Ruth Schwaiger scite author profile

The strength of lightweight mechanical metamaterials, which aim to exploit material-strengthening size effects by their microscale lattice structure, has been limited by the resolution of three-dimensional lithography technologies and their restriction to mainly polymer resins. Here, we demonstrate that pyrolysis of polymeric microlattices can overcome these limitations and create ultra-strong glassy carbon nanolattices with single struts shorter than 1 μm and diameters as small as 200 nm. They represent the smallest lattice structures yet produced--achieved by an 80% shrinkage of the polymer during pyrolysis--and exhibit material strengths of up to 3 GPa, corresponding approximately to the theoretical strength of glassy carbon. The strength-to-density ratios of the nanolattices are six times higher than those of reported microlattices. With a honeycomb topology, effective strengths of 1.2 GPa at 0.6 g cm(-3) are achieved. Diamond is the only bulk material with a notably higher strength-to-density ratio.

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High-strength cellular ceramic composites with 3D microarchitecture

Bauer

Hengsbach

Tesari

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

476

340

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Significance It has been a long-standing effort to create materials with low density but high strength. Technical foams are very light, but compared with bulk materials, their strength is quite low because of their random structure. Natural lightweight materials, such as bone, are cellular solids with optimized architecture. They are structured hierarchically and actually consist of nanometer-size building blocks, providing a benefit from mechanical size effects. In this paper, we demonstrate that materials with a designed microarchitecture, which provides both structural advantages and size-dependent strengthening effects, may be fabricated. Using 3D laser lithography, we produced micro-truss and -shell structures from ceramic–polymer composites that exceed the strength-to-weight ratio of all engineering materials, with a density below 1,000 kg/m 3 .

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Nano-sized twins induce high rate sensitivity of flow stress in pure copper

et al. 2005

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Some critical experiments on the strain-rate sensitivity of nanocrystalline nickel

et al. 2003

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Ruth Schwaiger

Approaching theoretical strength in glassy carbon nanolattices

High-strength cellular ceramic composites with 3D microarchitecture

Nano-sized twins induce high rate sensitivity of flow stress in pure copper

Some critical experiments on the strain-rate sensitivity of nanocrystalline nickel

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