Solid State Processing of Aluminum Matrix Composites Reinforced with Nanoparticulate Materials

Leparoux, Marc; Kollo, Lauri; Kwon, Hansang; Kallip, Kaspar; Babu, N. Kishore; AlOgab, Khaled A.; Talari, Mahesh Kumar

doi:10.1002/adem.201800401

Cited by 11 publications

(10 citation statements)

References 90 publications

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“…The issues associated with liquid‐phase process such as agglomeration, nonuniform microstructure, and interfacial reaction at higher melt temperatures lead to detrimental effect on the properties of composites. This stimulated the researchers to seek alternate methods of processing MMCs . The other common way of blending the composites is solid‐state processing including PM‐based techniques.…”

Section: Processing Methodsmentioning

confidence: 99%

“…This stimulated the researchers to seek alternate methods of processing MMCs. [52] The other common way of blending the composites is solid-state processing Figure 4. a) A TEM image of ball-milled CNTs used in a pressureless infiltration process, [45] b) HRTEM image showing Al 4 C 3 in Al matrix near the CNT/matrix interface in a friction stir processed 3 wt% CNT/AA2009, [46] c) silicon carbide layer on CNT surface in HVOF formed MWCNT/Al-Si composite, [47] d) TEM image showing the deformation of a CNT during cold spraying, [48] e) SEM image of CNT/Al composite powders with several typical CNTs (indicated by arrows) dispersed in Al powders by CVD, [49] f ) HRTEM image showing poor graphitization having reacted with Al at 650 C, [50] and g) the agglomerated CNTs and pores on the fracture surface of 1.8 vol% CNT/alumina nanocomposite.…”

Section: Solid-phase Processingmentioning

confidence: 99%

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Carbon Nanotube‐Reinforced Aluminum Matrix Composites

Mohammed

Chen

2019

Adv Eng Mater

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Herein, the investigations conducted in the area of aluminum (Al) matrix composites reinforced with carbon nanotubes (CNTs) are presented. The application of CNT reinforcement in Al alloys is driven by its exceptional chemical and mechanical properties. The critical issues in the processing techniques, challenges in the interfacial mechanisms between the Al matrix and CNTs, and strengthening effects due to the presence of reinforcements are reviewed. The mechanical properties of CNT/Al composites are found to be effectively enhanced with an addition of CNTs even at a small amount. The extent of strength improvements depends mainly on the dispersion of CNTs in the matrix and interfacial bonding between the matrix and CNTs. Limited theoretical modeling can predict the properties of CNT/Al composites to some extent, but without considering the detailed processing parameters. Based on the gaps identified here, future research directions are suggested, including the relationships between the processing parameters and micro-and nanostructures, and multiscale mechanical modeling and simulation, aiming to further understand the strengthening mechanisms and develop advanced CNT-reinforced Al and other metal composites for critical engineering applications.

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Section: Processing Methodsmentioning

confidence: 99%

Section: Solid-phase Processingmentioning

confidence: 99%

Carbon Nanotube‐Reinforced Aluminum Matrix Composites

Mohammed

Chen

2019

Adv Eng Mater

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“…Based on a two‐tailed Student's t‐Test, the differences between the FG and CG regions are significant (95% confidence) for both <xy> and <xz>/<yz> planes for the as‐processed condition, and the <xy> plane of the annealed condition. For the as‐processed condition, as no intragranular Al 3 (Sc x ,Zr 1‐ x ) particle precipitation takes place within the utilized processing window, the hardness is affected by precipitation‐based strengthening from pre‐existing oxides, the local dislocation density, and grain boundary (GB) effects . As the nano‐indents have an indent side length which is larger than the typical FG dimension, a measurement within the FG region will deform several GBs.…”

Section: Resultsmentioning

confidence: 99%

Mechanical Anisotropy Investigated in the Complex SLM‐Processed Sc‐ and Zr‐Modified Al–Mg Alloy Microstructure

et al. 2018

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Additive manufactured Sc-modified aluminum alloys hold great promise for aerospace components under high and/or complex loads. While the thermal patterns formed in the melt pool during selective laser melting (SLM) of the powdered material result in a complex microstructure featuring a bimodal grain size distribution, such alloys show an isotropic mechanical response during mm-scale testing. To understand the role of microstructure on the mechanical response, nanoindentation is performed on SLM-processed Scalmalloy 1 for both the untreated and precipitate-hardened alloy, studied both parallel and orthogonal to the build direction. The elastic modulus of the coarse and fine grained regions is significantly greater than the macro-scale modulus of the material, suggesting macroscopic control over the elastic performance. With negligible influence over the elastic properties, there is a significant correlation between the grain size distribution and the nanoindentation hardness. This weak but significant grain boundary strengthening is lost when applying load orthogonal to the build direction for the precipitate-hardened material. Hardness anisotropy is moreover observed in fine-grained regions for the as-processed sample. In contrast to the isotropy reported from larger-scale mechanical tests, the discrete microstructural zones deviate from ideal isotropic behavior, and this may have consequences for simulation and design of this alloy.

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“…The possible reason why the quality of obtained preforms after single-load scheme of compaction cannot be sufficient at a pressure above 800 MPa can be specific zones of resistances-micron-sized cavities or macro-pores [44][45][46][47]. They can be interpreted as arch construction composed from particles that can withstand high stresses, when the load increases, the arch (of a pore) formed by adhesion and chemical bonds of atoms of particles' surface only becomes denser and stronger, this inhibits further preform compaction [20,31,32,34,48,49].…”

Section: Developed Methods Of Complex Loadmentioning

confidence: 99%

A Cold-Pressing Method Combining Axial and Shear Flow of Powder Compaction to Produce High-Density Iron Parts

et al. 2019

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Highly performance methods for cold pressing (cold die forging) of preforms from iron powder with subsequent heat treatment and producing ready parts made of powder are described in the paper. These methods allow fabricating parts with smooth surfaces and improved mechanical characteristics—porosity, tensile strength. Application of the traditional design set-up with a single-axial loading is restricted to high stresses in the dies to deform the preforms that lead to cracks formation. New powder compaction schemes by applying active friction forces (shear-enhanced compaction) make it possible to unload dies and produce high-quality parts by cold pressing. The scheme allows moving the die in the direction of the material flow with a velocity that exceeds the material flow velocity.

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Solid State Processing of Aluminum Matrix Composites Reinforced with Nanoparticulate Materials

Cited by 11 publications

References 90 publications

Carbon Nanotube‐Reinforced Aluminum Matrix Composites

Carbon Nanotube‐Reinforced Aluminum Matrix Composites

Mechanical Anisotropy Investigated in the Complex SLM‐Processed Sc‐ and Zr‐Modified Al–Mg Alloy Microstructure

A Cold-Pressing Method Combining Axial and Shear Flow of Powder Compaction to Produce High-Density Iron Parts

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