Drastically Enhancing Moduli of Graphene-Coated Carbon
Nanotube Aerogels via Densification while Retaining Temperature-Invariant
Superelasticity and Ultrahigh Efficiency
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journal contribution
posted on 2017-10-09, 00:00authored byMichelle
N. Tsui, Kyu Hun Kim, Mohammad F. Islam
Lightweight
open-cell foams that are simultaneously superelastic, possess exceptionally
high Young’s moduli (Y), exhibit ultrahigh
efficiency, and resist fatigue as well as creep are particularly desirable
as structural frameworks. Unfortunately, many of these features are
orthogonal in foams of metals, ceramics, and polymers, particularly
under large temperature variations. In contrast, foams of carbon allotropes
including carbon nanotubes and graphene developed over the past few
years exhibit these desired properties but have low Y due to low density, ρ = 0.5–10 mg/mL. Densification
of these foams enhances Y although below expectation
and also dramatically degrades other properties because of drastic
changes in microstructure. We have recently developed size- and shape-tunable
graphene-coated single-walled carbon nanotube (SWCNT) aerogels that
display superelasticity at least up to a compressive strain (ε)
= 80%, fatigue and creep resistance, and ultrahigh efficiency over
−100–500 °C. Unfortunately, Y of
these aerogels is only ∼0.75 MPa due to low ρ ≈
14 mg/mL, limiting their competitiveness as structural foams. We report
fabrication of similar aerogels but with ρ spanning more than
an order of magnitude from 16–400 mg/mL through controlled
isostatic compression in the presence of a polymer coating circumventing
any microstructural changes in stark contrast to other foams of carbon
allotropes. The compressive stress (σ) versus ε measurements
show that the densification of aerogels from ρ ≈ 16 to
400 mg/mL dramatically enhances Y from 0.9 to 400
MPa while maintaining superelasticity at least up to ε = 10%
even at the highest ρ. The storage (E′) and loss (E″) moduli measured in the linear
regime show ultralow loss coefficient, tan δ = E″/E′ ≈ 0.02, that remains constant
over three decades of frequencies (0.628–628 rad/s), suggesting
unusually high frequency-invariant efficiency. Furthermore, these
aerogels retain exceptional fatigue resistance for 106 loading–unloading
cycles to ε = 2% and creep resistance for at least 30 min under
σ = 0.02 MPa with ρ = 16 mg/mL and σ = 2.5 MPa with
higher ρ = 400 mg/mL. Lastly, these robust mechanical properties
are stable over a broad temperature range of −100–500
°C, motivating their use as highly efficient structural components
in environments with extreme temperature variations.