Fabrication and deformation of aluminum–manganese microsandwich structure

The combination of low areal density, high flexural rigidity, and open architecture makes metallic microsandwiching a promising candidate for structural frameworks in small-scale multifunctional devices. We demonstrate a one-step electrodeposition procedure to synthesize an aluminum–manganese (Al–Mn...

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Veröffentlicht in:	Journal of materials research 2016-02, Vol.31 (4), p.480-487
Hauptverfasser:	Mraied, Hesham, Tran, Thanh Hai, Cai, Wenjun
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Sprache:	eng
Schlagworte:	Aluminum Aluminum manganese alloys Analysis Applied and Technical Physics Biomaterials Chemical synthesis Density Devices Electrodes Electrolytes Inorganic Chemistry Ion beams Manganese Materials Engineering Materials research Materials Science Metals Microscopy Nanostructure Nanotechnology Open architectures Phase transitions Plasma etching Polycarbonate resins Polycarbonates Scanning electron microscopy Studies
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container_end_page	487
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container_title	Journal of materials research
container_volume	31
creator	Mraied, Hesham Tran, Thanh Hai Cai, Wenjun
description	The combination of low areal density, high flexural rigidity, and open architecture makes metallic microsandwiching a promising candidate for structural frameworks in small-scale multifunctional devices. We demonstrate a one-step electrodeposition procedure to synthesize an aluminum–manganese (Al–Mn) microsandwich using a porous polycarbonate (PC) membrane template from room-temperature ionic liquid. Mn was added to refine the microstructure and increase the hardness of Al. A cyclic voltammogram study shows Mn codeposit with Al in an acidic chloroaluminate electrolyte. Increasing the MnCl2 concentration in the electrolyte from 0.05 to 0.25 M promoted a crystalline to amorphous phase transition of the deposited structures. Finally, mechanical properties and damage resistance of the microsandwiches were evaluated using nano- and micro-indentation tests as well as finite element methods.
doi_str_mv	10.1557/jmr.2016.28
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Mater. Res</addtitle><description>The combination of low areal density, high flexural rigidity, and open architecture makes metallic microsandwiching a promising candidate for structural frameworks in small-scale multifunctional devices. We demonstrate a one-step electrodeposition procedure to synthesize an aluminum–manganese (Al–Mn) microsandwich using a porous polycarbonate (PC) membrane template from room-temperature ionic liquid. Mn was added to refine the microstructure and increase the hardness of Al. A cyclic voltammogram study shows Mn codeposit with Al in an acidic chloroaluminate electrolyte. Increasing the MnCl2 concentration in the electrolyte from 0.05 to 0.25 M promoted a crystalline to amorphous phase transition of the deposited structures. 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subjects	Aluminum Aluminum manganese alloys Analysis Applied and Technical Physics Biomaterials Chemical synthesis Density Devices Electrodes Electrolytes Inorganic Chemistry Ion beams Manganese Materials Engineering Materials research Materials Science Metals Microscopy Nanostructure Nanotechnology Open architectures Phase transitions Plasma etching Polycarbonate resins Polycarbonates Scanning electron microscopy Studies
title	Fabrication and deformation of aluminum–manganese microsandwich structure
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