Effects of Grain Boundary Geometry and Boron Addition on the Local Mechanical Behavior of Interstitial-Free (IF) Steels

Endoh, Kazuki; Ii, Seiichiro; Kimura, Yuuji; Sasaki, Taisuke; Goto, Sota; Yokota, Takeshi; Ohmura, Takahito

doi:10.2320/matertrans.mt-m2021128

Cited by 9 publications

(2 citation statements)

References 40 publications

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“…Hardness testing is widely used to evaluate the plastic deformability of materials. In the last few decades, nanoindentation testing methods [ 8 , 9 , 10 , 11 , 12 , 13 , 14 , 15 , 16 , 17 , 18 ] have been developed and are rapidly becoming widespread for the evaluation of various materials, including steels [ 19 ], tungsten [ 20 ], copper [ 21 ], and NiTi alloys [ 22 ]. This has produced new metallurgical knowledge about nanoscale deformation that is useful for the development of superior materials.…”

Section: Introductionmentioning

confidence: 99%

Hardness–Deformation Energy Relationship in Metals and Alloys: A Comparative Evaluation Based on Nanoindentation Testing and Thermodynamic Consideration

2021

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Nanoindentation testing using a Berkovich indenter was conducted to explore the relationships among indentation hardness (H), elastic work energy (We), plastic work energy (Wp), and total energy (Wt = We + Wp) for deformation among a wide range of pure metal and alloy samples with different hardness, including iron, steel, austenitic stainless steel (H ≈ 2600–9000 MPa), high purity copper, single-crystal tungsten, and 55Ni–45Ti (mass%) alloy. Similar to previous studies, We/Wt and Wp/Wt showed positive and negative linear relationships with elastic strain resistance (H/Er), respectively, where Er is the reduced Young’s modulus obtained by using the nanoindentation. It is typically considered that Wp has no relationship with We; however, we found that Wp/We correlated well with H/Er for all the studied materials. With increasing H/Er, the curve converged toward Wp/We = 1, because the Gibbs free energy should not become negative when indents remain after the indentation. Moreover, H/Er must be less than or equal to 0.08. Thermodynamic analyses emphasized the physical meaning of hardness obtained by nanoindentation; that is, when Er is identical, harder materials show smaller values of Wp/We than those of softer ones during nanoindentation under the same applied load. This fundamental knowledge will be useful for identifying and developing metallic materials with an adequate balance of elastic and plastic energies depending on the application (such as construction or medical equipment).

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Section: Introductionmentioning

confidence: 99%

Hardness–Deformation Energy Relationship in Metals and Alloys: A Comparative Evaluation Based on Nanoindentation Testing and Thermodynamic Consideration

2021

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“…The pile-up model is widely accepted for understanding the Hall-Petch relationship [118], and the grain boundarydislocation interaction has been investigated from both experimental and computational viewpoints . Recently, nanoindentation techniques have been employed to understand the mechanical response in the vicinity of an individual grain boundary [128][129][130][131][132][133][134][135][136][137][138][139][140][141][142][143]. Moreover, in situ TEM (and SEM) straining experiments are powerful tools for understanding the microstructure evolution of small-scale specimens under the stress field.…”

Section: Dynamics and Quantitative Evaluation Associated With The Gra...mentioning

confidence: 99%

Quantitative Characterization by Transmission Electron Microscopy and Its Application to Interfacial Phenomena in Crystalline Materials

2024

Materials

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This paper reviews quantitative characterization via transmission electron microscopy (TEM) and its application to interfacial phenomena based on the results obtained through the studies. Several signals generated by the interaction between the specimen and the electron beam with a probe size of less than 1 nm are utilized for a quantitative analysis, which yields considerable chemical and physical information. This review describes several phenomena near the interfaces, e.g., clear solid–vapor interface (surface) segregation of yttria in the zirconia nanoparticles by an energy-dispersive X-ray spectroscopy analysis, the evaluation of the local magnetic moment at the grain boundary in terms of electron energy loss spectroscopy equipped with TEM, and grain boundary character dependence of the magnetism. The direct measurement of the stress to the dislocation transferred across the grain boundary and the microstructure evolution focused on the grain boundary formation caused by plastic deformation are discussed as examples of material dynamics associated with the grain boundary. Finally, the outlook for future investigations of interface studies, including the recent progress, is also discussed.

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Ultrahigh yield strength and large uniform elongation achieved in ultrafine-grained titanium containing nitrogen

et al. 2022

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Effects of Grain Boundary Geometry and Boron Addition on the Local Mechanical Behavior of Interstitial-Free (IF) Steels

Cited by 9 publications

References 40 publications

Hardness–Deformation Energy Relationship in Metals and Alloys: A Comparative Evaluation Based on Nanoindentation Testing and Thermodynamic Consideration

Hardness–Deformation Energy Relationship in Metals and Alloys: A Comparative Evaluation Based on Nanoindentation Testing and Thermodynamic Consideration

Quantitative Characterization by Transmission Electron Microscopy and Its Application to Interfacial Phenomena in Crystalline Materials

Ultrahigh yield strength and large uniform elongation achieved in ultrafine-grained titanium containing nitrogen

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