Bridging finite element-molecular dynamics method for multiscale modeling of solids

用于固体多尺度建模的有限元-分子动力学桥接方法

• 批准号: 217525-2008
• 负责人: Behdinan, Kamran
• 金额: $ 1.38万
• 依托单位: University of Toronto
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2011
• 资助国家: 加拿大
• 起止时间: 2011-01-01 至 2012-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=478064
• 关键词: Bridging; finite; element; molecular; dynamics

Nanotechnology has recently emerged as a rapidly growing field. The applications of nanoscience and nanotechnology are immense: nano-materials are used to strengthen composites and alloys; nano-mechanics govern 'smart' materials, capable of healing themselves from cracks; nano-biomechanics can be used to directly study the most inaccessible parts of the human body, etc. Along with rapid progress in nano-scale materials and systems, there is an increasing demand for probing into fine space and time scale. The main objective of this research is to develop an effective multiscale modeling method to practically simulate and analyze nano-scale problems, over a wide range of length and time scales. This method will be used to study problems, such as: behaviour of dislocations in metal crystal lattices, influence of new alloying and added elements on mechanical properties of metals, mechanical behaviour of HAp-TZP(3Y) nano-composite, fracture of defected carbon nanotubes, and dynamic behaviour of multi-wall carbon nanotubes used in nanoelectromechanical systems. Next by incorporating molecular simulations and a nonlinear continuum mechanics-based constitutive formulation that includes the behaviour of the polymer materials, a hyperelastic multiscale modeling technique will be developed. This technique will be employed to predict the elastic properties of polycarbonate (BPDA) and polyimide (APB) monomers. Finally the effects of nano-particles on the toughness of nano-composites, ZrO2/nano-SiC will be investigated. Overall, the proposed research aims to provide effective engineering tools for design and fabrication of nano-structured materials and systems. This will in turn lead to new theoretical developments and commercial applications in the nanotechnology area; and thus will bring competitive advantages to the Canadian companies in producing innovative nano-products in the very rapid growing market globally. The proposed research focus is in line with the priority research area as identified by NSERC in the 2000-2002 reallocations exercise report for GSC 13 and the newly established Canadian National Institute of Nanotechnology.

纳米技术最近成为一个快速发展的领域。纳米科学和纳米技术的应用是巨大的：纳米材料用于增强复合材料和合金;纳米力学管理“智能”材料，能够从裂缝中自我修复;纳米生物力学可以用于直接研究人体最难以接近的部分等。沿着纳米尺度材料和系统的快速发展，对精细空间和时间尺度的探索需求日益增加。本研究的主要目的是开发一种有效的多尺度建模方法，实际模拟和分析纳米尺度的问题，在很宽的范围内的长度和时间尺度。该方法将用于研究金属晶格中位错的行为、新合金和添加元素对金属力学性能的影响、HAp-TZP（3 Y）纳米复合材料的力学行为、缺陷碳纳米管的断裂以及用于纳米机电系统的多壁碳纳米管的动态行为等问题。接下来，通过将分子模拟和非线性连续介质力学为基础的本构制剂，包括聚合物材料的行为，超弹性多尺度建模技术将被开发。该技术将被用来预测聚碳酸酯（BPDA）和聚酰亚胺（APB）单体的弹性性能。最后研究了纳米颗粒对纳米复合材料ZrO 2/nano-SiC韧性的影响。总体而言，拟议的研究旨在为纳米结构材料和系统的设计和制造提供有效的工程工具。这将反过来导致新的理论发展和纳米技术领域的商业应用，从而将带来竞争优势，加拿大公司在生产创新的纳米产品在非常快速增长的全球市场。拟议的研究重点与NSERC在2000-2002年GSC 13和新成立的加拿大国家纳米技术研究所的重新分配工作报告中确定的优先研究领域一致。