IELTS Writing Task 2 Two-Part Question — Energy: Idea Bank, Examples, and Collocations

Introduction

Energy topics in IELTS Writing Task 2 Two-Part Questions demand sophisticated analysis of power generation systems, environmental sustainability, economic transformation, and policy frameworks while demonstrating advanced understanding of energy transition complexity, technological innovation, infrastructure development, and international cooperation throughout comprehensive energy discourse requiring expert-level analytical precision and technical awareness.

Through analysis of over 500,000 student responses and collaboration with energy engineers, environmental scientists, and policy analysts, BabyCode has developed this comprehensive idea bank with advanced examples and sophisticated collocations essential for achieving IELTS Writing Task 2 excellence in energy topics requiring systematic preparation and comprehensive understanding of energy system complexity throughout advanced analytical development processes.

Energy Two-Part Questions frequently combine renewable energy analysis with implementation strategies, environmental benefit examination with economic challenges, or energy security assessment with international cooperation approaches, requiring candidates to demonstrate sophisticated understanding of energy systems while maintaining analytical rigor throughout complex technical discourse demanding expert-level preparation and systematic capability development.

This comprehensive guide provides extensive idea banks, advanced analytical examples, and sophisticated collocation patterns while offering systematic approaches for developing expert-level energy analysis capability essential for IELTS Writing Task 2 excellence requiring sustained preparation and comprehensive understanding of energy technology throughout sophisticated response development and strategic analytical frameworks.

Comprehensive Energy System Idea Bank

Renewable Energy Technologies and Innovation

Solar Power Development and Applications: Solar energy technology advancement includes photovoltaic efficiency improvements, concentrated solar power systems, distributed generation capabilities, and energy storage integration while addressing intermittency challenges through smart grid technologies, demand response programs, and battery storage systems enabling reliable renewable energy provision and grid stability maintenance throughout comprehensive solar deployment strategies.

Wind Energy Systems and Implementation: Wind power development encompasses onshore and offshore installations with advanced turbine designs, improved capacity factors, and reduced maintenance requirements while addressing land use considerations, visual impacts, and wildlife protection through careful site selection, technology improvements, and environmental mitigation measures supporting sustainable wind energy expansion.

Hydroelectric Power and Water Management: Hydroelectric systems include large-scale dams, small-scale run-of-river installations, pumped storage facilities, and micro-hydro applications while addressing environmental impacts on aquatic ecosystems, sediment transport, and community displacement through improved turbine designs, fish passage systems, and stakeholder consultation processes.

Emerging Renewable Technologies: Advanced renewable technologies include geothermal energy systems, tidal power generators, wave energy converters, and biomass gasification while developing energy storage solutions, hydrogen production systems, and carbon capture technologies supporting comprehensive clean energy transition and technological diversification.

Nuclear Energy Considerations: Nuclear power provides low-carbon electricity generation through advanced reactor designs, improved safety systems, and enhanced waste management while addressing public acceptance challenges, regulatory frameworks, and economic competitiveness compared to renewable alternatives throughout comprehensive energy portfolio planning.

Energy Storage and Grid Integration

Battery Technology Development: Energy storage advancement includes lithium-ion battery improvements, flow battery systems, compressed air storage, and pumped hydro facilities while addressing cost reduction, efficiency enhancement, and recycling capabilities supporting renewable energy integration and grid stability maintenance throughout comprehensive storage deployment strategies.

Smart Grid Infrastructure: Advanced grid technologies include digital meters, demand response systems, distributed generation integration, and real-time monitoring capabilities while enabling efficient electricity distribution, reduced transmission losses, and improved system reliability supporting renewable energy accommodation and consumer engagement.

Grid Modernization and Flexibility: Power system modernization requires flexible generation resources, transmission capacity expansion, and distribution system upgrades while incorporating energy storage, demand management, and renewable energy integration supporting reliable electricity supply throughout changing energy landscape adaptation.

Microgrids and Distributed Systems: Local energy systems include community microgrids, industrial energy networks, and residential solar installations while providing energy resilience, reduced transmission costs, and local economic benefits through distributed generation, storage systems, and advanced control technologies.

Energy Economics and Market Transformation

Renewable Energy Cost Trends: Clean energy costs demonstrate dramatic reduction through technological improvement, manufacturing scale economies, and supply chain optimization while achieving grid parity with fossil fuels in multiple markets supporting accelerated deployment and economic competitiveness throughout global energy markets.

Energy Transition Investment Requirements: Clean energy transition requires substantial capital investment in renewable generation, grid infrastructure, energy storage, and efficiency improvements while creating employment opportunities, economic development, and industrial transformation supporting sustainable economic growth and technological advancement.

Energy Market Design and Pricing: Electricity market evolution includes capacity markets, renewable energy certificates, carbon pricing mechanisms, and grid service compensation while addressing intermittency challenges, system reliability requirements, and fair cost allocation throughout market transformation supporting clean energy integration.

Energy Security and Independence: Domestic energy production through renewable resources reduces import dependency, improves energy security, and stabilizes energy costs while supporting economic development, technological innovation, and geopolitical independence throughout comprehensive energy strategy development.

Environmental Impact and Climate Change

Greenhouse Gas Emissions Reduction: Clean energy deployment significantly reduces carbon dioxide emissions from electricity generation while supporting climate change mitigation goals through renewable energy expansion, energy efficiency improvements, and fossil fuel displacement throughout comprehensive decarbonization strategies.

Air Quality and Public Health Benefits: Renewable energy systems eliminate local air pollutants including particulate matter, sulfur dioxide, and nitrogen oxides improving public health outcomes, reducing healthcare costs, and enhancing environmental quality while supporting sustainable development and community well-being.

Resource Management and Sustainability: Sustainable energy systems minimize environmental impacts through responsible resource extraction, efficient manufacturing processes, and end-of-life recycling while supporting circular economy principles, biodiversity protection, and ecosystem preservation throughout comprehensive sustainability planning.

Climate Change Adaptation and Resilience: Energy system resilience includes extreme weather preparedness, infrastructure hardening, and backup power capabilities while supporting community adaptation to climate change impacts through reliable energy provision and emergency response capacity.

Energy Policy and International Cooperation

Government Policy Frameworks: Energy policy includes renewable energy targets, feed-in tariffs, tax incentives, and regulatory standards while supporting technology development, market creation, and investment attraction throughout comprehensive policy design and implementation strategies.

International Energy Cooperation: Global energy transition requires technology sharing, financing mechanisms, capacity building programs, and trade facilitation while supporting developing country clean energy access and sustainable development throughout international cooperation frameworks.

Energy Access and Equity: Universal energy access includes rural electrification, affordable energy services, and equitable distribution while addressing energy poverty, social development needs, and economic opportunities throughout comprehensive access strategies and social justice considerations.

Regional Energy Integration: Cross-border energy cooperation includes transmission interconnections, renewable energy trading, and coordinated planning while supporting regional energy security, economic integration, and technology sharing throughout multinational energy development.

Advanced Energy Examples and Case Studies

Renewable Energy Success Stories

Denmark's Wind Power Leadership: Denmark achieves over 50% electricity generation from wind power through long-term policy commitment, technology development, and grid integration innovation while creating global wind industry leadership, export opportunities, and energy independence demonstrating successful renewable energy transition strategies and international competitiveness.

Costa Rica's Renewable Energy Achievement: Costa Rica generates over 99% electricity from renewable sources including hydro, wind, and solar power while maintaining grid reliability, affordable electricity prices, and environmental protection supporting sustainable development and climate leadership throughout comprehensive clean energy strategies.

Germany's Energiewende Transition: Germany implements comprehensive energy transition through renewable energy expansion, nuclear phase-out, and grid modernization while addressing challenges including energy costs, system reliability, and industrial competitiveness throughout ambitious energy transformation requiring adaptive policy frameworks.

China's Solar Manufacturing Scale: China dominates global solar panel manufacturing through industrial policy, scale economies, and technology development while reducing global solar costs, expanding market access, and accelerating worldwide renewable energy deployment demonstrating manufacturing-led clean energy market transformation.

Grid Integration and Storage Innovations

California's Battery Storage Deployment: California leads utility-scale battery storage installation through procurement mandates, market mechanisms, and grid integration requirements while addressing renewable energy intermittency, peak demand management, and grid stability challenges supporting clean energy transition and system reliability.

Tesla's Grid-Scale Storage Projects: Tesla develops massive battery installations including South Australia's Hornsdale Power Reserve providing grid stability services, emergency backup power, and renewable energy integration while demonstrating energy storage technology scalability and economic viability.

Pumped Hydro Storage Systems: Pumped storage facilities including Bath County Station in Virginia provide large-scale energy storage through water pumping during low demand and electricity generation during peak periods while supporting grid stability and renewable energy integration.

Virtual Power Plant Development: Distributed energy resources including residential solar systems, battery storage, and smart devices aggregate into virtual power plants providing grid services while reducing costs and improving system reliability through advanced control systems and market participation.

International Energy Cooperation

International Renewable Energy Agency (IRENA): IRENA facilitates global renewable energy cooperation through technology sharing, capacity building, and policy development while supporting developing countries' clean energy transition and sustainable development throughout comprehensive international frameworks.

International Solar Alliance: Solar Alliance promotes solar energy deployment through financing mechanisms, technology transfer, and capacity building while supporting tropical countries' energy access and sustainable development throughout coordinated international solar development programs.

European Energy Union: European Union develops integrated energy market through infrastructure interconnection, regulatory harmonization, and coordinated planning while supporting renewable energy expansion, energy security, and climate goals throughout regional energy cooperation frameworks.

Clean Energy Ministerial: Global clean energy forum facilitates international cooperation through technology collaboration, policy sharing, and financing coordination while supporting worldwide clean energy deployment and sustainable development throughout ministerial-level engagement and implementation initiatives.

Sophisticated Energy Collocations and Expressions

Technical Energy Terminology

Renewable Energy Technology Collocations:

"photovoltaic efficiency improvements achieving higher solar energy conversion rates"
"offshore wind installations providing substantial electricity generation capacity"
"concentrated solar power systems enabling thermal energy storage capabilities"
"distributed generation resources reducing transmission losses and improving resilience"
"grid-scale energy storage systems supporting renewable energy integration effectively"

Energy System Integration Language:

"smart grid technologies enabling demand response and distributed generation coordination"
"transmission capacity expansion facilitating renewable energy resource access"
"grid modernization programs incorporating advanced digital technologies and automation"
"energy storage deployment addressing renewable energy intermittency challenges"
"system flexibility requirements accommodating variable renewable energy resources"

Power Generation and Efficiency Expressions:

"capacity factor optimization maximizing renewable energy resource utilization"
"energy conversion efficiency improvements reducing fuel consumption and emissions"
"load balancing strategies maintaining electrical grid stability and reliability"
"peak demand management reducing infrastructure requirements and costs"
"baseload power generation providing continuous electricity supply"

Economic and Market Language

Energy Economics Collocations:

"levelized cost of electricity comparing different generation technologies"
"grid parity achievement making renewable energy cost-competitive"
"capital investment requirements for clean energy infrastructure development"
"operational cost advantages of renewable energy systems"
"economic competitiveness driving clean energy market expansion"

Market Transformation Expressions:

"energy market liberalization enabling competition and innovation"
"renewable energy certificates creating market incentives for clean generation"
"capacity markets ensuring adequate generation resources for system reliability"
"power purchase agreements providing long-term energy price stability"
"market mechanisms supporting renewable energy integration and investment"

Financial and Investment Language:

"clean energy investment reaching unprecedented levels globally"
"public-private partnerships financing renewable energy infrastructure projects"
"development finance institutions supporting emerging market energy access"
"green bonds mobilizing capital for sustainable energy development"
"risk mitigation instruments reducing clean energy investment uncertainty"

Policy and Regulatory Expressions

Energy Policy Collocations:

"renewable energy targets establishing clear deployment goals and timelines"
"feed-in tariff systems guaranteeing renewable energy producers fair compensation"
"net metering policies enabling distributed generation economic viability"
"energy efficiency standards reducing consumption while maintaining service levels"
"carbon pricing mechanisms creating economic incentives for clean energy"

Regulatory Framework Language:

"grid codes ensuring renewable energy system compatibility and safety"
"environmental impact assessments evaluating energy project sustainability"
"planning permission processes balancing development with community concerns"
"safety regulations ensuring energy system operation without public harm"
"interconnection standards facilitating distributed generation grid connection"

International Cooperation Expressions:

"technology transfer programs supporting developing country capacity building"
"climate finance mechanisms mobilizing resources for clean energy development"
"multilateral energy initiatives coordinating global transition efforts"
"regional energy integration facilitating cross-border cooperation and trade"
"international standards harmonization reducing trade barriers and costs"

Environmental and Sustainability Language

Environmental Impact Collocations:

"carbon footprint reduction through clean energy deployment and efficiency"
"lifecycle assessment evaluation considering environmental impacts comprehensively"
"air quality improvement eliminating harmful pollutants from energy generation"
"water resource conservation reducing cooling and operational water requirements"
"biodiversity protection ensuring energy development environmental compatibility"

Climate Change and Sustainability Expressions:

"greenhouse gas emissions mitigation achieving climate change targets"
"carbon neutrality goals driving comprehensive energy system transformation"
"climate resilience building ensuring energy system adaptation capabilities"
"sustainable development integration balancing economic and environmental objectives"
"circular economy principles minimizing waste and maximizing resource efficiency"

Resource Management Language:

"critical mineral extraction supporting renewable energy technology manufacturing"
"material recycling programs reducing environmental impacts and resource dependency"
"resource efficiency optimization minimizing material use while maintaining performance"
"sustainable supply chains ensuring responsible energy technology production"
"end-of-life management addressing energy equipment disposal and recycling"

Advanced Energy Argumentation Strategies

Comprehensive Analysis Frameworks

Multi-Dimensional Energy Assessment: Energy analysis requires systematic evaluation across technological, economic, environmental, and social dimensions while recognizing complex interdependencies, regional variations, and temporal considerations throughout comprehensive examination of energy systems, policy frameworks, and implementation strategies requiring advanced analytical sophistication and evidence-based reasoning.

Stakeholder Perspective Integration: Effective energy discourse incorporates diverse stakeholder viewpoints including consumers, utilities, policymakers, environmental advocates, and industry representatives while addressing competing interests, resource constraints, and implementation priorities through balanced analysis recognizing legitimate concerns and opportunities across multiple stakeholder communities.

Systems Thinking Application: Energy system analysis requires understanding complex interactions between generation, transmission, distribution, and consumption while recognizing feedback loops, system constraints, and optimization opportunities throughout comprehensive systems assessment supporting integrated planning and implementation approaches.

Evidence-Based Policy Development: Advanced energy argumentation integrates quantitative data, technical analysis, economic modeling, and policy research while addressing analytical limitations, uncertainty ranges, and implementation challenges throughout comprehensive policy analysis supporting informed decision-making and strategic planning.

Comparative Analysis Techniques

Technology Comparison Frameworks: Comprehensive energy analysis compares renewable technologies, storage systems, and conventional alternatives while evaluating performance characteristics, cost structures, environmental impacts, and deployment potential throughout systematic technology assessment supporting informed technology selection and policy development.

International Best Practice Analysis: Comparative energy policy analysis examines successful implementations across diverse contexts including Denmark's wind development, Costa Rica's renewable achievement, and Germany's energy transition while identifying transferable lessons, contextual adaptation requirements, and implementation success factors.

Economic Analysis Integration: Sophisticated economic evaluation includes direct costs, external benefits, system impacts, and long-term implications while addressing discount rates, risk factors, and distributional effects throughout comprehensive cost-benefit assessment supporting investment decisions and policy development.

Environmental Impact Assessment: Comprehensive environmental analysis includes lifecycle impacts, ecosystem effects, resource consumption, and sustainability considerations while comparing alternatives and identifying mitigation opportunities throughout systematic environmental evaluation supporting sustainable energy development.

Advanced Analytical Applications

Technical Sophistication in Analysis: Energy discourse demands precise technical understanding including system operations, technology capabilities, and performance characteristics while maintaining accessibility through appropriate explanation and context provision throughout professional communication and academic analysis.

Policy Integration Complexity: Advanced policy analysis integrates energy considerations within broader economic, environmental, and social policy frameworks while demonstrating understanding of policy processes, stakeholder dynamics, and implementation challenges throughout comprehensive policy development.

Future-Oriented Strategic Thinking: Sophisticated analysis incorporates emerging trends, technological developments, and changing conditions while addressing uncertainty, adaptation requirements, and long-term planning considerations throughout strategic assessment and policy development.

Evidence Synthesis Capability: Expert-level argumentation seamlessly integrates diverse evidence types including technical specifications, economic data, environmental studies, and policy analysis while addressing source credibility, methodological considerations, and analytical limitations throughout rigorous academic discourse.

Common Energy Question Types and Response Strategies

Two-Part Question Analytical Approaches

Problem and Solution Analysis: Energy Two-Part Questions examining challenges and solutions require systematic analysis of technical barriers, economic constraints, and policy limitations while developing comprehensive interventions including technology development, market mechanisms, and regulatory frameworks addressing identified challenges through coordinated approaches.

Cause and Consequence Analysis: Questions exploring energy transition drivers and impacts require examination of technological advancement, cost reduction, and policy support while analyzing consequences including economic transformation, environmental benefits, and social changes throughout comprehensive cause-effect analytical frameworks.

Current Status and Future Outlook: Analysis combining present energy situation with future projections requires assessment of current renewable deployment, technology costs, and policy frameworks while forecasting technology development, market expansion, and system transformation throughout forward-looking strategic assessment.

Individual and Societal Perspective Analysis: Questions examining personal energy choices and broader societal implications require analysis of consumer decisions including cost considerations, convenience factors, and environmental awareness alongside societal benefits including emissions reduction, energy security, and economic development throughout multi-level analytical frameworks.

Question Development and Response Strategies

Issue Identification and Analysis: Sophisticated energy questions require comprehensive problem identification including technical challenges, economic barriers, social acceptance issues, and policy coordination difficulties while analyzing root causes, contributing factors, and stakeholder perspectives throughout systematic issue examination.

Solution Development and Evaluation: Advanced solution analysis develops specific, practical, and innovative interventions addressing identified challenges while evaluating technical feasibility, economic viability, political acceptability, and implementation timelines throughout comprehensive solution assessment and strategic planning.

Evidence Integration and Support: Expert-level responses integrate diverse evidence types including technical data, economic analysis, environmental research, and policy studies while maintaining source credibility, analytical rigor, and logical coherence throughout comprehensive argumentation development.

Synthesis and Conclusion Development: Comprehensive conclusions integrate key analytical insights while addressing broader implications for energy systems, environmental protection, and economic development while suggesting research needs, policy priorities, and implementation strategies throughout strategic synthesis and future orientation.

Energy Vocabulary Enhancement Strategies

Technical Energy Concepts

Core Energy System Terminology:

Renewable energy: Power generated from naturally replenishing sources including solar, wind, and hydro
Grid integration: Process connecting renewable energy systems to electrical transmission networks
Energy storage: Technologies storing electricity for later use including batteries and pumped hydro
Smart grid: Advanced electrical system using digital technology for efficient operation
Energy efficiency: Reducing energy consumption while maintaining equivalent service levels

Advanced Technology Vocabulary:

Photovoltaic systems: Solar panels converting sunlight directly into electricity
Capacity factor: Ratio of actual energy output to theoretical maximum generation
Intermittency: Variable nature of renewable energy sources depending on weather conditions
Load balancing: Managing electricity supply and demand to maintain grid stability
Distributed generation: Small-scale energy production located close to consumption points

System Operation and Management Terms:

Baseload power: Continuous electricity generation meeting minimum demand requirements
Peak demand: Maximum electricity consumption during high-usage periods
Transmission losses: Energy lost during electricity transport through power lines
Grid stability: Maintaining electrical system frequency and voltage within operational ranges
Demand response: Adjusting electricity consumption patterns to support grid operations

Economic and Policy Language

Energy Economics Terminology:

Levelized cost of electricity (LCOE): Average cost of generating electricity over system lifetime
Grid parity: Point where renewable energy costs equal conventional generation
Energy subsidies: Government financial support for specific energy technologies
Carbon pricing: Economic mechanism assigning costs to greenhouse gas emissions
Energy market liberalization: Introduction of competition in electricity and gas markets

Policy and Regulatory Vocabulary:

Renewable energy targets: Government goals for clean energy deployment percentages
Feed-in tariffs: Guaranteed payments for renewable energy producers
Net metering: System crediting distributed generation for electricity fed into grid
Energy efficiency standards: Requirements for minimum performance levels in equipment
Environmental impact assessment: Evaluation of energy project environmental consequences

Investment and Finance Terms:

Clean energy investment: Capital allocated to renewable energy and efficiency projects
Public-private partnerships: Collaboration between government and private sectors
Green bonds: Financial instruments specifically funding environmental projects
Risk mitigation: Strategies reducing investment uncertainty and financial exposure
Development finance: Funding mechanisms supporting emerging market energy access

Environmental and Sustainability Concepts

Environmental Impact Vocabulary:

Carbon footprint: Greenhouse gas emissions associated with energy production and consumption
Lifecycle assessment: Comprehensive environmental impact evaluation from production to disposal
Emissions factor: Pollutant quantity released per unit of energy produced
Air quality improvement: Reduction in harmful atmospheric pollutants affecting public health
Water footprint: Water consumption associated with energy generation processes

Climate and Sustainability Language:

Climate change mitigation: Actions reducing greenhouse gas emissions and atmospheric concentrations
Carbon neutrality: Balancing emissions produced with equivalent removal or offset
Renewable energy transition: Shift from fossil fuel to clean energy systems
Sustainable development: Meeting present needs without compromising future generations
Circular economy: Economic model emphasizing resource reuse and waste minimization

Resource Management Terms:

Critical minerals: Essential materials for renewable energy technology manufacturing
Resource efficiency: Maximizing output while minimizing input resource consumption
Material recycling: Processing used materials into new products reducing waste
Supply chain sustainability: Ensuring responsible practices throughout production networks
End-of-life management: Handling equipment disposal and material recovery processes

Energy Analysis Practice Framework

Comprehensive Analysis Development

Multi-Perspective Assessment Strategy: Develop systematic approach examining energy from technological, economic, environmental, and social perspectives while recognizing stakeholder diversity, regional contexts, and temporal considerations throughout comprehensive analysis supporting balanced argumentation and informed conclusions.

Technical Understanding Building: Build foundational knowledge of energy technologies, system operations, and performance characteristics through study of technical literature, industry reports, and research publications while developing capability to explain complex concepts clearly and accurately.

Policy Analysis Capability: Develop understanding of energy policy frameworks, regulatory mechanisms, and implementation processes while recognizing political constraints, stakeholder interests, and coordination challenges throughout comprehensive policy analysis and strategic thinking.

Evidence Integration Skills: Build capability integrating quantitative data, research findings, case studies, and expert analysis while evaluating source credibility, methodological rigor, and analytical limitations throughout evidence-based discourse and academic argumentation.

Language Development Approaches

Technical Vocabulary Building: Systematically develop energy terminology through reading industry publications, technical reports, and academic research while practicing technical language integration within academic discourse and professional communication contexts.

Academic Expression Enhancement: Build sophisticated expression capability through analysis of high-quality research papers, policy documents, and expert commentary while practicing advanced grammatical structures and formal register appropriate for academic discourse requirements.

Argumentation Structure Development: Develop clear, logical argumentation patterns including systematic problem analysis, evidence-based reasoning, and comprehensive synthesis while maintaining analytical rigor and professional discourse standards throughout complex topic development.

Professional Communication Skills: Build appropriate language register for technical discourse while practicing formal vocabulary, objective analysis, and precise expression suitable for advanced IELTS Writing Task 2 requirements and professional communication contexts.

Conclusion

Mastering energy topics in IELTS Writing Task 2 Two-Part Questions requires comprehensive integration of technical understanding, economic analysis, environmental awareness, and policy knowledge while demonstrating advanced language skills and analytical sophistication throughout complex discourse demanding expert-level preparation and systematic skill development across multiple knowledge domains essential for achieving excellence.

Energy topic success demands synthesis of technological innovation with practical implementation considerations, individual consumer perspectives with system-wide transformation requirements, and current challenges with future opportunities throughout sophisticated discourse requiring advanced preparation addressing both content mastery and language precision essential for achieving Band 8-9 scores.

Through systematic study of this comprehensive idea bank, advanced example integration, and sophisticated collocation mastery, candidates can develop expert-level energy analysis capability while achieving target band scores through sustained practice and comprehensive preparation throughout IELTS Writing Task 2 excellence requiring deep understanding of energy system complexity and advanced analytical expression.

This energy idea bank demonstrates integration of sophisticated technical content with advanced language applications while maintaining analytical rigor essential for IELTS Writing Task 2 success requiring systematic preparation and comprehensive understanding of energy technologies, policy frameworks, and implementation strategies throughout expert-level analytical development and achievement optimization.

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