van der Weijden Arno, van Hecke Martin, Noorduin Willem L
AMOLF, Science Park 104, Amsterdam 1098 XG, The Netherlands.
Leiden Institute of Physics, Leiden University, Niels Bohrweg 2, Leiden 2333 CA, The Netherlands.
Cryst Growth Des. 2022 Apr 6;22(4):2289-2293. doi: 10.1021/acs.cgd.1c01364. Epub 2022 Mar 14.
The next generation of advanced functional materials can greatly benefit from methods for realizing the right chemical composition at the right place. Nanocomposites of amorphous silica and metal carbonate nanocrystals (BaCO/SiO) form an attractive starting point as they can straightforwardly be assembled in different controllable three-dimensional (3D) shapes, while the chemical composition of the nanocrystals can be completely converted via ion exchange. Nevertheless, it is still unknown-let alone predictable-how nanoscopic changes in the lattice volume of the nanocrystals translate to changes in the microscopic dimensions of 3D BaCO/SiO structures during ion exchange. Here, we demonstrate that the microscopic shape adapts to contraction and expansion of the atomic spacing of nanocrystals. Starting from BaCO/SiO, we systematically decrease and increase lattice volumes by converting the BaCO nanocrystals into a range of chalcogenides and perovskites. Based on geometrical analysis, we obtain a precise prediction for how the microscopic nanocomposite volume follows the change in nanoscopic crystal volume. The silica matrix facilitates mechanical flexibility to adapt to nanoscopic volume changes, while preserving the 3D morphology and fine details of the original composite with high fidelity. The versatility and predictability of shape-preserving conversion reactions open up exciting opportunities for using nanocomposites as functional components.
下一代先进功能材料将极大地受益于能够在正确位置实现正确化学成分的方法。非晶态二氧化硅和金属碳酸盐纳米晶体(BaCO₃/SiO₂)的纳米复合材料是一个有吸引力的起点,因为它们可以直接组装成不同的可控三维(3D)形状,同时纳米晶体的化学成分可以通过离子交换完全转化。然而,纳米晶体晶格体积的纳米级变化如何在离子交换过程中转化为3D BaCO₃/SiO₂结构的微观尺寸变化,仍然未知,更不用说可预测了。在这里,我们证明微观形状会适应纳米晶体原子间距的收缩和膨胀。从BaCO₃/SiO₂开始,我们通过将BaCO₃纳米晶体转化为一系列硫族化物和钙钛矿,系统地减小和增加晶格体积。基于几何分析,我们精确预测了微观纳米复合材料体积如何随纳米级晶体体积的变化而变化。二氧化硅基质有助于机械柔韧性以适应纳米级体积变化,同时以高保真度保留原始复合材料的3D形态和精细细节。形状保持转化反应的多功能性和可预测性为将纳米复合材料用作功能组件开辟了令人兴奋的机会。
