Combinatorial investigation of Al–Cu intermetallics using small-scale mechanical testing

Xiao, Yuan; Besharatloo, Hossein; Gan, Bin; Maeder, Xavier; Spolenak, Ralph; Wheeler, Jeffrey M.

doi:10.1016/j.jallcom.2019.153536

Cited by 32 publications

(23 citation statements)

References 56 publications

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“…The ferrite, α, phase corresponds to the lobe which protrudes (particularly at higher depth indentation map histograms) in the lower right, corresponding to its higher modulus and lower hardness. This lobe can be seen to be strongly tilted along its H/E ratio, which is in agreement with previous observations of anisotropic phases [12,24].…”

Section: D Histograms and Statistical Analysis Of Duplex Stainless Steel Indentation Mapssupporting

confidence: 92%

“…The mechanical properties of the theta (Al 2 Cu) and aluminum phase are show significantly different magnitudes, with the hardness values showing greater disparity compared with E curves. These results are consistent with those recently observed on an Al-Cu diffusion couple investigated by the same methods [24]. The hardness and elastic modulus values as a function of indentation depth show stable behavior during indentation for both phases.…”

Section: Conventional Nanoindentationsupporting

confidence: 92%

“…At first, we see a single elliptical distribution for the histogram at the finest spacing of 1 µm, which is elongated at a roughly constant hardness level of 4.5 GPa, that displays a significant tail towards the origin. This type of tail has been observed before in previous works [14,24] to correspond to the influence of roughness or porosity on the hardness results. However, in this work, the high-level vibropolishing that the DSS sample underwent suggests that roughness is likely not a factor here.…”

Section: D Histograms and Statistical Analysis Of Duplex Stainless Steel Indentation Mapssupporting

confidence: 78%

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Influence of indentation size and spacing on statistical phase analysis via high-speed nanoindentation mapping of metal alloys

Besharatloo

Wheeler

2021

Journal of Materials Research

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The development of high-speed nanoindentation has enabled the acquisition of mechanical property maps over square millimeters of area with micron-scale resolution in reasonable amounts of time. This provides rich datasets which contain morphological and statistical data on the variation of mechanical properties in a microstructure. However, the influences of the indentation size and the deconvolution method employed on the extracted phase properties remain unclear. In this work, a range of depth/spacing increments was explored on two different materials systems, an Al-Cu eutectic alloy and a duplex stainless steel, representing an ‘easy’ and a ‘hard’ case for statistical deconvolution, respectively. A total of ~ 500,000 indentations were performed. A variety of statistical analyses were then employed and compared: the 1D analysis of Ulm et al. using 2 and 3 phases, a 2D rotated Gaussian fit, K-means clustering, and a visual comparison to 2D histograms. This revealed several different sensitivities of the deconvolution methods to various types of error in phase identification. Graphic abstract

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Section: D Histograms and Statistical Analysis Of Duplex Stainless Steel Indentation Mapssupporting

confidence: 92%

Section: Conventional Nanoindentationsupporting

confidence: 92%

Section: D Histograms and Statistical Analysis Of Duplex Stainless Steel Indentation Mapssupporting

confidence: 78%

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Influence of indentation size and spacing on statistical phase analysis via high-speed nanoindentation mapping of metal alloys

Besharatloo

Wheeler

2021

Journal of Materials Research

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“…In situ нано-/микро-механическим исследованиям деформационного поведения кристаллических, аморфных и нанокомпозитных материалов посвящен ряд обзоров, опубликованных в последнее десятилетие [114,[117][118][119]. Особенно отметим обширный многоплановый обзор [23] и энциклопедию современных подходов, методов и результатов исследования физико-механических свойств твердых тел и материалов самых различных классов в мультимасштабной размерной шкале от нано-до макро- [19].…”

Section: In Situ исследования механических свойств и динамики структуunclassified

“…Для упрощения процедуры вырезания ионным пучком микробалочки из массива часто выполняют ее треугольной или пятиугольной в сечении [191,192]. Описанные методы и приемы опробованы и использовались на макрооднородных монокристаллических, аморфных, композитных материалах, высокоэнтропийных и интерметаллических сплавах [119,163,164], пленочных керамических покрытиях (как для определения их собственных свойств, так и энергии адгезии к подложке) [193][194][195]. В [196][197][198] этими методами определяли условия перехода от вязкого к хрупкому разрушению (в частности, температуру и размеры пластической зоны в вершине трещины), а в [199] -закономерности водородного охрупчивания.…”

Section: разрушение в микро- субмикрои наношкалеunclassified

Наноиндентирование И Механические Свойства Материалов В Субмикро- И Наношкале. Недавние Результаты И Достижения (О Б З О Р)

Головин¹

2021

Физика Твердого Тела

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The review discusses the details of various materials mechanical behavior in submicro- and nanoscale. Significant advances in this scope result from the development of wide family of load based precise nanotesting techniques called nanoindentation. But nowadays, nanomechanical properties are studied not only by nanoindentation techniques in narrow sense, i.e. local loading of macro, micro and nanoscale objects. Nanomechanical load testing is discussed here within a wider scope employing precise deformation measurement with nanometer scale resolution caused by various types of low load application to the object under study including uniaxial compression or extension, shearing, bending or twisting, optionally accompanied by in situ monitoring sample microstructure using scanning and transmission electron microscopy and Laue microdiffraction technique. The main courses of experimental techniques development in recent ten years along with the results obtained using them in single, poly and nano crystalline materials, composites, films and coatings, amorphous solids and such biomaterials as tissues, living cells and macromolecules are described. Special attention is paid to deformation size effects and atomic mechanisms in nanoscale. This review is a natural continuation and development of the review published at Fiz.Tverd.Tela vol.50, issue 12, 2008 of the same author that discusses details of nanomechanical properties of solids. Current review includes wider range of nanomechanical testing concepts and recent achievements in the scope. The work was supported by RFBR grant for project #19-12-50235.

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Combinatorial Investigation of the Ni–Ta System via Correlated High‐Speed Nanoindentation and EDX Mapping

2021

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Combinatorial investigation of Al–Cu intermetallics using small-scale mechanical testing

Cited by 32 publications

References 56 publications

Influence of indentation size and spacing on statistical phase analysis via high-speed nanoindentation mapping of metal alloys

Influence of indentation size and spacing on statistical phase analysis via high-speed nanoindentation mapping of metal alloys

Наноиндентирование И Механические Свойства Материалов В Субмикро- И Наношкале. Недавние Результаты И Достижения (О Б З О Р)

Combinatorial Investigation of the Ni–Ta System via Correlated High‐Speed Nanoindentation and EDX Mapping

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