Microlattices as architected thin films: Analysis of mechanical properties and high strain elastic recovery

Microlattices as architected thin films: Analysis of mechanical properties and high strain elastic recovery

Ordered periodic microlattices with densities from 0.5 mg/cm3 to 500 mg/cm3 are fabricated by depositing various thin film materials (Au, Cu, Ni, SiO2, poly(C8H4F4)) onto sacrificial polymer lattice templates. Young's modulus and strength are measured in compression and the density scaling is d...

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Main Authors: Kevin J. Maloney, Christopher S. Roper, Alan J. Jacobsen, William B. Carter, Lorenzo Valdevit, Tobias A. Schaedler
Format: Article
Language:English
Published: AIP Publishing LLC 2013-08-01
Series:APL Materials
Online Access:http://link.aip.org/link/doi/10.1063/1.4818168
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spelling doaj-a0821154674741c4a74f34076b105e6d2020-11-25T01:17:17ZengAIP Publishing LLCAPL Materials2166-532X2013-08-011202210602210610.1063/1.4818168Microlattices as architected thin films: Analysis of mechanical properties and high strain elastic recoveryKevin J. MaloneyChristopher S. RoperAlan J. JacobsenWilliam B. CarterLorenzo ValdevitTobias A. SchaedlerOrdered periodic microlattices with densities from 0.5 mg/cm3 to 500 mg/cm3 are fabricated by depositing various thin film materials (Au, Cu, Ni, SiO2, poly(C8H4F4)) onto sacrificial polymer lattice templates. Young's modulus and strength are measured in compression and the density scaling is determined. At low relative densities, recovery from compressive strains of 50% and higher is observed, independent of lattice material. An analytical model is shown to accurately predict the transition between recoverable “pseudo-superelastic” and irrecoverable plastic deformation for all constituent materials. These materials are of interest for energy storage applications, deployable structures, and for acoustic, shock, and vibration damping.http://link.aip.org/link/doi/10.1063/1.4818168
collection DOAJ
language English
format Article
sources DOAJ
author Kevin J. Maloney
Christopher S. Roper
Alan J. Jacobsen
William B. Carter
Lorenzo Valdevit
Tobias A. Schaedler
spellingShingle Kevin J. Maloney
Christopher S. Roper
Alan J. Jacobsen
William B. Carter
Lorenzo Valdevit
Tobias A. Schaedler
Microlattices as architected thin films: Analysis of mechanical properties and high strain elastic recovery
APL Materials
author_facet Kevin J. Maloney
Christopher S. Roper
Alan J. Jacobsen
William B. Carter
Lorenzo Valdevit
Tobias A. Schaedler
author_sort Kevin J. Maloney
title Microlattices as architected thin films: Analysis of mechanical properties and high strain elastic recovery
title_short Microlattices as architected thin films: Analysis of mechanical properties and high strain elastic recovery
title_full Microlattices as architected thin films: Analysis of mechanical properties and high strain elastic recovery
title_fullStr Microlattices as architected thin films: Analysis of mechanical properties and high strain elastic recovery
title_full_unstemmed Microlattices as architected thin films: Analysis of mechanical properties and high strain elastic recovery
title_sort microlattices as architected thin films: analysis of mechanical properties and high strain elastic recovery
publisher AIP Publishing LLC
series APL Materials
issn 2166-532X
publishDate 2013-08-01
description Ordered periodic microlattices with densities from 0.5 mg/cm3 to 500 mg/cm3 are fabricated by depositing various thin film materials (Au, Cu, Ni, SiO2, poly(C8H4F4)) onto sacrificial polymer lattice templates. Young's modulus and strength are measured in compression and the density scaling is determined. At low relative densities, recovery from compressive strains of 50% and higher is observed, independent of lattice material. An analytical model is shown to accurately predict the transition between recoverable “pseudo-superelastic” and irrecoverable plastic deformation for all constituent materials. These materials are of interest for energy storage applications, deployable structures, and for acoustic, shock, and vibration damping.
url http://link.aip.org/link/doi/10.1063/1.4818168
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