Modern Physics Letters B,
Год журнала:
2024,
Номер
unknown
Опубликована: Сен. 24, 2024
Due
to
their
widespread
use
in
engineering,
hybrid
nanofluids
have
been
the
primary
focus
of
mathematical
and
physical
research.
Only
improvement
nanofluids’
variable
heat
conductivity
viscosity
has
considered
so
far.
Hybrid
nanofluid
flow
across
an
inclined
cylinder
many
potential
uses,
including
transfer
cooling
electrical
devices,
energy
storage,
refrigerants,
automobile
industry.
Examining
effects
buoyant
force,
viscosity,
thermal
conductivity,
mass
suction,
convective
conditions,
a
magnetic
field
on
stagnation
point
Al
2
O
3
–Cu/H
is
our
objective
this
work.
In
order
find
solutions
boundary-condition
flow-describing
partial
differential
equations,
we
turn
them
into
ordinary
equations
using
similarity
transformations.
We
achieve
by
employing
numerical
strategy
known
as
fourth-order
Runge–Kutta
technique,
which
incorporates
shooting
techniques.
A
graphical
representation
findings
emphasizes
influence
parameters
dynamics.
addition,
address
drag
force
rate
various
elements,
such
Biot
parameter,
variable,
variable.
The
mixed
convection
cause
velocity
profile
rise
while
temperature
falls.
research’s
results
elucidate
behind
contour
nanofluids,
seen
when
there
increment
radiation
number.
exhibits
significant
increase
36.87%
aiding
scenario
2.0
suction
applied
conjunction
with
0.01
nanofluid,
compared
conventional
fluid.
opposing
flow,
36.96%
that
Heat
increases
43.00%
Rd
from
0.1
0.5
for
both
assisting
flow.
Scientific Reports,
Год журнала:
2025,
Номер
15(1)
Опубликована: Янв. 31, 2025
The
hybrid
base
solvent
water
(H2O)
and
ethylene
glycol
(C2H6O2)
are
highly
use
in
industrial
applications
due
to
excellent
solvability.
Addition
of
nanoparticles
(GO-MoS2)
augments
the
thermal
conductivity
these
fluids
which
ultimately
make
them
very
productive.
Hence,
current
study
aims
develop
investigate
novel
nanofluid
model
(GO-MoS2)/(C2H6O2-H2O)
through
MRW
(moving
riga
wedge)
SRW
(static
cases.
traditional
Falkner
Skan
Model
(FSM)
is
modified
using
effects
solar
radiations,
internal
heating
source
fixed
magnets
associated
concept
Riga
wedge.
Further,
improved
thermal-physical
characteristics
nanofluids
will
enhance
productivity.
A
mathematical
developed
for
flow
situation
treated
numerically.
results
furnished
graphical
way
comprehensive
discussion
provided.
It
examined
that
movement
reduced
observed
rapid
velocity
near
surface.
heat
generating
radiations
number
enhanced
performance
better
predicted
ranges
parameters
from
[Formula:
see
text]
text].
Moreover,
boundary
layer
region
becomes
thin
it
increased
stronger
radiation
effects.
nanoparticle
amount
GO
MoS2
utilization
while
higher
magnetic
controlled
layer.
dynamics
noticed
dominant
case
as
compared
case.
Modern Physics Letters B,
Год журнала:
2025,
Номер
unknown
Опубликована: Март 29, 2025
Numerically,
the
effect
of
melting
heat
transfer
on
magnetohydrodynamics
(MHD)
tangent
hyperbolic
nanofluid
(Thnf)
flow
across
a
porous
wedge
is
evaluated.
Electronic
devices
generate
lot
while
running,
so
Thnf
commonly
used
to
reduce
its
temperature.
has
ability
more
effectively,
thus
minimizing
risk
high
temperature
and
component
disruptions.
The
impact
source/sink,
thermal
radiation,
homogeneous/heterogeneous
chemical
reactions
also
observed
in
fluid
flow.
modeled
equations
are
reformulated
into
non-dimensional
form
ordinary
differential
(ODEs),
which
further
numerically
solved
through
nonlinear
dynamics
(ND)-solve
approach.
For
validity
results,
numerical
outcomes
relatively
related
published
studies,
reveal
that
proposed
model
results
accurate
consistent.
Furthermore,
it
can
be
determined
from
graphical
velocity
drops
with
rising
permeability
parameter
whereas
enhances
positive
variation
power
law
index.
increasing
influence
angle
parameters
augments
energy
distribution
rate.
intensifying
heterogeneous
homogeneous
reaction
decreases
concentration
profile.
