Opportunities at the Intersection of 3D Printed Polymers and Pyrolysis for the Microfabrication of Carbon-Based Energy Materials.

IF 8.5 Q1 CHEMISTRY, MULTIDISCIPLINARY
JACS Au Pub Date : 2024-09-26 eCollection Date: 2024-10-28 DOI:10.1021/jacsau.4c00555
Philip R Onffroy, Samuel Chiovoloni, Han Lin Kuo, Max A Saccone, Jennifer Q Lu, Joseph M DeSimone
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引用次数: 0

Abstract

In an era marked by a growing demand for sustainable and high-performance materials, the convergence of additive manufacturing (AM), also known as 3D printing, and the thermal treatment, or pyrolysis, of polymers to form high surface area hierarchically structured carbon materials stands poised to catalyze transformative advancements across a spectrum of electrification and energy storage applications. Designing 3D printed polymers using low-cost resins specifically for conversion to high performance carbon structures via post-printing thermal treatments overcomes the challenges of 3D printing pure carbon directly due to the inability of pure carbon to be polymerized, melted, or sintered under ambient conditions. In this perspective, we outline the current state of AM methods that have been used in combination with pyrolysis to generate 3D carbon structures and highlight promising systems to explore further. As part of this endeavor, we discuss the effects of 3D printed polymer chemistry composition, additives, and pyrolysis conditions on resulting 3D pyrolytic carbon properties. Furthermore, we demonstrate the viability of combining continuous liquid interface production (CLIP) vat photopolymerization with pyrolysis as a promising avenue for producing 3D pyrolytic carbon lattice structures with 15 μm feature resolution, paving way for 3D carbon-based sustainable energy applications.

三维打印聚合物与热解技术在碳基能源材料微细加工方面的交叉机遇。
在对可持续高性能材料的需求日益增长的时代,增材制造(AM)(也称为三维打印)与聚合物热处理(或热解)的融合,形成了高比表面积分层结构碳材料,有望在电气化和能源存储应用领域推动变革性进步。由于纯碳无法在环境条件下聚合、熔化或烧结,因此使用低成本树脂设计三维打印聚合物,专门用于通过打印后热处理转换为高性能碳结构,克服了直接三维打印纯碳所面临的挑战。在本文中,我们概述了结合热解生成三维碳结构的 AM 方法的现状,并重点介绍了有待进一步探索的前景广阔的系统。作为这项工作的一部分,我们讨论了三维打印聚合物化学成分、添加剂和热解条件对生成的三维热解碳特性的影响。此外,我们还展示了将连续液相界面生产(CLIP)槽式光聚合与热解结合起来的可行性,这是生产特征分辨率为 15 μm 的三维热解碳晶格结构的一条可行途径,为基于三维碳的可持续能源应用铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
9.10
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