Ultra-low-density digitally architected carbon with a strutted tube-in-tube structure

Jianchao Ye; Ling Liu; James Oakdale; Joseph Lefebvre; Sanjit Bhowmick; Thomas Voisin; John D Roehling; William L Smith; Maira R Cerón; Jip van Ham; Leonardus Bimo Bayu Aji; Monika M Biener; Y Morris Wang; Juergen Biener; Patrick R Onck

doi:10.1038/s41563-021-01125-w

Ultra-low-density digitally architected carbon with a strutted tube-in-tube structure

Jianchao Ye^*
, Ling Liu
, James Oakdale
, Joseph Lefebvre
, Sanjit Bhowmick
, Thomas Voisin
, John D Roehling
, William L Smith
, Maira R Cerón
, Jip van Ham
, Leonardus Bimo Bayu Aji
, Monika M Biener
, Y Morris Wang
, Juergen Biener^*
, Patrick R Onck^*

^*Corresponding author for this work

Micromechanics

Research output: Contribution to journal › Article › Academic › peer-review

39 Citations (Scopus)

228 Downloads (Pure)

Abstract

Porous materials with engineered stretching-dominated lattice designs, which offer attractive mechanical properties with ultra-light weight and large surface area for wide-ranging applications, have recently achieved near-ideal linear scaling between stiffness and density. Here, rather than optimizing the microlattice topology, we explore a different approach to strengthen low-density structural materials by designing tube-in-tube beam structures. We develop a process to transform fully dense, three-dimensional printed polymeric beams into graphitic carbon hollow tube-in-tube sandwich morphologies, where, similar to grass stems, the inner and outer tubes are connected through a network of struts. Compression tests and computational modelling show that this change in beam morphology dramatically slows down the decrease in stiffness with decreasing density. In situ pillar compression experiments further demonstrate large deformation recovery after 30-50% compression and high specific damping merit index. Our strutted tube-in-tube design opens up the space and realizes highly desirable high modulus-low density and high modulus-high damping material structures.

Original language	English
Pages (from-to)	1498-1505
Number of pages	8
Journal	Nature Materials
Volume	20
Issue number	11
DOIs	https://doi.org/10.1038/s41563-021-01125-w
Publication status	Published - Nov-2021

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Ye, J., Liu, L., Oakdale, J., Lefebvre, J., Bhowmick, S., Voisin, T., Roehling, J. D., Smith, W. L., Cerón, M. R., van Ham, J., Bayu Aji, L. B., Biener, M. M., Wang, Y. M., Biener, J., & Onck, P. R. (2021). Ultra-low-density digitally architected carbon with a strutted tube-in-tube structure. Nature Materials, 20(11), 1498-1505. https://doi.org/10.1038/s41563-021-01125-w

@article{8f0599f471a74e8a851b2c64c8ac9b2a,

title = "Ultra-low-density digitally architected carbon with a strutted tube-in-tube structure",

abstract = "Porous materials with engineered stretching-dominated lattice designs, which offer attractive mechanical properties with ultra-light weight and large surface area for wide-ranging applications, have recently achieved near-ideal linear scaling between stiffness and density. Here, rather than optimizing the microlattice topology, we explore a different approach to strengthen low-density structural materials by designing tube-in-tube beam structures. We develop a process to transform fully dense, three-dimensional printed polymeric beams into graphitic carbon hollow tube-in-tube sandwich morphologies, where, similar to grass stems, the inner and outer tubes are connected through a network of struts. Compression tests and computational modelling show that this change in beam morphology dramatically slows down the decrease in stiffness with decreasing density. In situ pillar compression experiments further demonstrate large deformation recovery after 30-50\% compression and high specific damping merit index. Our strutted tube-in-tube design opens up the space and realizes highly desirable high modulus-low density and high modulus-high damping material structures.",

author = "Jianchao Ye and Ling Liu and James Oakdale and Joseph Lefebvre and Sanjit Bhowmick and Thomas Voisin and Roehling, \{John D\} and Smith, \{William L\} and Cer{\'o}n, \{Maira R\} and \{van Ham\}, Jip and \{Bayu Aji\}, \{Leonardus Bimo\} and Biener, \{Monika M\} and Wang, \{Y Morris\} and Juergen Biener and Onck, \{Patrick R\}",

note = "{\textcopyright} 2021. This is a U.S. government work and not under copyright protection in the U.S.; foreign copyright protection may apply.",

year = "2021",

month = nov,

doi = "10.1038/s41563-021-01125-w",

language = "English",

volume = "20",

pages = "1498--1505",

journal = "Nature Materials",

issn = "1476-1122",

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number = "11",

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T1 - Ultra-low-density digitally architected carbon with a strutted tube-in-tube structure

AU - Ye, Jianchao

AU - Liu, Ling

AU - Oakdale, James

AU - Lefebvre, Joseph

AU - Bhowmick, Sanjit

AU - Voisin, Thomas

AU - Roehling, John D

AU - Smith, William L

AU - Cerón, Maira R

AU - van Ham, Jip

AU - Bayu Aji, Leonardus Bimo

AU - Biener, Monika M

AU - Wang, Y Morris

AU - Biener, Juergen

AU - Onck, Patrick R

PY - 2021/11

Y1 - 2021/11

N2 - Porous materials with engineered stretching-dominated lattice designs, which offer attractive mechanical properties with ultra-light weight and large surface area for wide-ranging applications, have recently achieved near-ideal linear scaling between stiffness and density. Here, rather than optimizing the microlattice topology, we explore a different approach to strengthen low-density structural materials by designing tube-in-tube beam structures. We develop a process to transform fully dense, three-dimensional printed polymeric beams into graphitic carbon hollow tube-in-tube sandwich morphologies, where, similar to grass stems, the inner and outer tubes are connected through a network of struts. Compression tests and computational modelling show that this change in beam morphology dramatically slows down the decrease in stiffness with decreasing density. In situ pillar compression experiments further demonstrate large deformation recovery after 30-50% compression and high specific damping merit index. Our strutted tube-in-tube design opens up the space and realizes highly desirable high modulus-low density and high modulus-high damping material structures.

AB - Porous materials with engineered stretching-dominated lattice designs, which offer attractive mechanical properties with ultra-light weight and large surface area for wide-ranging applications, have recently achieved near-ideal linear scaling between stiffness and density. Here, rather than optimizing the microlattice topology, we explore a different approach to strengthen low-density structural materials by designing tube-in-tube beam structures. We develop a process to transform fully dense, three-dimensional printed polymeric beams into graphitic carbon hollow tube-in-tube sandwich morphologies, where, similar to grass stems, the inner and outer tubes are connected through a network of struts. Compression tests and computational modelling show that this change in beam morphology dramatically slows down the decrease in stiffness with decreasing density. In situ pillar compression experiments further demonstrate large deformation recovery after 30-50% compression and high specific damping merit index. Our strutted tube-in-tube design opens up the space and realizes highly desirable high modulus-low density and high modulus-high damping material structures.

U2 - 10.1038/s41563-021-01125-w

DO - 10.1038/s41563-021-01125-w

M3 - Article

C2 - 34697430

SN - 1476-1122

VL - 20

SP - 1498

EP - 1505

JO - Nature Materials

JF - Nature Materials

IS - 11

ER -

Ultra-low-density digitally architected carbon with a strutted tube-in-tube structure

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