Ultralight and compressible carbon materials have promising applications in strain and pressure detection. However, it is still difficult to prepare carbon materials with supercompressibility, elasticity, stable strain-electrical signal response, and ultrasensitive detection limits, due to the challenge in structural regulation. Herein, a new strategy to prepare a reduced graphene oxide (rGO)-based lamellar carbon aerogels with unexpected and integrated performances by designing wave-shape rGO layers and enhancing the interaction among the rGO layers is demonstrated. Addition of cellulose nanocrystalline and low-molecular-weight carbon precursors enhances the interaction among rGO layers and thus produces an ultralight, flexible, and superstable structure. The as-prepared carbon aerogel displays a supercompressibility (undergoing an extreme strain of 99%) and elasticity (100% height retention after 10 000 cycles at a strain of 30%), as well as stable strain-current response (at least 10 000 cycles). Particularly, the carbon aerogel is ultrasensitive for detecting tiny change in strain (0.012%) and pressure (0.25 Pa), which are the lowest detection limits for compressible carbon materials reported in the literature. Moreover, the carbon aerogel exhibits excellent bendable performance and can detect an ultralow bending angle of 0.052°. Additionally, the carbon aerogel also demonstrates its promising application as wearable devices.
Compressible and
elastic carbon aerogels (CECAs) hold great promise
for applications in wearable electronics and electronic skins. MXenes,
as new two-dimensional materials with extraordinary properties, are
promising materials for piezoresistive sensors. However, the lack
of sufficient interaction among MXene nanosheets makes it difficult
to employ them to fabricate CECAs. Herein, a lightweight CECA is fabricated
by using bacterial cellulose fiber as a nanobinder to connect MXene
(Ti3C2) nanosheets into continuous and wave-shaped
lamellae. The lamellae are highly flexible and elastic, and the oriented
alignment of these lamellae results in a CECA with super compressibility
and elasticity. Its ultrahigh structural stability can withstand an
extremely high strain of 99% for more than 100 cycles and long-term
compression at 50% strain for at least 100 000 cycles. Furthermore,
it has a high sensitivity that demonstrates not only an ultrahigh
linearity but also a broad working pressure range (0–10 kPa).
In particular, the CECA has a high linear sensitivity in almost the
entire workable strain range (0–95%). In addition, it has very
low detection limits for tiny strain and pressure. These features
enable the CECA-based sensor to be a flexible wearable device to monitor
both subtle and large biosignals of the human body.
Among all the plastic pollution, straws have brought particularly intricate problems since they are single use, consumed in a large volume, cannot be recycled in most places, and can never be fully degraded. To solve this problem, replacements for plastic straws are being developed following with the global trend of plastic straw bans. Nevertheless, none of the available degradable alternatives are satisfactory due to drawbacks including poor natural degradability, high cost, low mechanical performance, and poor water stability. Here, all-natural degradable straws are designed by hybridizing cellulose nanofibers and microfibers in a binder-free manner. Straws are fabricated by rolling up the wet hybrid film and sealed by the internal hydrogen bonding formed among the cellulose fibers after drying. The cellulose hybrid straws show exceptional behaviors including 1) excellent mechanical performance (high tensile strength of ≈70 MPa and high ductility with a fracture strain of 12.7%), 2) sufficient hydrostability (10× wet mechanical strength compared to commercial paper straw), 3) low cost, and 4) high natural degradability. Given the low-cost raw materials, the binder-free hybrid design based on cellulose structure can potentially be a suitable solution to solve the environmental challenges brought by the enormous usage of plastics straws.
Hydrothermal
synthesis of carbon quantum dots (CQDs) from biomass
is a green and sustainable route for CQDs applications in various
fields. However, one of the major problems is the low CQDs yield because
the traditional hydrothermal treatment would produce large amounts
of hydrochar byproduct. In this work, we present a novel, facile,
and effective method for large-scale synthesis of CQDs from biomass-derived
carbon including hydrochar and carbonized biomass through mild oxidation
(NaOH/H2O2 solution). An ultrahigh CQDs yield
of 76.9 wt % can be obtained, which is much higher than those obtained
from traditional hydrothermal and strong acid oxidation processes.
Furthermore, the CQDs have excellent quantum yield (QY) that is higher
than (or comparable to) those from other methods. In addition, the
CQDs have uniform size (∼2.4 nm) and their surface states can
be regulated to significantly improve the QY by adjusting the concentration
of oxidants. The CQDs displayed excellent sensitivity for Pb2+ detection along with good linear correlation ranging from 1.3 to
106.7 μM. These advantages, together with low cost, sustainability,
and green process, make this approach have great potential in the
synthesis and applications of CQDs in large scale.
An ultralight, elastic, cost-effective, and highly recyclable superabsorbent was fabricated from microfibrillated cellulose fibers for oil spillage cleanup.
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