主 办:爆炸科学与技术国家重点实验室
安全与防护协同创新中心
冲击环境材料技术国家级重点实验室
报告题目:基于化学界面工程的先进高强钢设计
报告人:陈 浩 副教授
清华大学
时间:2020年9月16日下午15:30
报告人简介:
陈浩,清华大学材料学院副教授,博士生导师,中组部“青年千人计划”和国家自然科学基金委“优秀青年科学基金”获得者。分别于2007和2009年获天津大学学士和硕士学位,2013年获荷兰代尔夫特理工大学(TU Delft)优秀博士学位(Cum Laude,前4%)。 2013-2015年先后在TU Delft、加拿大英属哥伦比亚大学(UBC)进行博士后研究。研究领域为高性能钢铁材料的相变机理与材料设计,具体包括相变热力学与动力学、先进高强钢、氢脆、增材制造等。在Acta Materialia(17篇)、Science Advance、Scripta Materialia、Metallurgical Materials Transaction A等金属结构材料领域权威期刊上发表论文70余篇。在美国TMS、PRICM等国际会议作特邀报告20余次。获得了国际固态相变大会首届Aaronson奖、清华大学“学术新人奖”等荣誉。担任美国TMS学会相变分会理事、中国材料学会青年委员会理事;担任Metallurgical Materials Transaction A、Acta Metallurgica Sinica和Rare Metals期刊编委。
报告摘要:
For decades, Grain Boundary Engineering (GBE) has proven to be one of the most effective approaches to tailor the mechanical properties of metallic materials, although there are limits to the fineness and types of microstructures achievable, due to the grain size increasing rapidly once being exposed to thermal loads (low thermal stability of crystallographic boundaries). Here we deploy a novel Chemical Boundary Engineering (CBE) approach, augmenting the variety in available alloy design strategies, which enables us to create a material with an ultrafine hierarchically heterogeneous microstructure even after being heated to high temperatures. When applied to plain steels with carbon content of only up to 0.2 wt.% this approach yields ultimate strength levels beyond 2.0 GPa in combination with good ductility (>20%). Although demonstrated here for plain carbon steels, the CBE design approach is in principle applicable also to other alloys.
