Small Scale Deformation using Advanced Nanoindentation Techniques
Tsui, Ting
Small Scale Deformation using Advanced Nanoindentation Techniques - MDPI - Multidisciplinary Digital Publishing Institute 2019 - 1 electronic resource (168 p.)
Open Access
Small scale mechanical deformations have gained a significant interest over the past few decades, driven by the advances in integrated circuits and microelectromechanical systems. One of the most powerful and versatile characterization methods is the nanoindentation technique. The capabilities of these depth-sensing instruments have been improved considerably. They can perform experiments in vacuum and at high temperatures, such as in-situ SEM and TEM nanoindenters. This allows researchers to visualize mechanical deformations and dislocations motion in real time. Time-dependent behavior of soft materials has also been studied in recent research works. This Special Issue on ""Small Scale Deformation using Advanced Nanoindentation Techniques""; will provide a forum for researchers from the academic and industrial communities to present advances in the field of small scale contact mechanics. Materials of interest include metals, glass, and ceramics. Manuscripts related to deformations of biomaterials and biological related specimens are also welcome. Topics of interest include, but are not limited to:
Creative Commons
English
books978-3-03897-967-8 9783038979661 9783038979678
10.3390/books978-3-03897-967-8 doi
n/a nanoscale fracture toughness helium irradiation cement paste solder fracture Pop-in fatigue strain rate sensitivity viscoelasticity nuclear fusion structural materials biomaterials transmission electron microscopy mammalian cells quasicontinuum method brittleness and ductility morphology creep dimensionless analysis size effect mechanical properties hardness shear transformation zone TSV micro-cantilever beam multiscale InP(100) single crystal surface pit defect mixed-mode micromechanics soft biomaterials metallic glass atomic force microscopy (AFM) Bi2Se3 thin films constitutive model pop-in rate factor FIB nickel nanoindenter miniaturized cantilever beam hydrogen embrittlement nanoindentation irradiation hardening reduced activation ferritic martensitic (RAFM) steels tantalum
Small Scale Deformation using Advanced Nanoindentation Techniques - MDPI - Multidisciplinary Digital Publishing Institute 2019 - 1 electronic resource (168 p.)
Open Access
Small scale mechanical deformations have gained a significant interest over the past few decades, driven by the advances in integrated circuits and microelectromechanical systems. One of the most powerful and versatile characterization methods is the nanoindentation technique. The capabilities of these depth-sensing instruments have been improved considerably. They can perform experiments in vacuum and at high temperatures, such as in-situ SEM and TEM nanoindenters. This allows researchers to visualize mechanical deformations and dislocations motion in real time. Time-dependent behavior of soft materials has also been studied in recent research works. This Special Issue on ""Small Scale Deformation using Advanced Nanoindentation Techniques""; will provide a forum for researchers from the academic and industrial communities to present advances in the field of small scale contact mechanics. Materials of interest include metals, glass, and ceramics. Manuscripts related to deformations of biomaterials and biological related specimens are also welcome. Topics of interest include, but are not limited to:
Creative Commons
English
books978-3-03897-967-8 9783038979661 9783038979678
10.3390/books978-3-03897-967-8 doi
n/a nanoscale fracture toughness helium irradiation cement paste solder fracture Pop-in fatigue strain rate sensitivity viscoelasticity nuclear fusion structural materials biomaterials transmission electron microscopy mammalian cells quasicontinuum method brittleness and ductility morphology creep dimensionless analysis size effect mechanical properties hardness shear transformation zone TSV micro-cantilever beam multiscale InP(100) single crystal surface pit defect mixed-mode micromechanics soft biomaterials metallic glass atomic force microscopy (AFM) Bi2Se3 thin films constitutive model pop-in rate factor FIB nickel nanoindenter miniaturized cantilever beam hydrogen embrittlement nanoindentation irradiation hardening reduced activation ferritic martensitic (RAFM) steels tantalum