CAREER: Illuminating molecular-level effects in new plant-based nanocomposites for additive manufacturing by stereolithography

职业：通过立体光刻阐明用于增材制造的新型植物基纳米复合材料的分子水平效应

• 批准号: 2337946
• 负责人: Stephen Chmely
• 金额: $ 62.53万
• 依托单位: Pennsylvania State Univ University Park
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2024
• 资助国家: 美国
• 起止时间: 2024-08-01 至 2029-07-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2337946&HistoricalAwards=false
• 关键词: CAREER; Illuminating; molecular; level; effects

NON-TECHNICAL SUMMARYPlants are remarkable organisms. They are towering, sunlight-driven factories that use carbon dioxide, water, and soil nutrients to create all the materials they need to survive, including the factory itself! While many human-made factories are constructed using concrete, plants use long molecules called polymers to create supporting structures. These structures allow a plant to stand up and reach out for sunlight, move water and nutrients between its organs, and protect itself and its offspring. One of these polymers is called lignin, and it functions like the cement in concrete; it is a sort of glue that holds everything together. It also has a chemical structure that is very similar to many of the plastics that people use in everyday life. Therefore, lignin could be used to make new plastics, including those used for 3D printing. Using lignin to 3D print objects would be like how plants use lignin to manufacture their leaves, stems, roots, and seeds. Also, since plants are a renewable resource, plastics made from them would also be renewable, which is the opposite of current non-renewable plastics that are made from crude oil. Finally, since plants use carbon dioxide to make lignin, growing new plants to make new plastics would reduce the amount of carbon dioxide in the atmosphere, which could lessen its effect on climate change. The goal of this project is to learn how to control the structure of lignin taken from plants and use it to create new materials for 3D printing. New chemistry methods to extract, modify, and use lignin will be explored. The principal investigator will also study how using lignin and other plant polymers could lessen the effects of climate change and how using them could help people in rural communities get good jobs related to these new renewable materials. In addition, the research plan will be augmented by enriching undergraduate education at the intersection of polymer science and sustainability, supporting undergraduate research opportunities related to sustainability, and disseminating cutting edge research principles to K12 students through Research Experiences for Teachers program.TECHNICAL SUMMARYThe overarching goals of this CAREER plan are to (1) develop 3D printable composite resins consisting of suitably modified nanocellulose and lignin, (2) use this research as a platform to introduce students to both fundamental principles of polymer science and issues of social justice and sustainability that underpin renewable bioproducts, and (3) contribute to global efforts to diminish the effects of anthropogenic climate change by reducing the concentration of atmospheric carbon. The proposed CAREER plan will advance knowledge and understanding in several fields, including green engineering, synthetic chemistry, and polymer science and engineering. The aims include (1) establishing approaches to control the oxidation state of aliphatic carbons in lignin during fractionation and upgrading, (2) developing techniques to control lignin structure and function as a photopolymerizable polymer matrix, and (3) identifying methods to blend modified lignin feedstocks to create new stereolithography resins. These activities explore transformative concepts, including producing entirely renewable biocomposite resins for 3D printing. In addition, the research plan will be augmented by (1) enriching undergraduate education at the intersection of polymer science and sustainability, (2) supporting undergraduate research opportunities related to sustainability and “Drawdown,” and (3) disseminating cutting edge research principles to K12 students through Research Experiences for Teachers.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

非技术概要植物是非凡的生物体，它们是高耸的、由阳光驱动的工厂，利用二氧化碳、水和土壤养分来制造它们生存所需的所有材料，包括工厂本身！植物使用称为聚合物的长分子来形成支撑结构，使植物能够直立并接触阳光，在其器官之间移动水分和养分，并保护自身及其后代，其中一种聚合物称为木质素。它的功能就像混凝土中的水泥一样；它是一种将所有东西粘合在一起的胶水，它的化学结构与人们日常生活中使用的许多塑料非常相似，因此，木质素可以用来制造新塑料。包括用于 3D 打印的木质素，就像植物使用木质素制造叶子、茎、根和种子一样。此外，由于植物是可再生资源，因此由它们制成的塑料也是可再生的。这是相反的最后，由于植物使用二氧化碳来制造木质素，种植新植物来制造新塑料将减少大气中的二氧化碳含量，从而减轻其对气候变化的影响。该项目的目标是了解如何控制从植物中提取的木质素的结构，并利用它来创建用于 3D 打印的新材料。首席研究员还将探索提取、修饰和使用木质素的新化学方法。研究如何使用木质素和其他植物聚合物可以减轻气候变化的影响，以及如何利用它们帮助农村社区的人们获得与这些新型可再生材料相关的好工作。此外，该研究计划将通过丰富聚合物交叉领域的本科教育来增强。科学和可持续发展，支持与可持续发展相关的本科生研究机会，并通过教师研究经验计划向 K12 学生传播前沿研究原理。技术摘要该职业计划的总体目标是 (1) 开发 3D由适当改性的纳米纤维素和木质素组成的可印刷复合树脂，（2）利用这项研究作为平台，向学生介绍聚合物科学的基本原理以及支撑可再生生物产品的社会正义和可持续性问题，以及（3）为全球努力做出贡献通过降低大气碳浓度来减少人为气候变化的影响 拟议的职业计划将促进多个领域的知识和理解，包括绿色工程、合成化学和聚合物科学与工程。目标包括（1）建立方法。来控制分馏和升级过程中木质素中脂肪族碳的氧化态，（2）开发控制木质素结构和作为光聚合聚合物基质的功能的技术，以及（3）确定混合改性木质素原料以创建新的立体光刻树脂的方法。概念，包括生产用于 3D 打印的完全可再生生物复合树脂。此外，该研究计划还将通过以下方式得到加强：(1) 丰富聚合物科学和交叉学科的本科教育。可持续发展，(2) 支持与可持续发展和“缩减”相关的本科生研究机会，以及 (3) 通过教师研究经验向 K12 学生传播前沿研究原理。该奖项反映了 NSF 的法定使命，并通过评估被认为值得支持利用基金会的智力优势和更广泛的影响审查标准。