In
order
to
explore
the
current
application
of
intelligent
oil
recovery
technology
in
electric
pump
wells
and
opportunity
for
lower
develop
pent.
Through
reading
a
large
number
literatures,
this
paper
systematically
summarizes
research
status
related
technologies
at
home
abroad
establishes
three
hot
topics:
fine-tuning
optimization
operation
parameters,
real-time
production
process
well
under
framework
data.
Then,
according
author's
many
years
work
experience,
pump-intelligent
gas
lift
string
multi-parameter
monitoring
submersible
offs
here
oilfield
are
displayed
panoramic
way,
providing
constructive
suggestions
colleagues.
International Journal of Advanced Economics,
Год журнала:
2024,
Номер
6(5), С. 139 - 172
Опубликована: Май 13, 2024
This
study
critically
evaluates
the
strategic
implications
of
carbon
pricing
mechanisms
on
global
environmental
sustainability
and
economic
development.
Employing
a
systematic
literature
review
content
analysis,
research
synthesizes
recent
findings
from
peer-reviewed
articles,
reports,
policy
documents
published
between
2010
2024.
The
study's
objectives
include
analyzing
effectiveness
in
reducing
greenhouse
gas
emissions,
assessing
its
impacts,
exploring
benefits,
understanding
role
international
cooperation
enhancing
efficacy
policies.
methodology
hinges
structured
search
strategy,
applying
rigorous
inclusion
exclusion
criteria
to
ensure
relevance
quality
reviewed.
analysis
reveals
that
pricing,
encompassing
both
taxes
cap-and-trade
systems,
serves
as
pivotal
tool
for
mitigating
climate
change
while
fostering
growth
structural
transformation.
Key
highlight
potential
drive
innovation
green
technologies,
importance
addressing
social
equity
concerns,
critical
coordination
cross-border
leakage
competitiveness
issues.
concludes
mechanisms,
when
effectively
designed
equitably
implemented,
can
align
with
development
goals.
Recommendations
policymakers
emphasize
need
comprehensive
strategies
integrate
broader
policies,
underscore
cooperation,
advocate
continued
refine
models
strategies.
contributes
ongoing
discourse
offering
insights
into
cornerstone
governance
sustainable
policy.
Keywords:
Carbon
Pricing
Mechanisms,
Environmental
Sustainability,
Economic
Development,
International
Cooperation.
Engineering Science & Technology Journal,
Год журнала:
2024,
Номер
5(5), С. 1678 - 1694
Опубликована: Май 13, 2024
The
review
explores
the
pivotal
role
of
sustainable
nanomaterials
in
promoting
green
supply
chains
and
advancing
environmental
sustainability.
Nanotechnology
has
emerged
as
a
promising
field
for
developing
innovative
materials
with
enhanced
properties
reduced
impacts.
Sustainable
nanomaterials,
characterized
by
their
eco-friendly
synthesis
methods,
biodegradability,
low
toxicity,
offer
transformative
opportunities
enhancing
sustainability
across
diverse
industries.
This
examines
potential
applications
chains,
encompassing
areas
such
renewable
energy,
water
purification,
waste
management,
packaging.
By
leveraging
unique
high
surface
area-to-volume
ratio,
catalytic
activity,
tunable
properties,
businesses
can
develop
solutions
to
address
pressing
challenges.
Case
studies
examples
highlight
successful
integration
into
chain
practices,
showcasing
ability
reduce
resource
consumption,
minimize
generation,
mitigate
also
discusses
challenges
considerations
associated
adoption
including
regulatory
compliance,
risk
assessment,
ethical
considerations.
Strategies
responsible
nanotechnology
practices
fostering
collaboration
among
stakeholders
are
proposed,
emphasizing
importance
interdisciplinary
approaches
stakeholder
engagement
achieving
goals.
In
conclusion,
holds
immense
driving
sustainability,
innovation,
long-term
prosperity.
Keywords:
Nanomaterials,
Green
Supply
Chains,
Environmental
Sustainability,
Circular
Economy,
Nanotechnology,
Chain
Optimization
Engineering Science & Technology Journal,
Год журнала:
2024,
Номер
5(5), С. 1695 - 1710
Опубликована: Май 13, 2024
Nanotechnology
has
emerged
as
a
promising
frontier
in
the
quest
for
sustainable
energy
solutions,
offering
transformative
opportunities
to
address
pressing
challenges
renewable
generation,
storage,
and
conversion.
This
review
explores
potential
of
nanotechnology
advancing
encompassing
wide
range
applications
spanning
solar
energy,
wind
fuel
cells.
By
leveraging
unique
properties
nanomaterials,
such
high
surface
area-to-volume
ratio,
tunable
optical
electronic
properties,
enhanced
catalytic
activity,
researchers
engineers
can
develop
innovative
materials
devices
with
unprecedented
performance
efficiency.
Nanotechnology-enabled
advancements
photovoltaics
include
development
next-generation
cells
incorporating
nanostructured
materials,
quantum
dots,
nanowires,
perovskite-based
cells,
enhance
light
absorption,
charge
transport,
overall
power
conversion
In
realm
nanomaterials
hold
promise
improving
longevity
batteries,
supercapacitors,
other
storage
through
electrode
electrolytes,
architectures.
Furthermore,
nanotechnology-driven
innovations
lightweight
durable
nanocomposite
turbine
blades,
cell
technologies,
including
catalyst
nanoparticles
efficient
hydrogen
production
conversion,
exemplify
diverse
energy.
Through
comprehensive
analysis
recent
research
efforts,
this
abstract
underscores
critical
role
accelerating
transition
future.
Keywords:
Nanotechnology,
Renewable
Energy,
Solar
Wind
Energy
Storage,
Nanomaterials.
Finance & Accounting Research Journal,
Год журнала:
2024,
Номер
6(5), С. 747 - 762
Опубликована: Май 12, 2024
The
concept
of
circular
economy
has
gained
significant
traction
in
recent
years
as
a
holistic
approach
to
sustainable
development
and
resource
management.
This
review
explores
the
principles
their
integration
into
global
supply
chain
strategies.
transition
from
linear
'take-make-dispose'
model
focused
on
recovery,
reuse,
regeneration
is
driving
paradigm
shift
how
businesses
operate
manage
chains.
Key
economy,
including
designing
out
waste
pollution,
keeping
products
materials
use,
regenerating
natural
systems,
are
examined
context
Strategies
for
implementing
across
various
stages
chain,
product
design
manufacturing
distribution,
consumption,
end-of-life
management,
discussed.
highlights
benefits
adopting
strategies,
reduced
reduction,
cost
savings,
enhanced
resilience
external
shocks.
Case
studies
examples
diverse
industries
illustrate
successful
implementation
demonstrating
tangible
environmental,
social,
economic
benefits.
Challenges
barriers
adoption
chains
also
addressed,
regulatory
hurdles,
technological
limitations,
cultural
barriers.
overcoming
these
challenges
promoting
mindset
among
stakeholders
explored,
emphasizing
importance
collaboration,
innovation,
cross-sector
partnerships.
strategies
offers
opportunities
growth,
resilience,
value
creation.
By
embracing
circularity,
can
unlock
new
sources
competitive
advantage
while
contributing
towards
more
regenerative
economy.
Keywords:
Circular
Economy,
Supply
Chain,
Sustainability,
Integration,
Challenges,
Opportunities.
International Journal of Applied Research in Social Sciences,
Год журнала:
2024,
Номер
6(5), С. 903 - 926
Опубликована: Май 12, 2024
This
paper
provides
an
overview
of
the
current
practices
and
future
directions
in
environmental
stewardship
within
oil
gas
industry,
focusing
on
key
areas
concern
strategies
for
improvement.
The
industry
has
made
significant
strides
recent
years,
driven
by
a
combination
regulatory
requirements,
corporate
initiatives,
stakeholder
pressure.
One
primary
focus
been
reduction
greenhouse
emissions
associated
with
extraction,
refining,
transportation
processes.
Companies
have
implemented
technologies
such
as
carbon
capture
storage
to
minimize
their
footprint,
alongside
investments
renewable
energy
sources
efficiency
measures
transition
towards
cleaner
alternatives.
Furthermore,
placed
increasing
emphasis
responsible
management
water
resources,
recognizing
potential
impacts
extraction
usage
operations.
Strategies
recycling,
reuse,
wastewater
treatment
adopted
mitigate
pollution
strain
local
ecosystems.
Biodiversity
conservation
also
emerged
critical
aspect
sector,
companies
undertaking
impact
assessments
collaborating
organizations
habitat
disruption
restore
ecosystems
affected
Community
engagement
social
responsibility
are
integral
components
stewardship,
seeking
address
operations
through
employment
opportunities,
infrastructure
development,
programs
benefiting
communities.
However,
continues
face
challenges
limitations
its
efforts
impact.
Accidental
spills,
leaks,
other
incidents
pose
ecological
risks,
highlighting
importance
stringent
safety
regulations
emergency
response
protocols.
Moreover,
presents
traditional
companies,
requiring
substantial
capital
investment
strategic
planning.
To
these
advance
several
proposed.
These
include
accelerating
energy,
enhancing
transparency
accountability
reporting
performance,
strengthening
enforcement,
investing
research
development
innovative
technologies,
fostering
collaboration
among
stakeholders,
governments,
NGOs,
Keywords:
Stewardship,
Oil,
Gas,
Sustainability,
Climate,
Mitigation
International Journal of Applied Research in Social Sciences,
Год журнала:
2024,
Номер
6(6), С. 1215 - 1226
Опубликована: Июнь 13, 2024
The
alignment
of
oil
and
gas
industry
practices
with
Sustainable
Development
Goals
(SDGs)
is
imperative
for
fostering
a
sustainable
future.
This
abstract
provides
an
overview
the
strategies
challenges
associated
this
alignment.
plays
significant
role
in
global
energy
supply,
economic
development,
geopolitical
dynamics.
However,
its
operations
often
have
adverse
environmental,
social,
impacts,
making
SDGs
essential.
Challenges
aligning
include
environmental
degradation
caused
by
extraction
activities,
social
disparities
oil-producing
regions,
regulatory
complexities.
To
address
these
challenges,
such
as
reducing
carbon
footprints,
transitioning
to
renewable
sources,
engaging
local
communities,
protecting
human
indigenous
rights,
diversification
are
crucial.
Case
studies
companies
successfully
highlight
best
lessons
learned.
Impact
assessments
demonstrate
positive
outcomes
aligned
on
conservation,
well-being,
development.
Recommendations
policy
reforms,
guidelines,
stakeholder
collaboration
facilitate
broader
adoption
practices.
In
conclusion,
essential
achieving
development
goals
globally.
calls
concerted
efforts
from
stakeholders,
policymakers,
civil
society
create
more
Keywords:
Oil,
Gas,
Industry
Practices,
(SDGs).
International Journal of Applied Research in Social Sciences,
Год журнала:
2024,
Номер
6(6), С. 1227 - 1243
Опубликована: Июнь 13, 2024
Carbon
capture
and
storage
(CCS)
has
emerged
as
a
critical
technology
in
the
fight
against
climate
change,
offering
viable
pathway
to
mitigate
CO2
emissions
from
industrial
processes
power
generation.
This
review
explores
best
practices
innovations
CCS
for
effective
storage,
highlighting
key
strategies
advancements
that
optimize
capacity,
enhance
security,
minimize
environmental
risks.
The
begins
by
delineating
importance
of
reducing
greenhouse
gas
meeting
global
targets.
It
underscores
urgency
deploying
technologies
at
scale
address
dual
challenge
decarbonizing
energy
systems
ensuring
security.
Drawing
upon
recent
research
industry
developments,
elucidates
capture,
transport,
emphasizing
integrated
holistic
approaches.
discusses
technologies,
including
post-combustion
pre-combustion
oxy-fuel
combustion,
efficiency
improvements
cost
reduction
strategies.
Furthermore,
delves
into
techniques,
such
geological
ocean
mineralization,
evaluating
their
respective
advantages,
challenges,
scalability.
site
selection,
characterization,
monitoring,
need
robust
risk
assessment
frameworks
regulatory
oversight
ensure
safety
integrity
sites.
Moreover,
examines
emerging
trends
CCS,
enhanced
oil
recovery
(EOR)
using
CO2,
direct
air
(DAC)
carbon
utilization
(CCUS)
initiatives.
potential
synergies
between
renewable
solutions
leverage
enable
decarbonization
hard-to-abate
sectors
heavy
aviation.
pivotal
role
achieving
deep
transitioning
low-carbon
economy.
calls
continued
research,
investment,
collaboration
unlock
full
accelerate
deployment
scale.
By
embracing
fostering
innovation,
stakeholders
can
pave
way
contribute
efforts
combat
change.
Keywords:
Best
Practices,
Innovation,
Carbon,
Capture,
Storage,
CO2.
