In-situ SEM cyclic nanoindentation of pre-sintered and sintered zirconia materials.

Afifah Z. Juri, A. Basak, Ling Yin
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引用次数: 3

Abstract

Efficient diamond machining of zirconia requires a comprehensive understanding of repetitive diamond indentation mechanics. This paper reports on in-situ cyclic nanoindentations of pre-sintered and sintered zirconia materials performed inside a scanning electron microscope (SEM). In-situ SEM imaging of cyclic indentation processes and high-magnification SEM mapping of indentation imprints were conducted. The elastic and plastic behaviors of pre-sintered and sintered zirconia materials were investigated as a function of the cyclic nanoindentation number using the Sakai and Sakai-Nowak models. For pre-sintered zirconia, cyclic nanoindentation induced quasi-plastic deformation, causing localized agglomeration of zirconia crystals with microcracks and large cracking along the indentation edge. Severely compressed, fragmented, and pulverized zirconia crystals and smeared surfaces were also observed. For sintered zirconia, shear bands dominated quasi-plastic deformation with the formation of edge pile-ups and localized microfractures occurred at indentation apex and diagonals. All elastic and plastic behaviors for pre-sintered and sintered zirconia materials revealed significantly microstructure-dependent. Pre-sintered zirconia yielded significantly lower contact hardness, Young's moduli, resistance to plasticity, elastic deformation components, and resistance to machining-induced cracking, and higher elastic and plastic displacements than sintered state. Meanwhile, all the behaviors for the two materials were independent from the cyclic nanoindentation number. A model was proposed for cyclic nanoindentation mechanics, revealing their cyclic indentation-induced microstructural changes in the two zirconia materials. This study advances the fundamental understanding of nanoindentation mechanics of zirconia materials.
预烧结和烧结氧化锆材料的原位SEM循环纳米压痕。
氧化锆的高效金刚石加工需要对重复金刚石压痕力学有全面的了解。本文报道了在扫描电子显微镜(SEM)内对预烧结和烧结氧化锆材料进行的原位循环纳米压痕。对循环压痕过程进行了原位SEM成像,并对压痕印记进行了高倍率SEM测绘。使用Sakai和Sakai-Nowak模型研究了预烧结和烧结氧化锆材料的弹性和塑性行为,作为循环纳米压痕数的函数。对于预烧结的氧化锆,循环纳米压痕引起准塑性变形,导致氧化锆晶体的局部团聚,沿压痕边缘出现微裂纹和大裂纹。还观察到严重压缩、破碎和粉碎的氧化锆晶体和涂抹的表面。对于烧结氧化锆,剪切带主导了准塑性变形,并在压痕顶点和对角线处形成了边缘堆积和局部微裂纹。预烧结和烧结氧化锆材料的所有弹性和塑性行为都显示出显著的微观结构依赖性。预烧结氧化锆的接触硬度、杨氏模量、塑性阻力、弹性变形成分和机械加工引起的裂纹阻力显著低于烧结状态,弹性和塑性位移也高于烧结状态。同时,这两种材料的所有行为都与循环纳米压痕数无关。提出了循环纳米压痕力学模型,揭示了循环压痕引起的两种氧化锆材料微观结构的变化。这项研究推进了对氧化锆材料纳米压痕力学的基本理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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