Many methods are used to develop 3D printing materials, and the sources for new 3D printing materials are seemingly endless. In a study entitled “Additive Manufacturing of 3D Glass-Ceramics down to Nanoscale Resolution,” a group of researchers use a sol-gel resin to fabricate an inorganic ceramic.
“Fabrication of a true-3D inorganic ceramic with resolution down to nanoscale using sol-gel resist precursor is demonstrated,” the researchers explain. “The method has an unrestricted free-form capability, control of the fill-factor, and high fabrication throughput. A systematic study of the proposed approach based on ultrafast laser 3D lithography of organic-inorganic hybrid sol-gel resin followed by a heat treatment enabled formation of inorganic amorphous and crystalline composites guided by the composition of the initial resin.”
A popular hybrid organic-inorganic sol-gel resist SZ2080 was converted into a material with entirely different properties through polymer-to-ceramic transition via high temperature sintering and oxidation. The silica and zirconia in the original material in the resist in the 20% inorganic part of the component led to the emergence of silica and zirconia crystalline phases in the final sintered ceramic material. In addition, “a proportional downscaling of the 3D polymerized object takes place with significant volume change of 40-50% dependent on annealing protocol without distortion of the proportions of the initial 3D design,” meaning that complex nanoscale patterns can be formed.
For the experiment, the researchers 3D printed different structures including bulk-cubes, periodic-3D woodpile micro lattices, free form structures, micro-sculptures, combining bulk and nanometer feature elements with complex bends, and macroscopic hexagonal 3D lattices which are usually used as artificial cell scaffolds.
“As the temperature increases the spectral shape changes and evolves via qualitatively two distinct form-factors,” the researchers state. “Close examination of the initial spectrum and comparison to that for T = 1000◦C reveals that they differ by the molecular vibrations which can be associated with the carbon-carbon, carbon-oxygen, carbon-hydrogen bonds. After heat-treatment those spectral lines vanishes. The new spectral form coincides with that typical for silica glass; we measured a control sample of fused silica.”
High temperature calcination of the 3D polymerized structures, created by 3D laser writing in the SZ2080 polymer resist, produced either silica-based glass or a polycrystalline ceramic pure inorganic material. A glass phase dominated in samples annealed at temperatures up to 1200°C, while formation of polycrystalline silica and zirconia was observed in samples annealed above 1200ºC.
“The presented modifications of silica-zirconia-rich resist SZ2080 from glass to polycrystalline ceramic by annealing shows a principle of the thermally guided 3D material printing which has nanoscale resolution,” the researchers conclude. “Isotropic down-sizing of the initial 3D polymerized objects with a volume fraction of 0.5-to-1 simplifies fabrication since there is no need to alter proportions of the initial material as it is widely used in DLW 3D nanolithography of photonic crystals, micro-optics and biomedical scaffolds in order to eliminate the effect of anisotropic shrinkage.”
The mechanical properties of the final structures, according to the researchers, acquire new features, such as resilience in harsh physical and chemical environments.
“Since nanoscale materials can initiate precipitation and guide growth of nano-crystallites, a wide field for experimentation horizons are widened by the presented modality of additive manufacturing,” they add.
Authors of the paper include Darius Gailevicius, Viktorija Padolskyte, Lina Mikoliūnaite, Simas Šakirzanovas, Saulius Juodkazis and Mangirdas Malinauskas.
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