5 research outputs found
Flexible Bifunctional Electrode for Alkaline Water Splitting with Long-Term Stability
Progress in electrochemical
water-splitting devices as
future renewable
and clean energy systems requires the development of electrodes composed
of efficient and earth-abundant bifunctional electrocatalysts. This
study reveals a novel flexible and bifunctional electrode (NiO@CNTR) by hybridizing macroscopically assembled
carbon nanotube ribbons (CNTRs) and
atmospheric plasma-synthesized NiO quantum dots (QDs) with varied
loadings to demonstrate bifunctional electrocatalytic activity for
stable and efficient overall water-splitting (OWS) applications. Comparative
studies on the effect of different electrolytes, e.g., acid and alkaline,
reveal a strong preference for alkaline electrolytes for the developed NiO@CNTR electrode, suggesting its bifunctionality
for both HER and OER activities. Our proposed NiO@CNTR electrode demonstrates significantly enhanced overall catalytic
performance in a two-electrode alkaline electrolyzer cell configuration
by assembling the same electrode materials as both the anode and the
cathode, with a remarkable long-standing stability retaining ∼100%
of the initial current after a 100 h long OWS run, which is attributed
to the “synergistic coupling” between NiO QD catalysts
and the CNTR matrix. Interestingly, the developed electrode exhibits
a cell potential (E10) of only 1.81 V
with significantly low NiO QD loading (83 μg/cm2)
compared to other catalyst loading values reported in the literature.
This study demonstrates a potential class of carbon-based electrodes
with single-metal-based bifunctional catalysts that opens up a cost-effective
and large-scale pathway for further development of catalysts and their
loading engineering suitable for alkaline-based OWS applications and
green hydrogen generation
Flexible Bifunctional Electrode for Alkaline Water Splitting with Long-Term Stability
Progress in electrochemical
water-splitting devices as
future renewable
and clean energy systems requires the development of electrodes composed
of efficient and earth-abundant bifunctional electrocatalysts. This
study reveals a novel flexible and bifunctional electrode (NiO@CNTR) by hybridizing macroscopically assembled
carbon nanotube ribbons (CNTRs) and
atmospheric plasma-synthesized NiO quantum dots (QDs) with varied
loadings to demonstrate bifunctional electrocatalytic activity for
stable and efficient overall water-splitting (OWS) applications. Comparative
studies on the effect of different electrolytes, e.g., acid and alkaline,
reveal a strong preference for alkaline electrolytes for the developed NiO@CNTR electrode, suggesting its bifunctionality
for both HER and OER activities. Our proposed NiO@CNTR electrode demonstrates significantly enhanced overall catalytic
performance in a two-electrode alkaline electrolyzer cell configuration
by assembling the same electrode materials as both the anode and the
cathode, with a remarkable long-standing stability retaining ∼100%
of the initial current after a 100 h long OWS run, which is attributed
to the “synergistic coupling” between NiO QD catalysts
and the CNTR matrix. Interestingly, the developed electrode exhibits
a cell potential (E10) of only 1.81 V
with significantly low NiO QD loading (83 μg/cm2)
compared to other catalyst loading values reported in the literature.
This study demonstrates a potential class of carbon-based electrodes
with single-metal-based bifunctional catalysts that opens up a cost-effective
and large-scale pathway for further development of catalysts and their
loading engineering suitable for alkaline-based OWS applications and
green hydrogen generation
Flexible Bifunctional Electrode for Alkaline Water Splitting with Long-Term Stability
Progress in electrochemical
water-splitting devices as
future renewable
and clean energy systems requires the development of electrodes composed
of efficient and earth-abundant bifunctional electrocatalysts. This
study reveals a novel flexible and bifunctional electrode (NiO@CNTR) by hybridizing macroscopically assembled
carbon nanotube ribbons (CNTRs) and
atmospheric plasma-synthesized NiO quantum dots (QDs) with varied
loadings to demonstrate bifunctional electrocatalytic activity for
stable and efficient overall water-splitting (OWS) applications. Comparative
studies on the effect of different electrolytes, e.g., acid and alkaline,
reveal a strong preference for alkaline electrolytes for the developed NiO@CNTR electrode, suggesting its bifunctionality
for both HER and OER activities. Our proposed NiO@CNTR electrode demonstrates significantly enhanced overall catalytic
performance in a two-electrode alkaline electrolyzer cell configuration
by assembling the same electrode materials as both the anode and the
cathode, with a remarkable long-standing stability retaining ∼100%
of the initial current after a 100 h long OWS run, which is attributed
to the “synergistic coupling” between NiO QD catalysts
and the CNTR matrix. Interestingly, the developed electrode exhibits
a cell potential (E10) of only 1.81 V
with significantly low NiO QD loading (83 μg/cm2)
compared to other catalyst loading values reported in the literature.
This study demonstrates a potential class of carbon-based electrodes
with single-metal-based bifunctional catalysts that opens up a cost-effective
and large-scale pathway for further development of catalysts and their
loading engineering suitable for alkaline-based OWS applications and
green hydrogen generation
Side Group of Poly(3-alkylthiophene)s Controlled Dispersion of Single-Walled Carbon Nanotubes for Transparent Conducting Film
Controlled
dispersion of single-walled carbon nanotubes (SWCNTs) in common solvents
is a challenging issue, especially for the rising need of low cost
flexible transparent conducting films (TCFs). Utilizing conductive
polymer as surfactant to facilitate SWCNTs solubility is the most
successful pragmatic approach to such problem. Here, we show that
dispersion of SWCNT with polymer significantly relies on the length
of polymer side groups, which not only influences the diameter distribution
of SWCNTs in solution, also eventually affects their effective TCF
performance. Surfactants with longer side groups covering larger nanotube
surface area could induce adequate steric effect to stabilize the
wrapped SWCNTs against the nonspecific aggregation, as discerned by
the optical and microscopic measurements, also evidenced from the
resultant higher electrokinetic potential. This approach demonstrates
a facile route to fabricate large-area SWCNTs-TCFs exhibiting high
transmittance and high conductivity, with considerable uniformity
over 10 cm × 10 cm
Highly Efficient Visible Light Photocatalytic Reduction of CO<sub>2</sub> to Hydrocarbon Fuels by Cu-Nanoparticle Decorated Graphene Oxide
The production of renewable solar
fuel through CO<sub>2</sub> photoreduction, namely artificial photosynthesis,
has gained tremendous attention in recent times due to the limited
availability of fossil-fuel resources and global climate change caused
by rising anthropogenic CO<sub>2</sub> in the atmosphere. In this
study, graphene oxide (GO) decorated with copper nanoparticles (Cu-NPs),
hereafter referred to as Cu/GO, has been used to enhance photocatalytic
CO<sub>2</sub> reduction under visible-light. A rapid one-pot microwave
process was used to prepare the Cu/GO hybrids with various Cu contents.
The attributes of metallic copper nanoparticles (∼4–5
nm in size) in the GO hybrid are shown to significantly enhance the
photocatalytic activity of GO, primarily through the suppression of
electron–hole pair recombination, further reduction of GO’s
bandgap, and modification of its work function. X-ray photoemission
spectroscopy studies indicate a charge transfer from GO to Cu. A strong
interaction is observed between the metal content of the Cu/GO hybrids
and the rates of formation and selectivity of the products. A factor
of greater than 60 times enhancement in CO<sub>2</sub> to fuel catalytic
efficiency has been demonstrated using Cu/GO-2 (10 wt % Cu) compared
with that using pristine GO