Hydrogels from Hydrothermal Treatment of Nanocrystalline Cellulose and their Applications

纳米晶纤维素水热处理水凝胶及其应用

• 批准号: RGPIN-2018-03691
• 负责人: Hatzikiriakos, Savvas
• 金额: $ 4.66万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=711968
• 关键词: Hydrogels; Hydrothermal; Treatment; Nanocrystalline; Cellulose

Canada's cellulosic fibre species are known as an abundant, renewable organic material with outstanding properties and a variety of existing and potentially useful, high-demand applications. More specifically nanocrystalline cellulose (CNC) is of particular interest to this proposal due to: (i) it is a unique material possessing a number of outstanding properties; (ii) Canada has its own CNC technologies and patenting rights to produce these materials; (iii) CNC's potential use in many applications is not yet fully explored. The proposal is based on our previous research in the area of kraft pulp suspensions and aims to produce technologies important to the Canadian economy and to that of the province of British Columbia. It is noted that numerous Canadian and International companies exist with interest in cellulose-based bio-products including Domtar, Solegear, Performance Biofilaments, Fibria, Canfor and Noram to name but a few. We have active collaboratons with Noram, Solegear and FPinnovations and we plan to continue and extend these collaborations. The long term objective is to develop transformative technologies that will target to convert CNC into useful materials and in addition combine it with biodegradable polymers to create value-added bio-products. More specific targets of this proposal are first to develop hydrogels and polyelectrolyte hydrogels based on CNC as sensors for external stimuli such as pressure, temperature and pH . The optimum properties of these sensors will be determined by developing a Molecular Dynamics (MD) method to simulate polyelectrolyte hydrogels. This theoretical framework will calculate the dynamics of these stimuli-responsive polyelectrolyte “smart” hydrogels and the results obtained from the simulations will be used to optimise the properties of the hydrogels to enable their manufacture. Moreover the use of polymer grafted CNC will be used to develop bio-nanocomposites. The main goal is to first synthesize biodegradable polymers and co-polymers of controlled microstructure which will be grafted onto the CNC fibers to produce fully biodegradable and environmentally friendly biocomposites. Finally the use of CNC hydrogels that will be produced by hydrogel methods (fully environmentally-friendly) will be used in stabilizing important products such as inks and paints, supporting Canada in leading the transition from a fossil-based economy to a sustainable and renewable bio-economy. This proposal is designed to train 10 HQP at different levels from undergraduate (UG) to PhD. The outcomes from this work will stimulate industrial interest and funding will be generated to double this number of HQP within the period of this program as has been the case in the past. The essence of this proposal is that it aims to develop fully bio-based, “smart” technology applications and products which will be essential building blocks in a sustainable environment.

加拿大的纤维素纤维品种被认为是一种丰富的可再生有机材料，具有出色的性能和各种现有的和潜在的有用的高需求应用。更具体地说，纳米晶体纤维素（CNC）对该提案特别感兴趣，因为：（i）它是一种具有许多突出特性的独特材料;（ii）加拿大拥有自己的CNC技术和生产这些材料的专利权;（iii）CNC在许多应用中的潜在用途尚未得到充分探索。该提案基于我们以前在硫酸盐纸浆悬浮液领域的研究，旨在生产对加拿大经济和不列颠哥伦比亚省经济具有重要意义的技术。值得注意的是，许多加拿大和国际公司对纤维素生物产品感兴趣，包括Domtar，Solegear，Performance Biofilaments，Fibria，Canfor和Noram等。我们与Noram、Solegear和FPinnovations有着积极的合作，我们计划继续并扩大这些合作。 长期目标是开发变革性技术，将CNC转化为有用的材料，并将其与可生物降解的聚合物联合收割机结合，以创造增值的生物产品。该提案的更具体的目标是首先开发基于CNC的水凝胶和水凝胶微球，作为外部刺激如压力、温度和pH的传感器。这些传感器的最佳性能将通过开发一种分子动力学（MD）方法来模拟水凝胶。这个理论框架将计算这些刺激响应的“智能”水凝胶的动力学，从模拟中获得的结果将用于优化水凝胶的性能，以使其能够制造。此外，使用聚合物接枝CNC将用于开发生物纳米复合材料。其主要目标是首先合成具有可控微观结构的可生物降解聚合物和共聚物，这些聚合物和共聚物将接枝到CNC纤维上，以生产完全可生物降解和环境友好的生物复合材料。最后，通过水凝胶方法（完全环保）生产的CNC水凝胶将用于稳定墨水和油漆等重要产品，支持加拿大领导从化石经济向可持续和可再生生物经济的过渡。 本方案旨在培养10名不同层次的HQP，从本科（UG）到博士。这项工作的成果将激发工业界的兴趣，并将产生资金，在本计划期间将HQP的数量增加一倍，这是过去的情况。这项建议的实质是，它旨在开发完全基于生物的“智能”技术应用和产品，这将是可持续环境的基本组成部分。