Andrea Simion , Mihai Vasilescu , Claudiu Filip , Milica Todea , Marieta Mureșan-Pop , Simion Simon
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引用次数: 1
摘要
核壳铝硅酸盐材料表面和界面的原子尺度描述尚未完全阐明,部分原因是它们的无定形特征和控制其性质的复杂机制。本文通过不同的固体核磁共振方法,即29Si, 29Si交叉极化(CP), 27Al, 27Al三量子(3Q)和1H-27Al异核相关(hetor) MAS NMR,展示了对纳米结构核壳铝硅酸盐的新见解。为此,研究了基于Stöber法制备二氧化硅核和静电吸引形成氧化铝壳的化学合成方法,分别制备了未掺杂和掺杂钆离子的纳米二氧化硅核-氧化铝壳微球。结果表明,在二氧化硅核和氧化铝壳之间的界面处形成了新的铝-硅酸盐层,铝在二氧化硅网络中小规模扩散,而硅离子在氧化铝网络中大规模迁移,导致了稳定的核-壳结构。此外,这一过程伴随着过渡区显著的局部结构变化,特别是在铝邻域,这一点现在已经很好地理解了,借助固态核磁共振光谱的力量。
Structural characterization of interfaces in silica core-alumina shell microspheres by solid-state NMR spectroscopy
Atomic-scale description of surfaces and interfaces in core-shell aluminosilicate materials is not fully elucidated, partially due to their amorphous character and complex mechanisms that govern their properties. In this paper, new insights into nanostructured core-shell aluminosilicates have been demonstrated, by using different solid-state NMR methods, i.e 29Si, 29Si cross-polarization (CP), 27Al, 27Al triple-quantum (3Q), and 1H–27Al heteronuclear correlation (HETCOR) MAS NMR. For this purpose, nanostructured silica core-alumina shell microspheres, undoped and doped with gadolinium ions respectively, obtained by a chemical synthesis based on the Stöber method for the silica core and electrostatic attraction for developing the alumina shell were studied. As a result, a new alumino-silicate layer formation was proved at the interface between silica core, where aluminum diffuses, on small scale, in the silica network, and alumina shell, where silicon ions migrate, on a larger scale, in the alumina network, leading to a stable core-shell structure. Moreover, this process is accompanied by significant local structural changes in the transition zone, particularly at the aluminum neighborhood, which is quite well understood now, with the power of solid-state NMR spectroscopy.
期刊介绍:
The journal Solid State Nuclear Magnetic Resonance publishes original manuscripts of high scientific quality dealing with all experimental and theoretical aspects of solid state NMR. This includes advances in instrumentation, development of new experimental techniques and methodology, new theoretical insights, new data processing and simulation methods, and original applications of established or novel methods to scientific problems.