Failure by Fracture and Fatigue in 'Nano' and 'Bio' Materials

R. O. RITCHIE; C. L. MUHLSTEIN; R. K. NALLA

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Failure by Fracture and Fatigue in 'Nano' and 'Bio' Materials

机译：“纳米”和“生物”材料因断裂和疲劳而失效

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The behavior of nanostructured materials/small-volume structures and biological/bio-implantable materials, so-called "nano" and "bio" materials, is currently much in vogue in materials science. One aspect of this field, which has to date received only limited attention, is their fracture and fatigue properties. In this paper, we examine two topics in this area, namely the premature fatigue failure of silicon-based micron-scale structures for microelectromechanical systems (MEMS), and the fracture properties of mineralized tissue, specifically human bone.

机译：纳米结构材料/小体积结构和生物/生物可植入材料（所谓的“纳米”和“生物”材料）的行为目前在材料科学中非常流行。迄今为止仅受到有限关注的这一领域的一个方面是它们的断裂和疲劳性能。在本文中，我们研究了该领域中的两个主题，即用于微机电系统（MEMS）的硅基微米级结构的过早疲劳失效，以及矿化组织（特别是人骨）的断裂特性。

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《JSME International Journal. Series C, Mechanical Systems, Machine Elements and Manufacturing》 |2004年第3期|p.238-251|共14页
作者
R. O. RITCHIE; C. L. MUHLSTEIN; R. K. NALLA;
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正文语种 eng
中图分类机械、仪表工业;机械学（机械设计基础理论）;
关键词
fracture toughness; fatigue; polysilicon; thin films; mems; bone;

机译：断裂韧性;疲劳;多晶硅;薄膜;薄膜;骨;

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1. Failure by Fracture and Fatigue in 'Nano' and 'Bio' Materials [J] . R. O. RITCHIE, C. L. MUHLSTEIN, R. K. NALLA JSME International Journal. Series C, Mechanical Systems, Machine Elements and Manufacturing . 2004,第3期

机译：“纳米”和“生物”材料因断裂和疲劳而失效
2. NT2F9 Ninth International Conference New trends in fatigue and fracture 'Failures of materials and structures by fatigue and fracture' [J] . International journal of applied mechanics and engineering . 2009,第2期

机译：NT2F9第九届国际会议疲劳和断裂的新趋势“由于疲劳和断裂导致的材料和结构失效”
3. Theory of Superplasticity and Fatigue of Polycrystalline Materials Based on Nanomechanics of Fracturing and Failure [J] . Cherepanov G. P. Physical mesomechanics . 2019,第1期

机译：基于破裂和破坏的纳米力学的多晶材料超塑性和疲劳理论
4. Fracture and fatigue:From macro to nano scales and from engineered materials to biological systems [C] . Subra Suresh International conference on fracture . 2013

机译：断裂和疲劳：从宏观到纳米尺度，从工程材料到生物系统
5. THE RESIDUAL STRENGTH DETERMINATION DUE TO FATIGUE LOADING BY FRACTURE MECHANICS IN NOTCHED COMPOSITE MATERIALS (STRESS CONCENTRATION, FAILURE CRITERIA). [D] . JEN, MING-HWA ROBERT. 1985

机译：缺口复合材料中由于断裂力学作用的疲劳载荷而确定的残余强度（应力集中，破坏准则）。
6. Fatigue Crack Growth and Fracture of Internal Fixation Materials in In Vivo Environments—A Review [O] . Kailun Wu, Bin Li, Jiong Jiong Guo 2021

机译：体内环境中内固定材料的疲劳裂纹生长和骨折 - 综述
7. Theory of Superplasticity and Fatigue of Polycrystalline Materials Based on Nanomechanics of Fracturing and Failure [O] . G. P. Cherepanov 2019

机译：基于压裂纳米力学的多晶材料超塑性高塑性和疲劳理论

Failure by Fracture and Fatigue in 'Nano' and 'Bio' Materials

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