对纳米氧化铈的尺寸依赖性储氧能力进行了热力学研究。小尺寸颗粒具有更高的表面 Ce/O 比,具有更多过剩的表面 Ce(4+)离子,这使得氧化铈在晶格中具有不断增强的储氧能力。对于氧化铈的完美八面体生长形状,非化学计量表面可以产生过剩的 Ce(4+)离子,Ce(4+)离子可以通过与晶格氧键合而稳定,从而增强氧化铈的储氧能力。随着颗粒尺寸的增加,由于边缘和角落处原子的贡献减少,表面 Ce/O 比接近 0.5。当八面体直径 D = 0.55nm 时,表面 Ce/O 比可达 0.75。当 D = 7.58nm 时,表面 Ce/O 比下降至 0.51。如果 D≥14.61nm,则表面 Ce/O 比等于 0.5。本研究通过热力学方法深入了解了纳米氧化铈的尺寸依赖性储氧能力,重点关注了氧化铈非化学计量表面上的尺寸依赖性过剩 Ce(4+)。