Department of Chemical and Biological Engineering, University of Colorado Boulder, Boulder, CO 80309, United States.
Department of Chemical and Biological Engineering, University of Colorado Boulder, Boulder, CO 80309, United States; Materials Science and Engineering Program, University of Colorado Boulder, Boulder, CO 80309, United States.
Dent Mater. 2024 Jun;40(6):976-983. doi: 10.1016/j.dental.2024.05.009. Epub 2024 May 9.
This study demonstrates the use of photopolymerization to create semi-crystalline linear polymers suitable for thermally reversible materials in dental cast moldings produced from 3D printing.
An aromatic diallyl, aliphatic dithiol chain extender, and monofunctional thiol were used in a photoinitiated system. The photopolymerization and crystallization kinetics as a function of chemistry and temperature were investigated using spectroscopy and calorimetry. These insights were used to realize vat photopolymerization-based 3D printing of functional objects that could be remotely melted and thereby removed using induction heating.
The addition of monothiol was shown to decrease the polymer molecular weight which correspondingly increased the crystallization rate. Photopolymerization kinetics are independent of temperature while crystallization was slowed as the temperature approaches the melting point of the materials. Through inclusion of chromium oxide, semicrystalline materials could be melted through induction heating. These materials were implemented in vat photopolymerization 3D printing to realize high-resolution objects that could be used as releasable dental molds following printing and induction heating.
This work demonstrates a proof-of-concept methodology to realize directly printable, thermally reversible semicrystalline materials for potential use as dental molding materials.
本研究展示了光聚合在牙科铸模 3D 打印中的应用,以制造适用于热可逆材料的半晶线性聚合物。
采用芳香型二烯丙基、脂肪族二硫醇链延长剂和单官能硫醇作为光引发体系。使用光谱法和量热法研究了光聚合和结晶动力学与化学和温度的关系。这些见解被用于实现基于 vat 光聚合的功能物体的 3D 打印,这些物体可以通过感应加热远程熔化并去除。
加入单硫醇会降低聚合物的分子量,从而相应提高结晶速率。光聚合动力学与温度无关,而结晶速度随着温度接近材料熔点而减慢。通过添加氧化铬,可以通过感应加热使半晶材料熔化。这些材料被应用于 vat 光聚合 3D 打印,以实现高分辨率的物体,这些物体可以在打印和感应加热后用作可释放的牙科模具。
这项工作展示了一种实现直接可打印、热可逆半晶材料的概念验证方法,这些材料有可能用作牙科成型材料。
