Considering
the
recent
increasing
demand
for
effective
wastewater
remediation
solutions,
microalgae
have
emerged
as
a
promising
option.
They
possess
unique
capability
to
thrive
in
various
types
while
efficiently
removing
nitrogen
and
phosphorus.
Integrating
into
oxidation
ponds
presents
numerous
advantages,
including
oxygen
generation
support
bacterial
degradation
of
organic
compounds
uptake
carbon
dioxide
through
photosynthesis.
In
this
study,
native
strain
Chlorella,
previously
isolated
from
sewage,
was
used
treatment
synthetic
wastewater.
A
first
set
batch
cultures
carried
out
obtain
kinetic
parameters:
maximum
growth
factor
(μmax)
half-saturation
constant
(Ks),
each
limiting
nutrient.
These
parameters
were
multi-substrate
model
able
predict
continuous
operation
within
laboratory
scale
raceway
reactor.
The
removal
capabilities
addressed
pollutant
evaluated
system
with
different
applied
dilution
rates.
This
comprehensive
approach
represents
significant
step
towards
addressing
utilizing
microalgae.
Considering
the
recent
increasing
demand
for
effective
wastewater
remediation
solutions,
microalgae
have
emerged
as
a
promising
option.
They
possess
unique
capability
to
thrive
in
various
types
while
efficiently
removing
nitrogen
and
phosphorus.
Integrating
into
oxidation
ponds
presents
numerous
advantages,
including
oxygen
generation
support
bacterial
degradation
of
organic
compounds
uptake
carbon
dioxide
through
photosynthesis.
In
this
study,
native
strain
Chlorella,
previously
isolated
from
sewage,
was
used
treatment
synthetic
wastewater.
A
first
set
batch
cultures
carried
out
obtain
kinetic
parameters:
maximum
growth
factor
(μmax)
half-saturation
constant
(Ks),
each
limiting
nutrient.
These
parameters
were
multi-substrate
model
able
predict
continuous
operation
within
laboratory
scale
raceway
reactor.
The
removal
capabilities
addressed
pollutant
evaluated
system
with
different
applied
dilution
rates.
This
comprehensive
approach
represents
significant
step
towards
addressing
utilizing
microalgae.
