| 000 | 03765naaaa2200829uu 4500 | ||
|---|---|---|---|
| 001 | https://directory.doabooks.org/handle/20.500.12854/59470 | ||
| 005 | 20220220075749.0 | ||
| 020 | _abooks978-3-03897-967-8 | ||
| 020 | _a9783038979661 | ||
| 020 | _a9783038979678 | ||
| 024 | 7 |
_a10.3390/books978-3-03897-967-8 _cdoi |
|
| 041 | 0 | _aEnglish | |
| 042 | _adc | ||
| 100 | 1 |
_aTsui, Ting _4auth |
|
| 700 | 1 |
_aVolinsky, Alex A. _4auth |
|
| 245 | 1 | 0 | _aSmall Scale Deformation using Advanced Nanoindentation Techniques |
| 260 |
_bMDPI - Multidisciplinary Digital Publishing Institute _c2019 |
||
| 300 | _a1 electronic resource (168 p.) | ||
| 506 | 0 |
_aOpen Access _2star _fUnrestricted online access |
|
| 520 | _aSmall 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: | ||
| 540 |
_aCreative Commons _fhttps://creativecommons.org/licenses/by-nc-nd/4.0/ _2cc _4https://creativecommons.org/licenses/by-nc-nd/4.0/ |
||
| 546 | _aEnglish | ||
| 653 | _an/a | ||
| 653 | _ananoscale | ||
| 653 | _afracture toughness | ||
| 653 | _ahelium irradiation | ||
| 653 | _acement paste | ||
| 653 | _asolder | ||
| 653 | _afracture | ||
| 653 | _aPop-in | ||
| 653 | _afatigue | ||
| 653 | _astrain rate sensitivity | ||
| 653 | _aviscoelasticity | ||
| 653 | _anuclear fusion structural materials | ||
| 653 | _abiomaterials | ||
| 653 | _atransmission electron microscopy | ||
| 653 | _amammalian cells | ||
| 653 | _aquasicontinuum method | ||
| 653 | _abrittleness and ductility | ||
| 653 | _amorphology | ||
| 653 | _acreep | ||
| 653 | _adimensionless analysis | ||
| 653 | _asize effect | ||
| 653 | _amechanical properties | ||
| 653 | _ahardness | ||
| 653 | _ashear transformation zone | ||
| 653 | _aTSV | ||
| 653 | _amicro-cantilever beam | ||
| 653 | _amultiscale | ||
| 653 | _aInP(100) single crystal | ||
| 653 | _asurface pit defect | ||
| 653 | _amixed-mode | ||
| 653 | _amicromechanics | ||
| 653 | _asoft biomaterials | ||
| 653 | _ametallic glass | ||
| 653 | _aatomic force microscopy (AFM) | ||
| 653 | _aBi2Se3 thin films | ||
| 653 | _aconstitutive model | ||
| 653 | _apop-in | ||
| 653 | _arate factor | ||
| 653 | _aFIB | ||
| 653 | _anickel | ||
| 653 | _ananoindenter | ||
| 653 | _aminiaturized cantilever beam | ||
| 653 | _ahydrogen embrittlement | ||
| 653 | _ananoindentation | ||
| 653 | _airradiation hardening | ||
| 653 | _areduced activation ferritic martensitic (RAFM) steels | ||
| 653 | _atantalum | ||
| 856 | 4 | 0 |
_awww.oapen.org _uhttps://mdpi.com/books/pdfview/book/1333 _70 _zDOAB: download the publication |
| 856 | 4 | 0 |
_awww.oapen.org _uhttps://directory.doabooks.org/handle/20.500.12854/59470 _70 _zDOAB: description of the publication |
| 999 |
_c74592 _d74592 |
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