材料科学
微加工
制作
3D打印
微观结构
纳米技术
热稳定性
聚合
变形
立体光刻
玻璃化转变
复合材料
超材料
3d打印机
聚合物
光子学
墨水池
热的
纳米结构
微技术
快速成型
毛细管作用
熔融沉积模型
变形(气象学)
聚二甲基硅氧烷
作者
Tao Yuan,Rui Li,Zhaoxin Lao,Yusheng Jin,Hao Wu,Zeheng Wu,Wei Zeng,Modong Jiang,Jincheng Ni,Yanlei Hu,Dong Wu,Jiaru Chu,Jiawen Li
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-11-18
卷期号:19 (47): 40547-40560
被引量:2
标识
DOI:10.1021/acsnano.5c15343
摘要
Four-dimensional (4D) printing enables simple structures to undergo programmed and controlled morphological reconfiguration for fabricating more complex three-dimensional (3D) architectures, which has recently garnered considerable research interest. However, 4D printing of glass, particularly for glass microstructures, faces fundamental challenges due to the limited deformability of glass and the lack of reliable deformation mechanisms. Here, a capillary-force-assisted assembly approach is presented to realize the 4D printing of glass microstructures with programmable morphing capabilities. The precursor microstructures fabricated by two-photon polymerization are reconfigured into complex 3D microassemblies under postprinting capillary force, ultimately yielding transparent glass microstructures upon thermal sintering. Compared with conventional 3D printing approaches, our 4D printing approach enables the fabrication of geometrically sophisticated glass microstructures, particularly development-resistant geometries such as hollow microarchitectures, which are previously unattainable through additive manufacturing techniques. Furthermore, the fabricated glass-based chiroptical metamaterials demonstrate giant chiroptical responses and enhanced environmental stability when compared to conventional polymeric counterparts. Fully enclosed hollow microarchitectures successfully encapsulate a diversity of inorganic particles. This work provides a scalable platform for advanced glass microfabrication and allows for the 4D printing of functional inorganic devices.
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