Waste to Energy Market Analysis

ID: MRFR/E&P/0861-CR

186 Pages

Chitranshi Jaiswal

July 2025

Waste To Energy Market Research Report Information By Type of Waste (Paper, Wood, Food Waste , Plastics ,Metals, And Others), By Technology (Incineration, Gasification, Pyrolysis), By application (Nasal Allergies, Cold, Asthma, Rhinitis, Sinusitis, Nasal Polyps and Others) , By Application (Electricity Generation, Heat Generation, Transport Fuels, Others) and by Region (North America, Europe, ...

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Summary Table of Contents Segmentation Download PDF

Market Analysis

Waste To Energy (Global, 2025)

Introduction

Waste to Energy (WtE) is becoming an increasingly important part of the world's transition to sustainable waste management and renewable energy. Urbanization continues to accelerate and waste volumes rise. The need for innovation in waste management and energy production becomes ever more urgent. Waste to Energy (WtE) plants convert municipal solid waste into electricity and heat, and are thus not only reducing the impact of burying waste but also contributing to energy security and resource recovery. This report examines the evolving Waste to Energy market, focusing on the regulatory framework, technological developments and public awareness, and examining the challenges and opportunities ahead. WtE is set to transform, reflecting a commitment to sustainable development and the circular economy.

PESTLE Analysis

Political: By 2025, government policy is increasingly in favour of renewable energy sources, including waste-to-energy (WtE) initiatives. In Europe, for example, the EU has set a target of reusing 65% of municipal waste by 2035. This is a direct incentive to WtE plants. Also, in the USA, the government has allocated approximately $1.5 billion to promote the development of WtE technology, which reflects the political will to reduce the amount of waste deposited in landfills and to increase energy production from waste.
Economic: The economic conditions for the waste-to-energy industry in 2025 are favourable. Rising energy prices and the rising costs of traditional waste management favour the waste-to-energy industry. The average cost of electricity produced by waste-to-energy plants is estimated at around 100 cnk/kWh, which is comparable with the cost of electricity from fossil fuels. Waste-to-energy investment is expected to reach 30 billion dollars, as both the public and private sectors seek to invest in sustainable energy solutions and waste management improvements.
Social: In 2025, public awareness and acceptance of waste-to-energy technology is growing, and it is estimated that about 70% of the population in urban areas support the introduction of waste-to-energy plants. Moreover, a public education campaign has been launched, demonstrating the benefits of reducing waste and generating clean energy. The WtE industry is expected to create about 50,000 jobs, contributing to local economies and increasing community involvement in sustainable practices.
Technological: By 2025, the efficiency of waste-to-energy processes will be improved and emissions reduced. Advances in gasification and anaerobic digestion technology are expected to increase the energy recovered by up to 20 per cent. Further, the integration of smart grids into waste-to-energy plants will optimize the distribution of energy. In the first pilot projects, the efficiency of the smart grid has been estimated to be 30 per cent higher.
Legal: In 2025, the regulatory framework for the waste-to-energy industry is tightened by the introduction of new emission standards. For example, the U.S. Environmental Protection Agency (EPA) sets a limit of 1,000 tons per year on the amount of greenhouse gases that can be emitted by a waste-to-energy plant. This means that the operators of waste-to-energy plants have to meet these legal requirements and, in order to comply with them, they have to invest in cleaner technology and monitoring systems.
Environmental: Waste-to-energy plants have an important role to play in 2025, since they reduce the need for land filling and thus lower greenhouse gas emissions. It is estimated that the amount of waste going to the WtE plants will be as much as ninety per cent lower than today, and the amount of methane produced by the decomposition of organic matter will be reduced. In addition, the carbon footprint of the energy produced from waste-to-energy is approximately 50 per cent lower than that of traditional fossil fuels, and this will contribute to the international efforts to combat climate change.

Porter's Five Forces

Threat of New Entrants: The Waste to Energy market in 2025 will be moderately threatened by new entrants. There are significant barriers to entry to this industry, both in terms of capital requirements and regulatory frameworks. However, the growing demand for sustainable energy solutions may lure new entrants. Competition will be strong, as established players will have the advantage of existing technology and customer relationships.
Bargaining Power of Suppliers: The suppliers of waste-to-energy generally have little bargaining power. The industry depends on a wide variety of raw materials, such as waste materials, which are often plentiful and abundant and which come from many suppliers. This limits the influence of a single supplier on prices and conditions and allows companies in the market to negotiate favorable conditions.
Bargaining Power of Buyers: The Waste-to-Energy market is characterized by medium-term buyer power. Municipalities and industries are looking for sustainable waste management solutions, and they have a choice of suppliers. However, the specialized nature of the Waste-to-Energy solutions limits the buyer's options, which reduces their bargaining power.
Threat of Substitutes: The threat of substitutes in the Waste to Energy market is high. The alternative energy sources such as wind, solar and traditional fossil fuels compete strongly. Furthermore, the development of new waste-reduction and recycling methods will further reduce the attractiveness of Waste to Energy solutions as consumers and businesses become more and more interested in sustainable solutions.
Competitive Rivalry: Competition in the waste-to-energy market is expected to be high in 2025. There are many established and new players in the market, and the growth in the market is driven by the increasing importance of both the waste and the green energy sectors. This competition can lead to price wars, technological innovations and aggressive marketing strategies as companies try to differentiate themselves and attract consumers.

SWOT Analysis

Strengths

Reduces landfill waste and promotes sustainable waste management.
Generates renewable energy, contributing to energy security.
Supports circular economy initiatives by converting waste into valuable resources.
Technological advancements improving efficiency and reducing emissions.
Government incentives and policies favoring renewable energy projects.

Weaknesses

High initial capital investment and operational costs.
Public opposition due to perceived environmental risks.
Limited availability of suitable waste feedstock in some regions.
Complex regulatory frameworks and permitting processes.
Technological dependency on specific waste types for optimal energy conversion.

Opportunities

Growing demand for renewable energy sources amid climate change concerns.
Expansion into emerging markets with increasing waste generation.
Partnerships with municipalities for integrated waste management solutions.
Innovations in waste sorting and processing technologies.
Potential for carbon credits and other environmental financial incentives.

Threats

Competition from other renewable energy sources like solar and wind.
Economic downturns affecting investment in infrastructure projects.
Changing regulations and policies that may impact operational viability.
Public perception and misinformation about waste-to-energy processes.
Technological failures or inefficiencies leading to financial losses.

Summary

Waste to Energy (WtE) in 2025 is characterized by its strengths in terms of reducing waste and generating energy, but faces challenges in the form of high costs and public opposition. Opportunities to grow are seen in emerging markets and technological development. Threats are seen in competition and regulatory changes. The strategic focus on innovation, public education and collaboration is crucial for the exploitation of strengths and opportunities and the mitigation of weaknesses and threats.

1. Market Overview

2. Market Trends

3. Market Segment Insights

4. Key Players and Competitive Insights

5. Industry Developments

6. Market Segmentation

7. Report Scope

8. Market Highlights

9. FAQs

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Market Summary

As per Market Research Future Analysis, the Global Waste-to-Energy Market was valued at USD 47.34 million in 2025 and is projected to reach USD 62.17 million by 2035, growing at a CAGR of 4.76% from 2025 to 2035. The increasing waste pileup, driven by population growth, urbanization, and industrialization, is propelling the demand for waste-to-energy solutions. Waste-to-energy technologies, including incineration, gasification, and pyrolysis, convert waste into energy while addressing environmental concerns. The Asia-Pacific region holds the largest market share, with significant investments in waste-to-energy infrastructure and supportive government policies.

Key Market Trends & Highlights

Key trends driving the Waste-to-Energy market include increasing waste generation and technological advancements.

Projected municipal waste to reach 3.4 billion tons by 2050 due to urbanization and economic development. Food Waste segment held the largest market share in 2022, emphasizing eco-friendly energy production. Incineration technology dominated the market in 2022, significantly reducing waste volume while generating energy. Electricity Generation application is expected to register the highest growth rate during the forecast period.

Waste to Energy Market

CAGR

4.76%

Market Size & Forecast

2024 Market Size	USD 37.27 Billion
2035 Market Size	USD 62.17 million
CAGR	4.76%
Largest Regional Market	Asia-Pacific.

Major Players

Key companies include Veolia, Babcock & Wilcox Enterprises, Arrow Ecology Ltd., Axpo Holding AG, Biogen LTD, and Hitachi Zosen Inova AG.

Market Trends

DIGITALIZATION IN WASTE MANAGEMENT TECHNIQUES TO SPUR MARKET

The growing trend of digitalization in waste management presents a significant opportunity for the global Waste-to-Energy (WTE) market. As digital technologies like Internet of Things (IoT), artificial intelligence (AI), big data analytics, and automation continue to evolve, they offer new ways to optimize waste management processes and enhance the efficiency of WTE systems. Digitalization allows for more precise monitoring, real-time tracking of waste streams, predictive maintenance, and better decision-making, all of which contribute to lowering costs and improving the performance of WTE plants.

These advancements can enable WTE facilities to operate more effectively, process a wider variety of waste types, and increase energy recovery rates, leading to significant growth in the market.

The transition towards sustainable waste management practices, particularly through the adoption of waste-to-energy technologies, appears to be gaining momentum as municipalities seek innovative solutions to address both waste disposal challenges and energy demands.

U.S. Environmental Protection Agency

Waste to Energy Market Market Drivers

Increasing Energy Demand

The Global Waste To Energy Market Industry is experiencing a surge in demand for energy, driven by the growing population and urbanization. As cities expand, the need for sustainable energy sources becomes more pressing. In 2024, the market is projected to reach 44.5 USD Million, reflecting a shift towards renewable energy solutions. Waste to energy technologies offer a dual benefit of waste management and energy production, making them attractive to governments and private sectors alike. This trend is expected to continue, as energy consumption is anticipated to rise significantly, necessitating innovative solutions to meet future energy needs.

Market Growth Projections

Technological Advancements

Technological innovation is a key driver of the Global Waste To Energy Market Industry. Advances in waste processing technologies, such as anaerobic digestion and gasification, enhance the efficiency of converting waste into energy. These technologies not only improve energy output but also reduce emissions, aligning with global sustainability goals. As these technologies become more commercially viable, they attract investment and drive market growth. The anticipated compound annual growth rate of 7.15% from 2025 to 2035 indicates a robust future for the industry, as stakeholders seek to leverage these advancements for cleaner energy production.

Government Policies and Regulations

Government initiatives play a crucial role in shaping the Global Waste To Energy Market Industry. Many countries are implementing stringent regulations aimed at reducing landfill waste and promoting renewable energy sources. Policies that incentivize waste-to-energy projects, such as tax breaks or subsidies, encourage investment in this sector. For instance, various nations have set ambitious targets for waste reduction and renewable energy generation, which could lead to a market growth trajectory that reaches 95.2 USD Million by 2035. These regulatory frameworks not only facilitate the development of waste-to-energy facilities but also enhance public awareness of sustainable practices.

Economic Benefits of Waste to Energy

The economic advantages associated with the Global Waste To Energy Market Industry are becoming increasingly apparent. Waste-to-energy facilities not only generate energy but also create jobs and stimulate local economies. By converting waste into a resource, these facilities can reduce the costs associated with waste disposal while providing a renewable energy source. This dual economic benefit is particularly appealing to municipalities facing budget constraints. As the market evolves, the financial viability of waste-to-energy projects is expected to improve, attracting further investment and leading to a more sustainable economic model for waste management and energy production.

Public Awareness and Environmental Concerns

Increasing public awareness regarding environmental issues is significantly influencing the Global Waste To Energy Market Industry. As communities become more conscious of waste management and its impact on climate change, there is a growing demand for sustainable waste disposal methods. Waste to energy solutions are viewed as a viable alternative to traditional landfill practices, which are often criticized for their environmental footprint. This shift in public perception is likely to drive investments and policy support for waste-to-energy projects, further propelling market growth. The alignment of public sentiment with environmental sustainability goals is expected to foster a favorable landscape for the industry.

Market Segment Insights

Waste To Energy By Type Of Waste Insights

Based on type of waste, the waste to energy market is segmented into: Paper, Wood, Food Waste, Plastics, Metals, Others. The Food Waste segment dominated the global market in 2024, while the Paper is projected to be the fastest–growing segment during the forecast period.

Food waste, which includes leftovers, expired items, and organic waste, is a growing challenge worldwide. However, food waste is a valuable resource for WTE technologies like anaerobic digestion, which converts organic material into <a href="https://www.marketresearchfuture.com/reports/organic-bioga-market-28857">biogas </a>(mainly methane), a renewable energy source. Food waste can also be processed through composting and incineration to produce energy. The environmental benefits of using food waste for energy are significant as it helps reduce greenhouse gas emissions from landfills, where food waste would otherwise decompose anaerobically and release methane. As food waste generation continues to increase globally, its role in WTE will become more critical.

Waste To Energy By Technology Insights

Based on technology, the waste to energy market is segmented into: Incineration, Gasification, Pyrolysis. The Incineration segment dominated the global market in 2024, while the Incineration is projected to be the fastest–growing segment during the forecast period.

Incineration is the most widely used Waste to Energy (WTE) technology, involving the combustion of solid waste at high temperatures to generate heat, which is then used to produce steam and drive turbines to generate electricity. The process significantly reduces the volume of waste, typically by 80-90%, and can also be used for district heating. While incineration is a mature and proven technology, it has been met with environmental concerns, especially related to air pollution and the release of toxic emissions, such as dioxins and furans, unless properly controlled.

However, advancements in flue gas cleaning and pollution control systems have helped mitigate these concerns, making incineration an important part of the WTE landscape, especially in regions like Europe, where strict regulations are in place.

Waste To Energy By Application Insights

Based on application, the waste to energy market is segmented into: Electricity Generation, Heat Generation, Transport Fuels, Others. The Electricity Generation segment dominated the global market in 2024, while the Heat Generation the Counter is projected to be the fastest–growing segment during the forecast period.

Electricity generation is the most common and widespread application of Waste to Energy (WTE) technologies. In this process, waste materials such as municipal solid waste (MSW), <a href="https://www.marketresearchfuture.com/reports/biomass-gasification-market-7313">biomass</a>, and other organic materials are incinerated, gasified, or processed through anaerobic digestion to produce heat, which is used to generate steam. This steam drives turbines that generate electricity. WTE plants focused on electricity generation are often integrated into local or national energy grids, contributing to renewable energy portfolios. This application not only helps reduce landfill waste but also provides a reliable and consistent source of energy.

As a renewable energy source, WTE plants that generate electricity are increasingly seen as an important solution to reducing dependence on fossil fuels while tackling waste management challenges.

Get more detailed insights about Waste To Energy Market Research Report – Forecast till 2035

Regional Insights

Key Companies in the Waste to Energy Market market include

Industry Developments

Q3 2024: Dubai launches world’s largest waste-to-energy plant Dubai inaugurated the world’s largest waste-to-energy plant in July 2024, designed to process 1.9 million tonnes of waste annually and generate 200 megawatts of electricity, as part of the city’s sustainability and clean energy goals.
Q3 2024: Veolia and EDF sign partnership to develop waste-to-energy projects in Europe Veolia and EDF announced a strategic partnership in July 2024 to jointly develop new waste-to-energy facilities across several European countries, aiming to accelerate the transition to circular energy solutions.
Q2 2024: Covanta Announces Opening of New Waste-to-Energy Facility in Ireland Covanta opened a new waste-to-energy facility in Dublin in May 2024, with the plant expected to process 600,000 tonnes of municipal solid waste per year and supply electricity to over 80,000 homes.
Q2 2024: Hitachi Zosen Inova Wins Contract for Waste-to-Energy Plant in Taiwan Hitachi Zosen Inova secured a contract in April 2024 to design and build a new waste-to-energy facility in Taoyuan, Taiwan, which will process 400,000 tonnes of waste annually and generate 45 megawatts of power.
Q2 2024: Ramky Enviro Engineers commissions waste-to-energy plant in Hyderabad Ramky Enviro Engineers commissioned a new waste-to-energy plant in Hyderabad, India, in June 2024, with a capacity to process 1,200 tonnes of waste per day and generate 19 megawatts of electricity.
Q2 2024: Singapore’s Tuas Nexus waste-to-energy facility begins operations Singapore’s Tuas Nexus, a large-scale integrated waste management and energy facility, began operations in May 2024, processing up to 2,900 tonnes of waste daily and generating electricity for the national grid.
Q3 2024: JFE Engineering to build new waste-to-energy plant in Vietnam JFE Engineering announced in July 2024 that it will construct a new waste-to-energy plant in Ho Chi Minh City, Vietnam, with a planned capacity of 500,000 tonnes per year and expected completion in 2026.
Q2 2024: Varme Energy receives $2.04 million investment for Canada’s first carbon-capture-ready waste-to-energy plant In May 2024, Emissions Reduction Alberta invested $2.04 million in Varme Energy’s front-end engineering and design study for a large-scale, carbon-capture-ready waste-to-energy plant, aiming to process municipal solid waste and capture 185,000 tonnes of CO2 annually.
Q2 2024: Biffa and Covanta sign agreement to develop new waste-to-energy facility in UK Biffa and Covanta signed an agreement in April 2024 to jointly develop a new waste-to-energy facility in the UK, targeting the processing of 350,000 tonnes of residual waste per year.
Q2 2024: EverEnviro Resource Management secures $50 million funding for waste-to-energy expansion EverEnviro Resource Management raised $50 million in Series B funding in June 2024 to expand its waste-to-energy operations across multiple Indian cities.
Q2 2024: JSW Energy acquires Mytrah Energy’s waste-to-energy assets JSW Energy completed the acquisition of Mytrah Energy’s waste-to-energy assets in May 2024, strengthening its renewable energy portfolio in India.
Q2 2024: Indaver opens new waste-to-energy facility in Meath Indaver opened a new waste-to-energy facility in Meath, Ireland, in April 2024, with the plant capable of processing 200,000 tonnes of waste annually and generating electricity for 20,000 homes.

Future Outlook

Waste to Energy Market Future Outlook

The Global Waste To Energy Market is projected to grow at a 4.76% CAGR from 2025 to 2035, driven by increasing energy demand, regulatory support, and technological advancements.

New opportunities lie in:

Invest in advanced anaerobic digestion technologies to enhance biogas production efficiency. Develop partnerships with municipalities for integrated waste management solutions. Explore emerging markets in developing regions for waste-to-energy project implementation.

By 2035, the market is expected to be robust, reflecting substantial growth and innovation.

Market Segmentation

Regional Outlook

{"North America"=>["US"
"Canada"
"Mexico"]}
{"Europe"=>["Germany"
"Italy"
"France"
"UK"
"Spain"
"Russia"
"Rest of Europe"]}
{"Asia-Pacific"=>["China"
"India"
"Japan"
"South Korea"
"Rest of APAC"]}
{"South America"=>["Brazil"
"Argentina"
"Rest of South America"]}
{"Middle East"=>["GCC Countries"
"South Africa"
"Rest of MEA"]}

Global Waste To Energy Regional Outlook

{"North America"=>["US"
"Canada"
"Mexico"]}
{"Europe"=>["Germany"
"Italy"
"France"
"UK"
"Spain"
"Russia"
"Rest of Europe"]}
{"Asia-Pacific"=>["China"
"India"
"Japan"
"South Korea"
"Rest of APAC"]}
{"South America"=>["Brazil"
"Argentina"
"Rest of South America"]}
{"Middle East"=>["GCC Countries"
"South Africa"
"Rest of MEA"]}

Waste To Energy Market By Technology Outlook (USD MILLION, 2019-2035)

Incineration
Gasification
Pyrolysis

Waste To Energy Market By Application Outlook (USD MILLION, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Waste To Energy Market By Type of Waste Outlook (USD MILLION, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Report Scope

Report Attribute/Metric	Details
Market Size 2024	USD 44.53 MILLION
Market Size 2025	USD 47.34 MILLION
Market Size 2035	62.17 (Value (USD MILLION))
Compound Annual Growth Rate (CAGR)	4.76% (2025 - 2035)
Base Year	2024
Market Forecast Period	2025 - 2035
Historical Data	2019- 2023
Market Forecast Units	Value (USD MILLION)
Report Coverage	Revenue Forecast, Market Competitive Landscape, Growth Factors, and Trends
Segments Covered	By Type of Waste, By Technology, By Application
Geographies Covered	North America, Europe, Asia-Pacific, South America, Middle East & Africa.
Countries Covered	the U.S., Canada, Mexico, Germany, Italy, France , UK ,Spain, Russia, Rest of Europe, China, India, Japan, South Korea, Rest of APAC , Brazil, Argentina, Rest of South America, GCC Countries, South Africa, Rest of MEA.
Key Companies Profiled	Arrow Ecology, AXPO Holding Ag, Biogen, BLUEFIRE Renewables, BTA International GMBH, Ramboll, Emery Energy Company, GEOCYCLE, Viridor, VLS Environmental Solutions, KANADEVIA Inova, REWORLD, Enercon, Babcock & Wilcox , Veolia , And Among Others
Key Market Opportunities	· Digitalization In Waste Management Techniques To Spur Market · Rising Energy Demand
Key Market Dynamics	· Growing Concern For Waste Management To Meet The Needs For Sustainable Urban Living · Increasing Focus On Non-Fossil Fuel Sources Of Energy

Market Highlights

Author

Chitranshi Jaiswal

Research Analyst Level I

She holds an experience of about 6+ years in market research and business consulting, working under the spectrum of information communication technology, telecommunications and semiconductor domains. aarti conceptualizes and implements a scalable business strategy and provides strategic leadership to the clients. her expertise lies in market estimation, competitive intelligence, pipeline analysis, customer assessment, etc.

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FAQs

How much is the Waste To Energy Market?

The Waste To Energy Market size is expected to be valued at USD 95.19 MILLION in 2035.

What is the growth rate of the Waste To Energy Market?

The global market is projected to grow at a CAGR of 7.2% during the forecast period, 2024-2035.

Which region held the largest market share in the Waste To Energy Market?

Asia Pacific had the largest share of the global market.

Who are the key players in the Waste To Energy Market?

The key players in the market are Astec Industries Arrow Ecology, AXPO Holding Ag, Biogen, BLUEFIRE Renewables, BTA International GMBH, Ramboll, Emery Energy Company, GEOCYCLE, Viridor, VLS Environmental Solutions, KANADEVIA Inova, REWORLD, Enercon, Babcock & Wilcox , Veolia , And Among Others.

Which Application led the Waste To Energy Market?

Electricity Generation dominated the market in 2024.

Which Technology had the largest market share in the Waste To Energy Market?

Incineration segment had the largest revenue share of the global market.

--- "Table of Contents
Executive Summary
Market Introduction
1. DEFINITION
2. Scope of the Study
3. RESEARCH OBJECTIVE
4. MARKET STRUCTURE
Research Methodology
1. OVERVIEW
2. DATA FLOW
  1. Data Mining Process
3. PURCHASED DATABASE:
4. SECONDARY SOURCES:
  1. Secondary Research data flow:
5. PRIMARY RESEARCH:
  1. Primary Research DATA FLOW:
  2. Primary Research: Number of Interviews conducted
  3. Primary Research: Regional Coverage
6. APPROACHES FOR MARKET SIZE ESTIMATION:
  1. trade Analysis Approach
7. DATA FORECASTING
  1. Data forecasting Technique
8. DATA MODELING
  1. microeconomic factor analysis:
  2. Data modeling:
9. TEAMS AND ANALYST CONTRIBUTION
MARKET DYNAMICS
1. INTRODUCTION
2. DRIVERS
  1. Increasing Waste Pileup
  2. Growing concern for waste management to meet the needs for sustainable urban living
  3. Increasing focus on non-fossil fuel sources of energy
  4. Increase in production of clean energy from waste drives market growth
3. RESTRAINT
  1. Varying composition of waste streams
  2. High cost associated with waste to energy
4. OPPORTUNITY
  1. Digitalization in waste management techniques to spur market
  2. Rising Energy Demand
5. IMPACT ANALYSIS OF COVID-19
  1. Impact on Supply Chain of Waste-to-energy
  2. Impact on Market Demand for Waste-to-energy
MARKET FACTOR ANALYSIS
1. SUPPLY/VALUE CHAIN ANALYSIS
  1. Waste Collection & Sorting
  2. Waste Processing and Pre-treatment
  3. Energy Conversion
  4. Energy Distribution & Storage
  5. End-Users
2. PORTER’S FIVE FORCES MODEL
  1. THREAT OF NEW ENTRANTS
  2. BARGAINING POWER OF SUPPLIERS
  3. THREAT OF SUBSTITUTES
  4. BARGAINING POWER OF BUYERS
  5. Intensity of RIVALRY
3. TECHNOLOGICAL ADVANCEMENTS
  1. Emerging technologies for waste to energy
  2. Current Utility Scale Plants
  3. Government initiatives for Renewable Energy from Waste
  4. New developments in sustainable waste-to-energy systems
4. R&D UPDATE
  1. Current Scenario
  2. Future Roadmap
  3. Novel Applications
  4. Key Developments
5. REGULATORY FRAMEWORK
  1. Government Policies
  2. Environmental Regulations
  3. Regulations and Compliance in Waste Management
  4. Patent Analysis
GLOBAL WASTE TO ENERGY MARKET, BY TYPE OF WASTE
1. OVERVIEW
2. PAPER
3. WOOD
4. FOOD WASTE
5. PLASTICS
6. METALS
7. OTHERS
GLOBAL WASTE TO ENERGY MARKET, BY TECHNOLOGY
1. OVERVIEW
2. INCINERATION
3. GASIFICATION
4. PYROLYSIS
GLOBAL WASTE TO ENERGY MARKET, BY APPLICATION
1. OVERVIEW
2. ELECTRICITY GENERATION
3. HEAT GENERATION
4. TRANSPORT FUELS
5. OTHERS
GLOBAL WASTE TO ENERGY MARKET, BY REGION
1. INTRODUCTION
2. REGIONAL ANALYSIS BY COUNTRY
  1. NORTH AMERICA
  2. europe
  3. asia pacific
  4. south america
  5. middle east & africa
Competitive Landscape
1. INTRODUCTION
2. COMPETITION DASHBOARD
3. COMPETITIVE BENCHMARKING
4. MARKET SHARE ANALYSIS, 2024
5. LEADING PLAYER IN TERMS OF NUMBER OF DEVELOPMENTS IN THE GLOBAL WASTE-TO-ENERGY MARKET
6. COMPARATIVE ANALYSIS: KEY PLAYERS FINANCIAL
7. KEY DEVELOPMENTS & GROWTH STRATEGIES
  1. Business Investment, agreement, partnership & expansion
  2. Acquisition
COMPANY PROFILES
1. ARROW ECOLOGY
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
2. AXPO HOLDING AG
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
3. BIOGEN
  1. Company Overview
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERED
  4. KEY DEVELOPMENTS
  5. SWOT Analysis
  6. Key Strategy
4. BLUEFIRE RENEWABLES
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
5. BTA INTERNATIONAL GMBH
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
6. RAMBOLL
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
7. EMERY ENERGY COMPANY
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
8. GEOCYCLE
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
9. VIRIDOR
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
10. VLS ENVIRONMENTAL SOLUTIONS
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
11. KANADEVIA INOVA
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
12. REWORLD
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
13. ENERCON
  1. Company Overview
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERED
  4. KEY DEVELOPMENTS
  5. SWOT Analysis
  6. Key Strategy
14. BABCOCK & WILCOX
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
15. VEOLIA
  1. COMPANY OVERVIEW
  2. FINANCIAL OVERVIEW
  3. PRODUCTS OFFERed
  4. KEY DEVELOPMENTS
  5. SWOT ANALYSIS
  6. Key Strategy
16. DATA CITATIONS
List of Tables and Figures
1. LIST OF TABLES
2. TABLE 1 QFD MODELING FOR MARKET SHARE ASSESSMENT
3. TABLE 2 GLOBAL WASTE TO ENERGY MARKET, ESTIMATES & FORECAST BY TYPE OF WASTE, 2019–2035 (USD BILLION)
4. TABLE 3 GLOBAL WASTE TO ENERGY MARKET ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
5. TABLE 4 WASTE TO ENERGY MARKET ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
6. TABLE 5 WASTE TO ENERGY MARKET ESTIMATES & FORECAST, BY REGION, 2019–2035 (USD BILLION)
7. TABLE 6 NORTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY COUNTRY, 2019–2035 (USD BILLION)
8. TABLE 7 NORTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
9. TABLE 8 NORTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
10. TABLE 9 NORTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
11. TABLE 10 US WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
12. TABLE 11 US WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
13. TABLE 12 US WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
14. TABLE 13 CANADA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
15. TABLE 14 CANADA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
16. TABLE 15 CANADA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
17. TABLE 16 MEXICO WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
18. TABLE 17 MEXICO WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
19. TABLE 18 MEXICO WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
20. TABLE 19 EUROPE WASTE TO ENERGY ESTIMATES & FORECAST, BY COUNTRY, 2019–2035 (USD BILLION)
21. TABLE 20 EUROPE WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
22. TABLE 21 EUROPE WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
23. TABLE 22 EUROPE WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
24. TABLE 23 GERMANY WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
25. TABLE 24 GERMANY WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
26. TABLE 25 GERMANY WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
27. TABLE 26 ITALY WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
28. TABLE 27 ITALY WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
29. TABLE 28 ITALY WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
30. TABLE 29 FRANCE WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
31. TABLE 30 FRANCE WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
32. TABLE 31 FRANCE WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
33. TABLE 32 UK WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
34. TABLE 33 UK WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
35. TABLE 34 UK WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
36. TABLE 35 SPAIN WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
37. TABLE 36 SPAIN WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
38. TABLE 37 SPAIN WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
39. TABLE 38 RUSSIA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
40. TABLE 39 RUSSIA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
41. TABLE 40 RUSSIA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
42. TABLE 41 REST OF EUROPE WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
43. TABLE 42 REST OF EUROPE WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
44. TABLE 43 REST OF EUROPE WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
45. TABLE 44 ASIA PACIFIC WASTE TO ENERGY ESTIMATES & FORECAST, BY COUNTRY, 2019–2035 (USD BILLION)
46. TABLE 45 ASIA PACIFIC WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
47. TABLE 46 ASIA PACIFIC WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
48. TABLE 47 ASIA PACIFIC WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
49. TABLE 48 CHINA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
50. TABLE 49 CHINA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
51. TABLE 50 CHINA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
52. TABLE 51 INDIA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
53. TABLE 52 INDIA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
54. TABLE 53 INDIA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
55. TABLE 54 JAPAN WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
56. TABLE 55 JAPAN WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
57. TABLE 56 JAPAN WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
58. TABLE 57 SOUTH KOREA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
59. TABLE 58 SOUTH KOREA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
60. TABLE 59 SOUTH KOREA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
61. TABLE 60 REST OF APAC WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
62. TABLE 61 REST OF APAC WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
63. TABLE 62 REST OF APAC WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
64. TABLE 63 SOUTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY COUNTRY, 2019–2035 (USD BILLION)
65. TABLE 64 SOUTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
66. TABLE 65 SOUTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
67. TABLE 66 SOUTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
68. TABLE 67 BRAZIL WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
69. TABLE 68 BRAZIL WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
70. TABLE 69 BRAZIL WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
71. TABLE 70 ARGENTINA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
72. TABLE 71 ARGENTINA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
73. TABLE 72 ARGENTINA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
74. TABLE 73 REST OF SOUTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
75. TABLE 74 REST OF SOUTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
76. TABLE 75 REST OF SOUTH AMERICA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
77. TABLE 76 MIDDLE EAST & AFRICA WASTE TO ENERGY ESTIMATES & FORECAST, BY COUNTRY, 2019–2035 (USD BILLION)
78. TABLE 77 MIDDLE EAST & AFRICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
79. TABLE 78 MIDDLE EAST & AFRICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
80. TABLE 79 MIDDLE EAST & AFRICA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
81. TABLE 80 GCC COUNTRIES WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
82. TABLE 81 GCC COUNTRIES WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
83. TABLE 82 GCC COUNTRIES WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
84. TABLE 83 SOUTH AFRICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
85. TABLE 84 SOUTH AFRICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
86. TABLE 85 SOUTH AFRICA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
87. TABLE 86 REST OF MIDDLE EAST & AFRICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TYPE OF WASTE, 2019–2035 (USD BILLION)
88. TABLE 87 REST OF MIDDLE EAST & AFRICA WASTE TO ENERGY ESTIMATES & FORECAST, BY TECHNOLOGY, 2019–2035 (USD BILLION)
89. TABLE 88 REST OF MIDDLE EAST & AFRICA WASTE TO ENERGY ESTIMATES & FORECAST, BY APPLICATION, 2019–2035 (USD BILLION)
90. TABLE 89 COMPETITION DASHBOARD: GLOBAL WASTE-TO-ENERGY MARKET
91. TABLE 90 COMPARATIVE ANALYSIS: KEY PLAYERS FINANCIAL
92. TABLE 91 BUSINESS INVESTMENT, AGREEMENT, PARTNERSHIP & EXPANSION
93. TABLE 92 ACQUISITION
94. TABLE 93 ARROW ECOLOGY: PRODUCTS OFFERED
95. TABLE 94 AXPO HOLDING AG: PRODUCTS OFFERED
96. TABLE 95 AXPO HOLDING AG: KEY DEVELOPMENTS
97. TABLE 96 BIOGEN: PRODUCTS OFFERED
98. TABLE 97 BLUEFIRE RENEWABLES: PRODUCTS OFFERED
99. TABLE 98 BTA INTERNATIONAL GMBH: PRODUCTS OFFERED
100. TABLE 99 RAMBOLL: PRODUCTS OFFERED
101. TABLE 100 RAMBOLL: KEY DEVELOPMENTS
102. TABLE 101 EMERY ENERGY COMPANY: PRODUCTS OFFERED
103. TABLE 102 GEOCYCLE (PARENT: HOLCIM GROUP): FINANCIAL OVERVIEW
104. TABLE 103 GEOCYCLE: PRODUCTS OFFERED
105. TABLE 104 GEOCYCLE: KEY DEVELOPMENTS
106. TABLE 105 VIRIDOR: PRODUCTS OFFERED
107. TABLE 106 VIRIDOR: KEY DEVELOPMENTS
108. TABLE 107 VLS ENVIRONMENTAL SOLUTIONS: PRODUCTS OFFERED
109. TABLE 108 VLS ENVIRONMENTAL SOLUTIONS: KEY DEVELOPMENTS
110. TABLE 109 KANADEVIA INOVA: PRODUCTS OFFERED
111. TABLE 110 KANADEVIA INOVA: KEY DEVELOPMENTS
112. TABLE 111 REWORLD: PRODUCTS OFFERED
113. TABLE 112 REWORLD: KEY DEVELOPMENTS
114. TABLE 113 ENERCON: PRODUCTS OFFERED
115. TABLE 114 BABCOCK & WILCOX: PRODUCTS OFFERED
116. TABLE 115 BABCOCK & WILCOX: KEY DEVELOPMENTS
117. TABLE 116 VEOLIA: PRODUCTS OFFERED
118. TABLE 117 VEOLIA: KEY DEVELOPMENTS LIST OF FIGURES
119. FIGURE 1 GLOBAL WASTE TO ENERGY MARKET (BY REGION), 2024
120. FIGURE 2 GLOBAL WASTE TO ENERGY MARKET SNAPSHOT, 2024
121. FIGURE 3 GLOBAL WASTE TO ENERGY MARKET: STRUCTURE
122. FIGURE 4 GLOBAL WASTE TO ENERGY MARKET: MARKET GROWTH FACTOR ANALYSIS (2019-2035)
123. FIGURE 5 UNITED STATES: POPULATION GROWTH FROM 2018 TO 2023 (COMPARED TO THE PREVIOUS YEAR)
124. FIGURE 6 DRIVER IMPACT ANALYSIS (2025-2035)
125. FIGURE 7 CHALLENGE IMPACT ANALYSIS (2025-2035)
126. FIGURE 8 DEGREE OF URBANIZATION IN CHINA IN SELECTED YEARS FROM 2018 TO 2024
127. FIGURE 9 SUPPLY CHAIN: GLOBAL WASTE TO ENERGY MARKET
128. FIGURE 10 Porter's Five Forces Analysis OF THE WASTE TO ENERGY MARKET
129. FIGURE 11 GRANTED PATENT ANALYSIS OF GLOBAL WASTE TO ENERGY MARKET
130. FIGURE 12 GLOBAL WASTE TO ENERGY MARKET ESTIMATES & FORECAST, BY TYPE OF WASTE, 2024 (% SHARE)
131. FIGURE 13 GLOBAL WASTE TO ENERGY MARKET, BY TECHNOLOGY, 2024 (% SHARE)
132. FIGURE 14 WASTE TO ENERGY MARKET ESTIMATES & FORECAST, BY APPLICATION, 2024 (% SHARE)
133. FIGURE 15 COMPETITIVE BENCHMARKING: GLOBAL WASTE-TO-ENERGY MARKET
134. FIGURE 16 MAJOR PLAYERS MARKET SHARE ANALYSIS, 2024 (%)
135. FIGURE 17 LEADING PLAYER IN TERMS OF NUMBER OF DEVELOPMENTS IN THE GLOBAL WASTE-TO-ENERGY MARKET
136. FIGURE 18 ARROW ECOLOGY: SWOT ANALYSIS
137. FIGURE 19 AXPO HOLDING AG: FINANCIAL OVERVIEW SNAPSHOT
138. FIGURE 20 AXPO HOLDING AG: SWOT ANALYSIS
139. FIGURE 21 BIOGEN: SWOT ANALYSIS
140. FIGURE 22 BLUEFIRE RENEWABLES: SWOT ANALYSIS
141. FIGURE 23 BTA INTERNATIONAL GMBH: SWOT ANALYSIS
142. FIGURE 24 RAMBOLL: FINANCIAL OVERVIEW SNAPSHOT
143. FIGURE 25 RAMBOLL: SWOT ANALYSIS
144. FIGURE 26 EMERY ENERGY COMPANY: SWOT ANALYSIS
145. FIGURE 27 GEOCYCLE: SWOT ANALYSIS
146. FIGURE 28 VIRIDOR: ANALYSIS
147. FIGURE 29 VLS ENVIRONMENTAL SOLUTIONS: SWOT ANALYSIS
148. FIGURE 30 KANADEVIA INOVA (PARENT COMPANY: KANADEVIA): FINANCIAL OVERVIEW SNAPSHOT
149. FIGURE 31 KANADEVIA INOVA: SWOT ANALYSIS
150. FIGURE 32 REWORLD: SWOT ANALYSIS
151. FIGURE 33 ENERCON: SWOT ANALYSIS
152. FIGURE 34 BABCOCK & WILCOX: FINANCIAL OVERVIEW SNAPSHOT
153. FIGURE 35 BABCOCK & WILCOX: SWOT ANALYSIS
154. FIGURE 36 VEOLIA: FINANCIAL OVERVIEW SNAPSHOT
155. FIGURE 37 VEOLIA: SWOT ANALYSIS "

Global Outlook (US$ Billion, 2019-2035)

Global Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Global Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Global Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

North America Outlook (US$ Billion, 2019-2035)

North America Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

North America Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

North America Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

US Outlook (US$ Billion, 2019-2035)

US Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

US Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

US Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Canada Outlook (US$ Billion, 2019-2035)

Canada Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Canada Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Canada Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Mexico Outlook (US$ Billion, 2019-2035)

Mexico Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Mexico Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Mexico Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Europe Outlook (US$ Billion, 2019-2035)

Europe Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Europe Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Europe Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Germany Outlook (US$ Billion, 2019-2035)

Germany Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Germany Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Germany Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Italy Outlook (US$ Billion, 2019-2035)

Italy Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Italy Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Italy Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

France Outlook (US$ Billion, 2019-2035)

France Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

France Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

France Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

UK Outlook (US$ Billion, 2019-2035)

UK Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

UK Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

UK Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Spain Outlook (US$ Billion, 2019-2035)

Spain Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Spain Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Spain Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Russia Outlook (US$ Billion, 2019-2035)

Russia Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Russia Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Russia Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Rest of Europe Outlook (US$ Billion, 2019-2035)

Rest of Europe Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Rest of Europe Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Rest of Europe Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Asia Pacific Outlook (US$ Billion, 2019-2035)

Asia Pacific Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Asia Pacific Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Asia Pacific Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

China Outlook (US$ Billion, 2019-2035)

China Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

China Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

China Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

India Outlook (US$ Billion, 2019-2035)

India Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

India Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

India Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Japan Outlook (US$ Billion, 2019-2035)

Japan Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Japan Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Japan Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

South Korea Outlook (US$ Billion, 2019-2035)

South Korea Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

South Korea Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

South Korea Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Rest of APAC Outlook (US$ Billion, 2019-2035)

Rest of APAC Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Rest of APAC Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Rest of APAC Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

South America Outlook (US$ Billion, 2019-2035)

South America Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

South America Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

South America Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Brazil Outlook (US$ Billion, 2019-2035)

Brazil Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Brazil Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Brazil Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Argentina Outlook (US$ Billion, 2019-2035)

Argentina Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Argentina Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Argentina Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Rest of South America Outlook (US$ Billion, 2019-2035)

Rest of South America Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Rest of South America Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Rest of South America Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Middle East & Africa Outlook (US$ Billion, 2019-2035)

Middle East & Africa Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Middle East & Africa Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Middle East & Africa Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

GCC Countries Outlook (US$ Billion, 2019-2035)

GCC Countries Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

GCC Countries Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

GCC Countries Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

South Africa Outlook (US$ Billion, 2019-2035)

South Africa Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

South Africa Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

South Africa Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

Rest of MEA Outlook (US$ Billion, 2019-2035)

Rest of MEA Waste to Energy, Type of Waste (US$ Billion, 2019-2035)

Paper
Wood
Food Waste
Plastics
Metals
Others

Rest of MEA Waste to Energy, Technology (US$ Billion, 2019-2035)

Incineration
Gasification
Pyrolysis

Rest of MEA Waste to Energy, Application (US$ Billion, 2019-2035)

Electricity Generation
Heat Generation
Transport Fuels
Others

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Customer Strories

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Case Study

Chemicals and Materials

Global Magnesium Sulfate Market – Forecast till 2027