朱银波,九三学社社员,中国科学技术大学近代力学系,副教授,硕士研究生导师,中国科学院青年创新促进会会员,中国科学院青年创新促进会合肥分会秘书长。1991年3月出生于河南省潢川县,2013年6月获得华北水利水电大学工程力学学士学位,2017年6月获得中国科学技术大学固体力学博士学位(导师:吴恒安教授),同年获得中国科学院院长特别奖。入选2017年度博士后创新人才支持计划,2022年度中国科学院青年创新促进会会员,2024年度中国科学技术大学仲英青年学者;曾获得2017年度中国科学技术大学优秀博士学位论文奖,2018年度中国科学院优秀博士学位论文奖,2022年度中国科学技术大学翟光龙学者基金。主讲本科生课程《材料力学》和《工程计算方法》以及研究生课程《高等应用数学》。
研究方向:微纳米力学
研究兴趣:序构材料微纳米力学、材料设计与多尺度力学、二维受限水与纳尺度限域传质
(旧主页网址http://staff.ustc.edu.cn/~zhuyinbo/)
Introduction of my investigations:
My research interest now focuses on the mechanical behavior and design of hierarchically structural materials, including graphene-based nacre-like materials, nanocellulose-based hierarchical materials, nanoceramics, and amorphous carbons. During my Ph.D. period, I focused on 2D water/ice in graphene nanocapillaries and mass transfer under nanoconfinement.
Material design is gradually breaking through the assumption of continuum system. The combination of different building blocks into complex architectures has opened unprecedented opportunities in materials science and engineering. Traditional mechanical studies have been unable to establish the theoretical framework of advanced materials at multiscale, resulting in more common scientific problems emerged from interdisciplinary fields. Although modern physics edged mechanics out into the wilds of engineering, we should note that there is plenty of room in the cross field of mechanics and advanced materials.
The objective of my research is to improve the understanding of multiscale structure-property relationships and design principles in hierarchical materials, as well as the inherent correlations between mechanical behavior and application functionality of advanced materials. The development of multiscale mechanics has covered from the physical edge at atomistic scale to the framework of continuum theories. It is of the utmost importance to extend the models and methods of multiscale mechanics that would provide in-depth understandings for the structure-property-function relationships of materials. In my investigations, our group aims to reveal the micromechanical mechanism and optimization strategy of high-performance hierarchical materials through the combination of multiscale theoretical simulations and experimental characterizations, which should help to realize the mechanical design of hierarchical microstructures and interfaces in advanced materials oriented by application requirements.