Agronomy,
Год журнала:
2023,
Номер
13(11), С. 2695 - 2695
Опубликована: Окт. 26, 2023
Soil
salinity
is
a
serious
global
problem
that
threatens
high
percentage
of
the
soils.
Salinity
stress
can
create
ionic,
oxidative,
and
osmotic
stress,
along
with
hormonal
imbalances,
in
stressful
plants.
This
kind
was
investigated
on
agricultural
productivity
at
different
levels,
starting
vitro
(plant
tissue
culture),
through
hydroponics,
pots,
field
conditions.
Several
approaches
were
studied
for
managing
including
using
traditional
materials
(e.g.,
gypsum,
sulfur),
organic
amendments
compost,
biochar,
chitosan),
applied
manufactured
or
engineered
nanomaterials
(NMs).
Application
ameliorating
has
gained
great
attention
due
to
their
efficiency,
eco-friendliness,
non-toxicity,
especially
biological
nanomaterials.
The
application
NMs
did
not
only
support
growing
plants
under
but
also
increased
yield
crops,
provided
an
economically
feasible
nutrient
management
approach,
environmentally
robust
sustainable
crop
productivity.
Nano-management
may
involve
applying
nano-amendments,
nanomaterials,
nano-enabled
nutrients,
nano-organic
amendments,
derived
smart
nanostructures,
nano-tolerant
plant
cultivars.
Producing
cultivars
are
tolerant
be
achieved
conventional
breeding
plantomics
technologies.
In
addition
large-scale
use
there
urgent
need
address
treat
nanotoxicity.
study
aims
contribute
this
area
research
by
exploring
nano-management
current
practices
raises
many
questions
regarding
expected
interaction
between
toxic
effects
such
includes
whether
acts
positively
negatively
cultivated
soil
activity,
what
regulatory
ecotoxicity
tests
protocols
should
used
research.
Agrochemicals,
Год журнала:
2023,
Номер
2(2), С. 296 - 336
Опубликована: Июнь 9, 2023
In
an
alarming
tale
of
agricultural
excess,
the
relentless
overuse
chemical
fertilizers
in
modern
farming
methods
have
wreaked
havoc
on
once-fertile
soil,
mercilessly
depleting
its
vital
nutrients
while
inflicting
irreparable
harm
delicate
balance
surrounding
ecosystem.
The
excessive
use
such
leaves
residue
products,
pollutes
environment,
upsets
agrarian
ecosystems,
and
lowers
soil
quality.
Furthermore,
a
significant
proportion
nutrient
content,
including
nitrogen,
phosphorus,
potassium,
is
lost
from
(50–70%)
before
being
utilized.
Nanofertilizers,
other
hand,
nanoparticles
to
control
release
nutrients,
making
them
more
efficient
cost-effective
than
traditional
fertilizers.
Nanofertilizers
comprise
one
or
plant
within
where
at
least
50%
particles
are
smaller
100
nanometers.
Carbon
nanotubes,
graphene,
quantum
dots
some
examples
types
nanomaterials
used
production
nanofertilizers.
new
generation
that
utilize
advanced
nanotechnology
provide
sustainable
method
fertilizing
crops.
They
designed
deliver
controlled
manner,
ensuring
gradually
released
over
extended
period,
thus
providing
steady
supply
essential
elements
plants.
controlled-release
system
fertilizers,
as
it
reduces
need
for
frequent
application
amount
fertilizer.
These
high
surface
area-to-volume
ratio,
ideal
holding
releasing
nutrients.
Naturally
occurring
found
various
sources,
volcanic
ash,
ocean,
biological
matter
viruses
dust.
However,
regarding
large-scale
production,
relying
solely
naturally
may
not
be
sufficient
practical.
agriculture,
has
been
primarily
increase
crop
minimizing
losses
activating
defense
mechanisms
against
pests,
insects,
environmental
challenges.
nanofertilizers
can
reduce
runoff
leaching
into
improving
sustainability.
also
improve
fertilizer
efficiency,
leading
higher
yields
reducing
overall
cost
application.
especially
beneficial
areas
inefficient
ineffective.
way
fertilize
crops
impact
product
promising
technology
help
meet
increasing
demand
food
Currently,
face
limitations,
costs
potential
safety
concerns
due
nanomaterials,
further
research
needed
fully
understand
their
long-term
effects
health,
growth,
environment.
Fungal Diversity,
Год журнала:
2024,
Номер
125(1), С. 1 - 71
Опубликована: Март 20, 2024
Abstract
The
field
of
mycology
has
grown
from
an
underappreciated
subset
botany,
to
a
valuable,
modern
scientific
discipline.
As
this
study
grown,
there
have
been
significant
contributions
science,
technology,
and
industry,
highlighting
the
value
fungi
in
era.
This
paper
looks
at
current
research,
along
with
existing
limitations,
suggests
future
areas
where
scientists
can
focus
their
efforts,
mycology.
We
show
how
become
important
emerging
diseases
medical
discuss
trends
potential
drug
novel
compound
discovery.
explore
phylogenomics,
its
potential,
outcomes
address
question
phylogenomics
be
applied
fungal
ecology.
In
addition,
functional
genomics
studies
are
discussed
importance
unravelling
intricate
mechanisms
underlying
behaviour,
interactions,
adaptations,
paving
way
for
comprehensive
understanding
biology.
look
research
building
materials,
they
used
as
carbon
sinks,
biocircular
economies.
numbers
always
great
interest
often
written
about
estimates
varied
greatly.
Thus,
we
needs
order
obtain
more
reliable
estimates.
aspects
machine
learning
(AI)
it
mycological
research.
Plant
pathogens
affecting
food
production
systems
on
global
scale,
such,
needed
area,
particularly
disease
detection.
latest
data
High
Throughput
Sequencing
if
still
gaining
new
knowledge
same
rate
before.
A
review
nanotechnology
is
provided
addressed.
Arbuscular
Mycorrhizal
Fungi
addressed
acknowledged.
Fungal
databases
becoming
important,
therefore
provide
major
databases.
Edible
medicinal
huge
medicines,
especially
Asia
prospects
discussed.
Lifestyle
changes
(e.g.,
endophytes,
pathogens,
and/or
saprobes)
also
extremely
trend
special
issue
Diversity.
Biology,
Год журнала:
2024,
Номер
13(3), С. 199 - 199
Опубликована: Март 21, 2024
Microalgae
have
commercial
potential
in
different
sectors
of
the
industry.
Specifically
modern
agriculture,
they
can
be
used
because
ability
to
supply
nutrients
soil
and
produce
plant
growth
hormones,
polysaccharides,
antimicrobial
compounds,
other
metabolites
that
improve
agricultural
productivity.
Therefore,
products
formulated
from
microalgae
as
biofertilizers
biostimulants
turn
out
beneficial
for
agriculture
are
positioned
a
novel
environmentally
friendly
strategy.
However,
these
bioproducts
present
challenges
preparation
affect
their
shelf
life
due
rapid
degradation
bioformulated
products.
this
work
aimed
provide
comprehensive
review
microalgae,
which
bibliometric
analysis
was
carried
establish
trends
using
scientometric
indicators,
technological
advances
were
identified
terms
formulation
methods,
global
market
analyzed.
Heliyon,
Год журнала:
2024,
Номер
10(10), С. e31393 - e31393
Опубликована: Май 1, 2024
Nanotechnology
has
emerged
as
a
powerful
tool
in
addressing
global
challenges
and
advancing
sustainable
development.
By
manipulating
materials
at
the
nanoscale,
researchers
have
unlocked
new
possibilities
various
fields,
including
energy,
healthcare,
agriculture,
construction,
transportation,
environmental
conservation.
This
paper
explores
potential
of
nanotechnology
nanostructures
contributing
to
achievement
United
Nations
(UN)
Sustainable
Development
Goals
(SDGs)
by
improving
energy
efficiency
conversion,
leading
more
clean
future,
water
purification
processes,
enabling
access
drinking
for
communities,
targeted
drug
delivery
systems,
early
disease
detection,
personalized
medicine,
thus
revolutionizing
crop
yields,
efficient
nutrient
pest
control
mechanisms,
many
other
areas,
therefore
food
security
issues.
It
also
highlights
nanomaterials
remediation
pollution
control.
Therefore,
understanding
harnessing
nanotechnology's
potential,
policymakers,
researchers,
stakeholders
can
work
together
toward
future
achieving
17
UN
SDGs.
