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引用次数: 1
摘要
晶格缺陷如空位、位错和晶界的观察和评价在材料设计中是非常重要的。电阻率测量在获得平均微观结构信息方面优于电子显微镜,包括晶格缺陷的密度和类型。本研究的目的是估计商业纯度(CP) Ti在拉伸变形过程中电阻率的变化。采用直流四点法测量冷轧Ti薄板沿轧制方向(RD)在77 K (ρ77)和300 K (ρ300)时的电阻率,确定了ρ77 = α/(R - 1) + β, R = ρ300/ρ77的Matthiessen经验关系。ρ77与1/(R - 1)呈线性关系,α值为0.5266,β值为- 0.0024。将阻力比R代入Matthiessen经验关系式,估算拉伸变形过程中ρ77的变化。在弹性变形区,电阻率变化不明显。因此,位错密度变化不明显。然而,在屈服点附近,电阻率确实急剧增加。
Measurement of Electrical Resistivity during Tensile Deformation of Pure Ti
The observation and evaluation of lattice defects such as vacancies, dislocations, and grain boundaries are very important in materials design. Electrical resistivity measurement is superior to electron microscopy for obtaining average microstructural information, including density and type of lattice defects. The purpose of this study was to estimate changes in electrical resistivity during the tensile deformation of commercial-purity (CP) Ti. The electrical resistivity of a cold-rolled Ti sheet was measured at 77 K (ρ77) and 300 K (ρ300) along the rolling direction (RD) using a direct current (DC) four-point method to determine Matthiessen’s empirical relationship, ρ77 = α/(R – 1) + β, R = ρ300/ρ77. Plots of ρ77 versus 1/(R – 1) showed a linear relationship, and the values of α and β were determined to be 0.5266 and –0.0024, respectively. Changes in ρ77 during tensile deformation were estimated by substituting the resistance ratio R into Matthiessen’s empirical relationship. In the elastic deformation region, no remarkable change in the resistivity was observed. Therefore, the dislocation density did not change significantly. However, the resistivity did increase drastically near the yield point.
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