题 目:基于现代混凝土纳米技术的混凝土多尺度性能研究
Investigation on multiscale properties of concrete based on modern concrete nanotechnology
时 间:2017年11月24日14:30-16:00
地 点:七号楼二楼大会议室
报告人:悉尼科技大学,Lecture,李文贵
欢迎广大师生参加
土木与交通学院
2017年11月20日
报告人简介:
李文贵博士目前为澳大利亚悉尼科技大学(University of Technology Sydney,世界排名前200名)土木与环境工程学院讲师和博士生导师,并担任悉尼科技大学基础建设研究中心(Center for Built Infrastructure Research)核心成员。2013年获得同济大学与美国西北大学(Northwestern University)联合培养结构工程专业博士学位。在美国西北大学学习期间,师从著名混凝土领域专家、美国工程院院士和中国工程院外籍院士Surendra P. Shah教授。2014年获得澳大利亚科学基金会优秀青年科学基金(ARC DECRA Fellow)。2015-2016年为澳大利亚蒙纳士大学土木工程学院(Monash University)从事特聘研究员工作。2016年入职悉尼科技大学工作,并获得永久性教师职位。2017年获得悉尼科技大学杰出青年基金项目。研究方向主要包括纳米混凝土技术、混凝土耐久性、地聚合物混凝土、多功能混凝土、混凝土抗高温和抗冲击性能和绿色再生骨料混凝土等。在本领域国际权威(重要)期刊ACI Materials, Cement and Concrete Research, Cement and Concrete Composites和Construction and Building Materials等国际期刊发表学术论文30多篇,国际会议论文20余篇, Google Scholar论文引用次数达700多次,并担任10多个国际期刊的审稿人。目前在澳大利亚主持4个纳米混凝土和地聚合物混凝土方面的研究项目,同时指导5位博士研究生,并担任澳大利亚基金委员会项目评审专家。
报告摘要:
Nano-engineering encompasses the techniques of manipulation of the structure at the nanometer scale to develop a new generation of tailored, multifunctional, cementitious composites with superior mechanical performance and durability potentially having a range of novel properties such as: low electrical resistivity, self-sensing capabilities, self-cleaning, self-healing, high ductility, and self-control of cracks. Concrete can be nano-engineered by the incorporation of nanosized building blocks or objects to control material behavior and add novel properties, or by the grafting of molecules onto cement particles, cement phases, aggregates, and additives to provide surface functionality, which can be adjusted to promote specific interfacial interactions.
The presentation will review the current state of the field of nanotechnology in concrete and recent key advances. The potential of nanotechnology to improve the performance of concrete and to lead to the development of novel, sustainable, advanced cement-based composites with unique mechanical, thermal, and electrical properties is promising. The advances in instrumentation and computational science are enabling scientists and engineers to obtain unprecedented information about concrete, from the atomic through the continuum scale, and the role of nanoscale structures on performance and durability. This information is crucial for predicting the service life of concrete and for providing new insights on how it can be improved. New developments have taken place in the nano-engineering and nanomodification of concrete. Additionally, introduction of these novel materials into the public sphere through civil infrastructure will necessitate an evaluation and understanding of the impact they may have on the environment and human lives.
