PSS conducting-polymer-silksericin composite is presented using a water-based, benchtop photolithographic process. Conducting microstructures formed on a flexible silk fibroin sheet allow a fully organic, flexible bioelectronic device. Large-area microfabricated devices such as biosensors that are biocompatible and degradable over a controlled period of time can be formed.
The synthesis of
size and shape controlled Au/Ag/Pd alloy nanoparticles
(NPs) and their self-supported assembly into monolithic aerogels for
electro-oxidation of ethanol is reported. Two distinct morphologies
of ultrasmall (3–5 nm) Au/Ag/Pd alloy NPs were produced via
stepwise galvanic replacement of thiol-coated Ag NPs. The resultant
nanoalloys were self-assembled into large, free-standing, aerogel
superstructures that exhibit direct NP connectivity, high surface
area (269 ± 18.1–76 ± 6.4 m2/g) and mesoporosity
(2–50 nm), and high electrocatalytic activity via controlled
oxidation of the surfactant ligands. The gelation kinetics have been
tuned by varying the oxidant/surfactant molar ratio that governs the
acidity of sol–gel reaction and consequently the extent of
Ag dealloying with in situ generated HNO3. As-synthesized
Au/Ag/Pd aerogels exhibit polymeric or colloidal gel morphology that
can be manipulated by varying the shape and composition of precursor
NPs. The electrocatalytic activity of ternary alloy aerogels for oxidation
of ethanol was investigated using cyclic voltammetry and chronoamperometry.
The monolithic aerogels exhibit high catalytic activity and durability,
which is ∼20–30 times greater than those of the discrete
Au/Ag/Pd alloy NPs. The polymeric morphology of high Pd-containing
alloy aerogels resulted in ∼1 order of magnitude higher current
density and mass activity in comparison to low Pd-containing colloidal
aerogels. The synergistic effect of trimetallic alloy mitigates the
catalyst poisoning effects and increases the stability and durability
while the self-supported superstructure with direct NP connectivity,
high surface area, and mesoporosity offers a facile conduit for both
molecular and electron transport, enabling Au/Ag/Pd aerogel as a high-efficiency
electrocatalyst.
Summary
The present study reports the economic and sustainable syntheses of functional porous carbons for supercapacitor and CO2 capture applications. Lignin, a byproduct of pulp and paper industry, was successfully converted into a series of heteroatom‐doped porous carbons (LHPCs) through a hydrothermal carbonization followed by a chemical activating treatment. The prepared carbons include in the range of 2.5 to 5.6 wt% nitrogen and 54 wt% oxygen in its structure. All the prepared carbons exhibit micro‐ and mesoporous structures with a high surface area in the range of 1788 to 2957 m2 g−1. As‐prepared LHPCs as an active electrode material and CO2 adsorbents were investigated for supercapacitor and CO2 capture applications. Lignin‐derived heteroatom‐doped porous carbon 850 shows an outstanding gravimetric specific capacitance of 372 F g−1 and excellent cyclic stability over 30,000 cycles in 1 M KOH. Lignin‐derived heteroatom‐doped porous carbon 700 displays a remarkable CO2 capture capacity of up to 4.8 mmol g−1 (1 bar and 298 K). This study illustrates the effective transformation of a sustainable waste product into a highly functional carbon material for energy storage and CO2 separation applications.
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