ACS Applied Nano Materials,
Journal Year:
2024,
Volume and Issue:
7(11), P. 13547 - 13556
Published: May 22, 2024
The
development
of
efficient
and
facile
nonprecious
metal
catalysts
for
the
oxygen
reduction
reaction
(ORR)
holds
great
significance.
Among
these,
single-atomic
metal–nitrogen–carbon
(M–N–C)
are
emerging
candidates
due
to
their
high
activity
prolonged
lifespan.
However,
traditional
preparation
M–N–C
suffers
from
thermal
aggregation
low
space–time
yield,
limiting
application
in
industry.
Inspired
by
"chainmail
protection"
carbonaceous
materials,
here
we
propose
an
"armor
strategy
large-scale
synthesis
a
highly
active
Fe
single-atom
ORR
catalyst
(Fe-8/8-CN)
pyrolyzing
well-designed
precursor
Fe-ZIF-8/ZIF-8.
In
this
precursor,
2-methylimidazole
zinc
MOF
(ZIF-8)
loaded
with
iron
(Fe-ZIF-8)
is
encased
additional
ZIF-8
armor
layer
(Fe-ZIF-8/ZIF-8)
that
effectively
shields
species
within
inner
during
pyrolysis
process,
ultimately
yielding
(Fe-8/8-CN).
Furthermore,
approaches
construction
Fe-ZIF-8/ZIF-8
make
it
efficiently
scale
up
yield
18.7
kg
m–3
day–1.
particular,
protection
preparing
universally
applicable
leaf-shaped
ZIF-L
other
ZIFs
diverse
morphologies.
Thanks
presence
outer
core
dispersing
catalytic
sites
porous
defect-rich
characteristics
volatilization
Zn
ZIF-8,
resulting
Fe-8/8-CN
demonstrates
superior
performance
alkaline
electrolyte
(E1/2
=
0.93
V,
JL
−5.89
mA
cm–2).
Finally,
Fe-8/8-CN,
as
cathode
material
flexible
zinc–air
batteries,
exhibits
peak
power
density
(97
mW
cm–2)
excellent
durability
Pt/C.
Synthetic Communications,
Journal Year:
2022,
Volume and Issue:
52(6), P. 795 - 826
Published: Feb. 22, 2022
Quinazolines
and
their
derivative
are
among
the
most
significant
heterocyclic
compounds
due
to
several
chemical
reactivities
vital
range
of
biological
activity.
Although
a
tremendous
number
research
papers
dedicated
synthesizing
quinazolines
derivatives
using
reaction
conditions
like
expensive
catalysts,
multistep
reactions,
high
temperature,
use
base
toxic
solvents.
But
moving
toward
greener
approach,
nanocatalysts
have
emerged
as
potential
candidates
owing
surface
area
more
exposed
active
sites
for
reactants
which
enhances
selectivity
reduces
quantity
catalyst
requirement.
The
synthesis
quinazoline
is
mainly
limited
primary
screening
eco-friendly
nanocatalysts.
This
review
provides
importance
its
enlists
various
(2015–present)
involved
in
with
emphasis
on
synthetic
strategies
catalytic
performances.
will
provide
an
idea
rational
designing
eco-friendly,
novel
efficient
Nature Communications,
Journal Year:
2023,
Volume and Issue:
14(1)
Published: May 17, 2023
Sustainable
production
of
acetic
acid
is
a
high
priority
due
to
its
global
manufacturing
capacity
and
numerous
applications.
Currently,
it
predominantly
synthesized
via
carbonylation
methanol,
in
which
both
the
reactants
are
fossil-derived.
Carbon
dioxide
transformation
into
highly
desirable
achieve
net
zero
carbon
emissions,
but
significant
challenges
remain
this
efficiently.
Herein,
we
report
heterogeneous
catalyst,
thermally
transformed
MIL-88B
with
Fe0
Fe3O4
dual
active
sites,
for
selective
formation
methanol
hydrocarboxylation.
ReaxFF
molecular
simulation,
X-ray
characterisation
results
show
catalyst
consisting
dispersed
Fe0/Fe(II)-oxide
nanoparticles
carbonaceous
matrix.
This
efficient
showed
yield
(590.1
mmol/gcat.L)
81.7%
selectivity
at
150
°C
aqueous
phase
using
LiI
as
co-catalyst.
Here
present
plausible
reaction
pathway
formic
intermediate.
No
difference
were
noticed
during
recycling
study
up
five
cycles.
work
scalable
industrially
relevant
utilisation
reduce
especially
when
green
hydrogen
readily
available
future.
Inorganic Chemistry,
Journal Year:
2023,
Volume and Issue:
62(14), P. 5565 - 5575
Published: March 29, 2023
Two
dimeric
{ε-Zn4PMo12}-based
metal-organic
frameworks
(MOFs),
[ε-PMo8VMo4VIO34(OH)6Zn4][LO]
(SDUT-21,
LO
=
[5-((4'-carboxybenzyl)oxy)isophthalic
acid])
and
[TBA]3[ε-PMo8VMo4VIO37(OH)3Zn4][LN]
(SDUT-22,
TBA+
tetrabutylammonium
ion,
LN
[5-((4-carboxybenzyl)imino)isophthalic
acid]),
combining
the
advantages
of
polyoxometalates
(POMs)
MOFs,
were
synthesized
by
one-pot
assembly
strategy.
The
{ε-Zn4PMo12}
units
act
as
nodes
that
are
linked
flexible
ligands
extended
into
two-
or
three-dimensional
frameworks.
cyclic
voltammetry
proton
conductivity
measurements
SDUT-21
SDUT-22
performed
indicated
high
electron
transfer
abilities.
These
materials
also
e
xhibited
catalytic
performance
for
synthesis
quinazolinones
in
heterogeneous
state,
different
binding
capacities
toward
substrates
caused
activity
to
be
higher
than
under
same
conditions.
In
addition,
used
catalysts
could
readily
recovered
five
successive
cycles
maintained
efficiency.
ACS Applied Nano Materials,
Journal Year:
2024,
Volume and Issue:
7(11), P. 13547 - 13556
Published: May 22, 2024
The
development
of
efficient
and
facile
nonprecious
metal
catalysts
for
the
oxygen
reduction
reaction
(ORR)
holds
great
significance.
Among
these,
single-atomic
metal–nitrogen–carbon
(M–N–C)
are
emerging
candidates
due
to
their
high
activity
prolonged
lifespan.
However,
traditional
preparation
M–N–C
suffers
from
thermal
aggregation
low
space–time
yield,
limiting
application
in
industry.
Inspired
by
"chainmail
protection"
carbonaceous
materials,
here
we
propose
an
"armor
strategy
large-scale
synthesis
a
highly
active
Fe
single-atom
ORR
catalyst
(Fe-8/8-CN)
pyrolyzing
well-designed
precursor
Fe-ZIF-8/ZIF-8.
In
this
precursor,
2-methylimidazole
zinc
MOF
(ZIF-8)
loaded
with
iron
(Fe-ZIF-8)
is
encased
additional
ZIF-8
armor
layer
(Fe-ZIF-8/ZIF-8)
that
effectively
shields
species
within
inner
during
pyrolysis
process,
ultimately
yielding
(Fe-8/8-CN).
Furthermore,
approaches
construction
Fe-ZIF-8/ZIF-8
make
it
efficiently
scale
up
yield
18.7
kg
m–3
day–1.
particular,
protection
preparing
universally
applicable
leaf-shaped
ZIF-L
other
ZIFs
diverse
morphologies.
Thanks
presence
outer
core
dispersing
catalytic
sites
porous
defect-rich
characteristics
volatilization
Zn
ZIF-8,
resulting
Fe-8/8-CN
demonstrates
superior
performance
alkaline
electrolyte
(E1/2
=
0.93
V,
JL
−5.89
mA
cm–2).
Finally,
Fe-8/8-CN,
as
cathode
material
flexible
zinc–air
batteries,
exhibits
peak
power
density
(97
mW
cm–2)
excellent
durability
Pt/C.
