Waste To Energy Market
Waste to Energy Market Forecasts to 2028 - Global Analysis By Waste Type (Process Waste, Municipal Solid Waste, Agriculture Waste, Medical Waste and Industrial Waste), Technology (Biochemical, Thermal, Biological, Physical and Anaerobic Digestion), Application (Heat, Electricity, Combined Heat & Power and Transport Fuels) and Geography
|
Years Covered |
2020-2028 |
|
Estimated Year Value (2022) |
US $58.59 BN |
|
Projected Year Value (2028) |
US $100.17 BN |
|
CAGR (2022 - 2028) |
9.35% |
|
Regions Covered |
North America, Europe, Asia Pacific, South America, and Middle East & Africa |
|
Countries Covered |
US, Canada, Mexico, Germany, UK, Italy, France, Spain, Japan, China, India, Australia, New Zealand, South Korea, Rest of Asia Pacific, South America, Argentina, Brazil, Chile, Middle East & Africa, Saudi Arabia, UAE, Qatar, and South Africa |
|
Largest Market |
Asia Pacific |
|
Highest Growing Market |
Europe |
According to Stratistics MRC, the Global Waste to Energy Market is accounted for $58.59 billion in 2022 and is expected to reach $100.17 billion by 2028 growing at a CAGR of 9.35% during the forecast period. Waste to energy is a process that converts waste into energy, reducing dependency on oil and coal for energy production. Waste to energy is a sustainable method that keeps waste out of landfills and limits the release of methane gas from landfills. It also prevents waste from entering landfills and reduces carbon dioxide emissions. These facilities use a boiler to burn trash or waste to create steam, which is then used to generate electricity. By eliminating pollutants from gas combustion and preventing them from entering the smokestack, the waste to energy process contributes to a reduction in air pollution.
According to the U.S. Environmental Protection Agency, greenhouse gas emissions witness a one-ton reduction for every ton of solid waste processed in waste to energy facilities. For instance, the U.S. based Covanta Holding Corporation utilizes its waste to energy facilities to recycle 500 kilotons of metal and convert approximately 21.0 million tons of waste into usable energy.
Market Dynamics:
Driver:
Increase in Production of Clean Energy
Growing urbanization and industrialization are accompanied by economic expansion, which generates waste, environmental hazards, and carbon dioxide (CO2) emissions. With widespread changes in people's lifestyles, the proportion of business and residential garbage has also significantly increased. Waste to energy has a role to play in achieving the transition to a sustainable energy ecosystem, serving as a clean demand response option, an energy source to reduce greenhouse gas (GHG) emissions, a design consideration for eco-industrial parks, and occasionally the only option for end-of-life waste treatment. In addition, one of the major forces driving the global market is the expanding demand for energy worldwide as a result of population growth, rapid industrialization, and urbanization.
Restraint:
High Installation Cost
The building of the necessary infrastructure, operating costs, waste management and segregation costs, and other costs are all part of the cost of setting up a waste to energy plant, and specifically an incineration facility. The incinerator plants also need to be maintained regularly, which is expected to hinder the market's growth over the projected period. Therefore, trained personnel and devoted staff are required to handle them.
Opportunity:
Waste to Energy has Potential to Replace Coal
Municipal solid waste combustion in waste-to-energy plants is a reliable and affordable substitute for coal power plants. As coal is burned to produce power, toxic gases such sulphur dioxide, nitrogen oxides, and hydrogen chloride are released, along with trace amounts of lead, mercury, and cadmium. On average, waste-to-energy plants can produce 300 million tonnes of electricity per year by waste incineration. This reduces the demand placed on fossil fuels, coal and other non-renewable energy sources.
Threat:
Low awareness and lack of infrastructure
The main factors that could impede the market's expansion are a lack of awareness regarding waste-to-energy plants and a lack of financial resources to implement cutting-edge technologies to generate electricity from waste. Inadequate infrastructure makes it challenging for developing countries to increase the amount of electricity generated from garbage.
Covid-19 Impact:
Due to the lockdown that has been imposed across many nations, the COVID-19 outbreak has caused severe uncertainty. The accumulation of a significant amount of toxic medical waste, including gloves, PPE kits, sanitizer bottles, and other items, has had a negative impact on the waste-to-energy market by increasing people's concern about acquiring the virus. Due to inappropriate waste collection and disposal, restrictions on economic activity, mobility, and the closure of industrial and production facilities, there was a severe impact on waste management.
The thermal segment is expected to be the largest during the forecast period
The thermal energy produced from burning waste is significantly responsible for the growth of thermal technology as it is used to generate steam turbines, which in turn generate power. For instance, Japan is a pioneer in the field and operates some of the most advanced thermal treatment centers, which can process 39 million tonnes of waste annually. As a result, this technology is extensively used and reliable.
The municipal solid waste segment is expected to have the highest CAGR during the forecast period
Owing to enhanced waste production from households, companies, retail stores, educational institutions, hotels, and other institutions, municipal solid waste has the highest CAGR. However, government organisations have established a framework that focuses on recycling garbage created as raw material, which is likely to promote the reuse of waste produced by commercial operations.
Region with largest share:
During the forecast period, Asia Pacific is expected to have the largest share owing to an increase in efforts by the government to adopt better MSW management techniques, offer incentives for waste-to-energy projects in the form of capital subsidies and feed-in tariffs, and provide financial support for R&D projects on a cost-sharing basis across the globe.
Region with highest CAGR:
An increase in government initiatives to support waste-to-energy projects and lower the emission of harmful gases is mainly responsible for this growth. Waste-to-energy plants occur in Europe. For instance, the 2013-built incinerator plant in Naples, Italy, has the capacity to burn 650,000 tonnes of garbage annually. Vartan, Aros, and Herning are only some of the waste-to-energy plants in Sweden and Denmark that produce more than 100 kW of electricity. In addition, the UK has a gasification-based waste to energy plant in Manchester that has a 78,000-ton annual capacity and can handle municipal solid waste, commercial garbage, and industrial waste.
Key players in the market
Some of the key players in Waste to Energy market include John Wood Group Plc, Plasco Energy Group. INC, China Everbright International Limited, Wheelabrator Technologies Holdings Inc., Suez, Covanta Holding Corporation, Waste Management Inc., Hitachi Zosen Inova AG, Babcock & Wilcox Enterprises, Inc., Veolia, Bluefire Renewables, C&G Environmental Protection Holdings Ltd., WM Intellectual Property Holdings, L.L.C., Abu Dhabi National Energy Company Pjsc (TAQA) and OMNI Conversion Technologies Inc.
Key Developments:
In October 2021, the waste-to-energy plant at Kapuluppada, Andhra Pradesh, India was inaugurated. The plant capacity is around 15 MW and is expected to receive 900 to 1000 tonnes of waste on a daily basis which will be supplied by Greater Visakhapatnam Municipal Corporation.
In January 2021, the Indian state-controlled oil firm (IOC) and North Delhi Municipal Corporation (NDMC) have joined forces in setting up a waste-to-energy plant (WtE) at NDMC’s Ranikhera, New Delhi, landfill site.
In December 2020, the Karnataka government laid the foundation for a waste-to-energy (WtE) plant at Bidadi, which is being developed by Karnataka Power Corporation Ltd (KPCL). The plant is expected to be operational by the end of 2022 and is set to be the first WtE plant in the state.
Waste Types Covered:
• Process Waste
• Municipal Solid Waste
• Agriculture Waste
• Medical Waste
• Industrial Waste
Technologies Covered:
• Biochemical
• Thermo-chemical
• Biological
• Physical
• Anaerobic Digestion
Applications Covered:
• Electricity
• Combined Heat & Power
• Transport Fuels
Regions Covered:
• North America
o US
o Canada
o Mexico
• Europe
o Germany
o UK
o Italy
o France
o Spain
o Rest of Europe
• Asia Pacific
o Japan
o China
o India
o Australia
o New Zealand
o South Korea
o Rest of Asia Pacific
• South America
o Argentina
o Brazil
o Chile
o Rest of South America
• Middle East & Africa
o Saudi Arabia
o UAE
o Qatar
o South Africa
o Rest of Middle East & Africa
What our report offers:
- Market share assessments for the regional and country-level segments
- Strategic recommendations for the new entrants
- Covers Market data for the years 2020, 2021, 2022, 2025, and 2028
- Market Trends (Drivers, Constraints, Opportunities, Threats, Challenges, Investment Opportunities, and recommendations)
- Strategic recommendations in key business segments based on the market estimations
- Competitive landscaping mapping the key common trends
- Company profiling with detailed strategies, financials, and recent developments
- Supply chain trends mapping the latest technological advancements
Free Customization Offerings:
All the customers of this report will be entitled to receive one of the following free customization options:
• Company Profiling
o Comprehensive profiling of additional market players (up to 3)
o SWOT Analysis of key players (up to 3)
• Regional Segmentation
o Market estimations, Forecasts and CAGR of any prominent country as per the client's interest (Note: Depends on feasibility check)
• Competitive Benchmarking
Benchmarking of key players based on product portfolio, geographical presence, and strategic alliances
Table of Contents
1 Executive Summary
2 Preface
2.1 Abstract
2.2 Stake Holders
2.3 Research Scope
2.4 Research Methodology
2.4.1 Data Mining
2.4.2 Data Analysis
2.4.3 Data Validation
2.4.4 Research Approach
2.5 Research Sources
2.5.1 Primary Research Sources
2.5.2 Secondary Research Sources
2.5.3 Assumptions
3 Market Trend Analysis
3.1 Introduction
3.2 Drivers
3.3 Restraints
3.4 Opportunities
3.5 Threats
3.6 Technology Analysis
3.7 Application Analysis
3.8 Emerging Markets
3.9 Impact of Covid-19
4 Porters Five Force Analysis
4.1 Bargaining power of suppliers
4.2 Bargaining power of buyers
4.3 Threat of substitutes
4.4 Threat of new entrants
4.5 Competitive rivalry
5 Global Waste to Energy Market, By Waste Type
5.1 Introduction
5.2 Process Waste
5.3 Municipal Solid Waste
5.4 Agriculture Waste
5.5 Medical Waste
5.6 Industrial Waste
6 Global Waste to Energy Market, By Technology
6.1 Introduction
6.2 Biochemical
6.2.1 Anaerobic Digestion
6.3 Thermal
6.3.1 Incineration
6.3.2 Gasification
6.3.3 Plasma-Arc Gasification
6.3.4 Pyrolysis & Gasification
6.4 Biological
6.4.1 Fermentation
6.4.2 Biogas Plants/Anaerobic Digestion
6.4.3 Methane Capture/Landfill Gas
6.4.4 Landfill Gas
6.5 Physical
7 Global Waste to Energy Market, By Application
7.1 Introduction
7.2 Electricity
7.3 Combined Heat & Power
7.4 Transport Fuels
8 Global Waste to Energy Market, By Geography
8.1 Introduction
8.2 North America
8.2.1 US
8.2.2 Canada
8.2.3 Mexico
8.3 Europe
8.3.1 Germany
8.3.2 UK
8.3.3 Italy
8.3.4 France
8.3.5 Spain
8.3.6 Rest of Europe
8.4 Asia Pacific
8.4.1 Japan
8.4.2 China
8.4.3 India
8.4.4 Australia
8.4.5 New Zealand
8.4.6 South Korea
8.4.7 Rest of Asia Pacific
8.5 South America
8.5.1 Argentina
8.5.2 Brazil
8.5.3 Chile
8.5.4 Rest of South America
8.6 Middle East & Africa
8.6.1 Saudi Arabia
8.6.2 UAE
8.6.3 Qatar
8.6.4 South Africa
8.6.5 Rest of Middle East & Africa
9 Key Developments
9.1 Agreements, Partnerships, Collaborations and Joint Ventures
9.2 Acquisitions & Mergers
9.3 New Product Launch
9.4 Expansions
9.5 Other Key Strategies
10 Company Profiling
10.1 John Wood Group Plc
10.2 Plasco Energy Group. INC
10.3 China Everbright International Limited
10.4 Wheelabrator Technologies Holdings Inc.
10.5 Suez
10.6 Covanta Holding Corporation
10.6 Waste Management Inc.
10.7 Hitachi Zosen Inova AG
10.9 Babcock & Wilcox Enterprises, Inc.
10.10 Veolia
10.11 Bluefire Renewables
10.12 C&G Environmental Protection Holdings Ltd.
10.13 WM Intellectual Property Holdings, L.L.C.
10.14 Abu Dhabi National Energy Company Pjsc (TAQA)
10.15 OMNI Conversion Technologies Inc.
List of Tables
1 Global Waste to Energy Market Outlook, By Region (2020-2028) ($MN)
2 Global Waste to Energy Market Outlook, By Waste Type (2020-2028) ($MN)
3 Global Waste to Energy Market Outlook, By Process Waste (2020-2028) ($MN)
4 Global Waste to Energy Market Outlook, By Municipal Solid Waste (2020-2028) ($MN)
5 Global Waste to Energy Market Outlook, By Agriculture Waste (2020-2028) ($MN)
6 Global Waste to Energy Market Outlook, By Medical Waste (2020-2028) ($MN)
7 Global Waste to Energy Market Outlook, By Industrial Waste (2020-2028) ($MN)
8 Global Waste to Energy Market Outlook, By Technology (2020-2028) ($MN)
9 Global Waste to Energy Market Outlook, By Biochemical (2020-2028) ($MN)
10 Global Waste to Energy Market Outlook, By Anaerobic Digestion (2020-2028) ($MN)
11 Global Waste to Energy Market Outlook, By Thermal (2020-2028) ($MN)
12 Global Waste to Energy Market Outlook, By Incineration (2020-2028) ($MN)
13 Global Waste to Energy Market Outlook, By Gasification (2020-2028) ($MN)
14 Global Waste to Energy Market Outlook, By Plasma-Arc Gasification (2020-2028) ($MN)
15 Global Waste to Energy Market Outlook, By Pyrolysis & Gasification (2020-2028) ($MN)
16 Global Waste to Energy Market Outlook, By Biological (2020-2028) ($MN)
17 Global Waste to Energy Market Outlook, By Fermentation (2020-2028) ($MN)
18 Global Waste to Energy Market Outlook, By Biogas Plants/Anaerobic Digestion (2020-2028) ($MN)
19 Global Waste to Energy Market Outlook, By Methane Capture/Landfill Gas (2020-2028) ($MN)
20 Global Waste to Energy Market Outlook, By Landfill Gas (2020-2028) ($MN)
21 Global Waste to Energy Market Outlook, By Physical (2020-2028) ($MN)
22 Global Waste to Energy Market Outlook, By Application (2020-2028) ($MN)
23 Global Waste to Energy Market Outlook, By Electricity (2020-2028) ($MN)
24 Global Waste to Energy Market Outlook, By Combined Heat & Power (2020-2028) ($MN)
25 Global Waste to Energy Market Outlook, By Transport Fuels (2020-2028) ($MN)
26 North America Waste to Energy Market Outlook, By Country (2020-2028) ($MN)
27 North America Waste to Energy Market Outlook, By Waste Type (2020-2028) ($MN)
28 North America Waste to Energy Market Outlook, By Process Waste (2020-2028) ($MN)
29 North America Waste to Energy Market Outlook, By Municipal Solid Waste (2020-2028) ($MN)
30 North America Waste to Energy Market Outlook, By Agriculture Waste (2020-2028) ($MN)
31 North America Waste to Energy Market Outlook, By Medical Waste (2020-2028) ($MN)
32 North America Waste to Energy Market Outlook, By Industrial Waste (2020-2028) ($MN)
33 North America Waste to Energy Market Outlook, By Technology (2020-2028) ($MN)
34 North America Waste to Energy Market Outlook, By Biochemical (2020-2028) ($MN)
35 North America Waste to Energy Market Outlook, By Anaerobic Digestion (2020-2028) ($MN)
36 North America Waste to Energy Market Outlook, By Thermal (2020-2028) ($MN)
37 North America Waste to Energy Market Outlook, By Incineration (2020-2028) ($MN)
38 North America Waste to Energy Market Outlook, By Gasification (2020-2028) ($MN)
39 North America Waste to Energy Market Outlook, By Plasma-Arc Gasification (2020-2028) ($MN)
40 North America Waste to Energy Market Outlook, By Pyrolysis & Gasification (2020-2028) ($MN)
41 North America Waste to Energy Market Outlook, By Biological (2020-2028) ($MN)
42 North America Waste to Energy Market Outlook, By Fermentation (2020-2028) ($MN)
43 North America Waste to Energy Market Outlook, By Biogas Plants/Anaerobic Digestion (2020-2028) ($MN)
44 North America Waste to Energy Market Outlook, By Methane Capture/Landfill Gas (2020-2028) ($MN)
45 North America Waste to Energy Market Outlook, By Landfill Gas (2020-2028) ($MN)
46 North America Waste to Energy Market Outlook, By Physical (2020-2028) ($MN)
47 North America Waste to Energy Market Outlook, By Application (2020-2028) ($MN)
48 North America Waste to Energy Market Outlook, By Electricity (2020-2028) ($MN)
49 North America Waste to Energy Market Outlook, By Combined Heat & Power (2020-2028) ($MN)
50 North America Waste to Energy Market Outlook, By Transport Fuels (2020-2028) ($MN)
51 Europe Waste to Energy Market Outlook, By Country (2020-2027) ($MN)
52 Europe Waste to Energy Market Outlook, By Waste Type (2020-2028) ($MN)
53 Europe Waste to Energy Market Outlook, By Process Waste (2020-2028) ($MN)
54 Europe Waste to Energy Market Outlook, By Municipal Solid Waste (2020-2028) ($MN)
55 Europe Waste to Energy Market Outlook, By Agriculture Waste (2020-2028) ($MN)
56 Europe Waste to Energy Market Outlook, By Medical Waste (2020-2028) ($MN)
57 Europe Waste to Energy Market Outlook, By Industrial Waste (2020-2028) ($MN)
58 Europe Waste to Energy Market Outlook, By Technology (2020-2028) ($MN)
59 Europe Waste to Energy Market Outlook, By Biochemical (2020-2028) ($MN)
60 Europe Waste to Energy Market Outlook, By Anaerobic Digestion (2020-2028) ($MN)
61 Europe Waste to Energy Market Outlook, By Thermal (2020-2028) ($MN)
62 Europe Waste to Energy Market Outlook, By Incineration (2020-2028) ($MN)
63 Europe Waste to Energy Market Outlook, By Gasification (2020-2028) ($MN)
64 Europe Waste to Energy Market Outlook, By Plasma-Arc Gasification (2020-2028) ($MN)
65 Europe Waste to Energy Market Outlook, By Pyrolysis & Gasification (2020-2028) ($MN)
66 Europe Waste to Energy Market Outlook, By Biological (2020-2028) ($MN)
67 Europe Waste to Energy Market Outlook, By Fermentation (2020-2028) ($MN)
68 Europe Waste to Energy Market Outlook, By Biogas Plants/Anaerobic Digestion (2020-2028) ($MN)
69 Europe Waste to Energy Market Outlook, By Methane Capture/Landfill Gas (2020-2028) ($MN)
70 Europe Waste to Energy Market Outlook, By Landfill Gas (2020-2028) ($MN)
71 Europe Waste to Energy Market Outlook, By Physical (2020-2028) ($MN)
72 Europe Waste to Energy Market Outlook, By Application (2020-2028) ($MN)
73 Europe Waste to Energy Market Outlook, By Electricity (2020-2028) ($MN)
74 Europe Waste to Energy Market Outlook, By Combined Heat & Power (2020-2028) ($MN)
75 Europe Waste to Energy Market Outlook, By Transport Fuels (2020-2028) ($MN)
76 Asia Pacific Waste to Energy Market Outlook, By Country (2020-2027) ($MN)
77 Asia Pacific Waste to Energy Market Outlook, By Waste Type (2020-2028) ($MN)
78 Asia Pacific Waste to Energy Market Outlook, By Process Waste (2020-2028) ($MN)
79 Asia Pacific Waste to Energy Market Outlook, By Municipal Solid Waste (2020-2028) ($MN)
80 Asia Pacific Waste to Energy Market Outlook, By Agriculture Waste (2020-2028) ($MN)
81 Asia Pacific Waste to Energy Market Outlook, By Medical Waste (2020-2028) ($MN)
82 Asia Pacific Waste to Energy Market Outlook, By Industrial Waste (2020-2028) ($MN)
83 Asia Pacific Waste to Energy Market Outlook, By Technology (2020-2028) ($MN)
84 Asia Pacific Waste to Energy Market Outlook, By Biochemical (2020-2028) ($MN)
85 Asia Pacific Waste to Energy Market Outlook, By Anaerobic Digestion (2020-2028) ($MN)
86 Asia Pacific Waste to Energy Market Outlook, By Thermal (2020-2028) ($MN)
87 Asia Pacific Waste to Energy Market Outlook, By Incineration (2020-2028) ($MN)
88 Asia Pacific Waste to Energy Market Outlook, By Gasification (2020-2028) ($MN)
89 Asia Pacific Waste to Energy Market Outlook, By Plasma-Arc Gasification (2020-2028) ($MN)
90 Asia Pacific Waste to Energy Market Outlook, By Pyrolysis & Gasification (2020-2028) ($MN)
91 Asia Pacific Waste to Energy Market Outlook, By Biological (2020-2028) ($MN)
92 Asia Pacific Waste to Energy Market Outlook, By Fermentation (2020-2028) ($MN)
93 Asia Pacific Waste to Energy Market Outlook, By Biogas Plants/Anaerobic Digestion (2020-2028) ($MN)
94 Asia Pacific Waste to Energy Market Outlook, By Methane Capture/Landfill Gas (2020-2028) ($MN)
95 Asia Pacific Waste to Energy Market Outlook, By Landfill Gas (2020-2028) ($MN)
96 Asia Pacific Waste to Energy Market Outlook, By Physical (2020-2028) ($MN)
97 Asia Pacific Waste to Energy Market Outlook, By Application (2020-2028) ($MN)
98 Asia Pacific Waste to Energy Market Outlook, By Electricity (2020-2028) ($MN)
99 Asia Pacific Waste to Energy Market Outlook, By Combined Heat & Power (2020-2028) ($MN)
100 Asia Pacific Waste to Energy Market Outlook, By Transport Fuels (2020-2028) ($MN)
101 South America Waste to Energy Market Outlook, By Country (2020-2027) ($MN)
102 South America Waste to Energy Market Outlook, By Waste Type (2020-2028) ($MN)
103 South America Waste to Energy Market Outlook, By Process Waste (2020-2028) ($MN)
104 South America Waste to Energy Market Outlook, By Municipal Solid Waste (2020-2028) ($MN)
105 South America Waste to Energy Market Outlook, By Agriculture Waste (2020-2028) ($MN)
106 South America Waste to Energy Market Outlook, By Medical Waste (2020-2028) ($MN)
107 South America Waste to Energy Market Outlook, By Industrial Waste (2020-2028) ($MN)
108 South America Waste to Energy Market Outlook, By Technology (2020-2028) ($MN)
109 South America Waste to Energy Market Outlook, By Biochemical (2020-2028) ($MN)
110 South America Waste to Energy Market Outlook, By Anaerobic Digestion (2020-2028) ($MN)
111 South America Waste to Energy Market Outlook, By Thermal (2020-2028) ($MN)
112 South America Waste to Energy Market Outlook, By Incineration (2020-2028) ($MN)
113 South America Waste to Energy Market Outlook, By Gasification (2020-2028) ($MN)
114 South America Waste to Energy Market Outlook, By Plasma-Arc Gasification (2020-2028) ($MN)
115 South America Waste to Energy Market Outlook, By Pyrolysis & Gasification (2020-2028) ($MN)
116 South America Waste to Energy Market Outlook, By Biological (2020-2028) ($MN)
117 South America Waste to Energy Market Outlook, By Fermentation (2020-2028) ($MN)
118 South America Waste to Energy Market Outlook, By Biogas Plants/Anaerobic Digestion (2020-2028) ($MN)
119 South America Waste to Energy Market Outlook, By Methane Capture/Landfill Gas (2020-2028) ($MN)
120 South America Waste to Energy Market Outlook, By Landfill Gas (2020-2028) ($MN)
121 South America Waste to Energy Market Outlook, By Physical (2020-2028) ($MN)
122 South America Waste to Energy Market Outlook, By Application (2020-2028) ($MN)
123 South America Waste to Energy Market Outlook, By Electricity (2020-2028) ($MN)
124 South America Waste to Energy Market Outlook, By Combined Heat & Power (2020-2028) ($MN)
125 South America Waste to Energy Market Outlook, By Transport Fuels (2020-2028) ($MN)
126 Middle East & Africa Waste to Energy Market Outlook, By Country (2020-2027) ($MN)
127 Middle East & Africa Waste to Energy Market Outlook, By Waste Type (2020-2028) ($MN)
128 Middle East & Africa Waste to Energy Market Outlook, By Process Waste (2020-2028) ($MN)
129 Middle East & Africa Waste to Energy Market Outlook, By Municipal Solid Waste (2020-2028) ($MN)
130 Middle East & Africa Waste to Energy Market Outlook, By Agriculture Waste (2020-2028) ($MN)
131 Middle East & Africa Waste to Energy Market Outlook, By Medical Waste (2020-2028) ($MN)
132 Middle East & Africa Waste to Energy Market Outlook, By Industrial Waste (2020-2028) ($MN)
133 Middle East & Africa Waste to Energy Market Outlook, By Technology (2020-2028) ($MN)
134 Middle East & Africa Waste to Energy Market Outlook, By Biochemical (2020-2028) ($MN)
135 Middle East & Africa Waste to Energy Market Outlook, By Anaerobic Digestion (2020-2028) ($MN)
136 Middle East & Africa Waste to Energy Market Outlook, By Thermal (2020-2028) ($MN)
137 Middle East & Africa Waste to Energy Market Outlook, By Incineration (2020-2028) ($MN)
138 Middle East & Africa Waste to Energy Market Outlook, By Gasification (2020-2028) ($MN)
139 Middle East & Africa Waste to Energy Market Outlook, By Plasma-Arc Gasification (2020-2028) ($MN)
140 Middle East & Africa Waste to Energy Market Outlook, By Pyrolysis & Gasification (2020-2028) ($MN)
141 Middle East & Africa Waste to Energy Market Outlook, By Biological (2020-2028) ($MN)
142 Middle East & Africa Waste to Energy Market Outlook, By Fermentation (2020-2028) ($MN)
143 Middle East & Africa Waste to Energy Market Outlook, By Biogas Plants/Anaerobic Digestion (2020-2028) ($MN)
144 Middle East & Africa Waste to Energy Market Outlook, By Methane Capture/Landfill Gas (2020-2028) ($MN)
145 Middle East & Africa Waste to Energy Market Outlook, By Landfill Gas (2020-2028) ($MN)
146 Middle East & Africa Waste to Energy Market Outlook, By Physical (2020-2028) ($MN)
147 Middle East & Africa Waste to Energy Market Outlook, By Application (2020-2028) ($MN)
148 Middle East & Africa Waste to Energy Market Outlook, By Electricity (2020-2028) ($MN)
149 Middle East & Africa Waste to Energy Market Outlook, By Combined Heat & Power (2020-2028) ($MN)
150 Middle East & Africa Waste to Energy Market Outlook, By Transport Fuels (2020-2028) ($MN)
List of Figures
RESEARCH METHODOLOGY
We at ‘Stratistics’ opt for an extensive research approach which involves data mining, data validation, and data analysis. The various research sources include in-house repository, secondary research, competitor’s sources, social media research, client internal data, and primary research.
Our team of analysts prefers the most reliable and authenticated data sources in order to perform the comprehensive literature search. With access to most of the authenticated data bases our team highly considers the best mix of information through various sources to obtain extensive and accurate analysis.
Each report takes an average time of a month and a team of 4 industry analysts. The time may vary depending on the scope and data availability of the desired market report. The various parameters used in the market assessment are standardized in order to enhance the data accuracy.
Data Mining
The data is collected from several authenticated, reliable, paid and unpaid sources and is filtered depending on the scope & objective of the research. Our reports repository acts as an added advantage in this procedure. Data gathering from the raw material suppliers, distributors and the manufacturers is performed on a regular basis, this helps in the comprehensive understanding of the products value chain. Apart from the above mentioned sources the data is also collected from the industry consultants to ensure the objective of the study is in the right direction.
Market trends such as technological advancements, regulatory affairs, market dynamics (Drivers, Restraints, Opportunities and Challenges) are obtained from scientific journals, market related national & international associations and organizations.
Data Analysis
From the data that is collected depending on the scope & objective of the research the data is subjected for the analysis. The critical steps that we follow for the data analysis include:
- Product Lifecycle Analysis
- Competitor analysis
- Risk analysis
- Porters Analysis
- PESTEL Analysis
- SWOT Analysis
The data engineering is performed by the core industry experts considering both the Marketing Mix Modeling and the Demand Forecasting. The marketing mix modeling makes use of multiple-regression techniques to predict the optimal mix of marketing variables. Regression factor is based on a number of variables and how they relate to an outcome such as sales or profits.
Data Validation
The data validation is performed by the exhaustive primary research from the expert interviews. This includes telephonic interviews, focus groups, face to face interviews, and questionnaires to validate our research from all aspects. The industry experts we approach come from the leading firms, involved in the supply chain ranging from the suppliers, distributors to the manufacturers and consumers so as to ensure an unbiased analysis.
We are in touch with more than 15,000 industry experts with the right mix of consultants, CEO's, presidents, vice presidents, managers, experts from both supply side and demand side, executives and so on.
The data validation involves the primary research from the industry experts belonging to:
- Leading Companies
- Suppliers & Distributors
- Manufacturers
- Consumers
- Industry/Strategic Consultants
Apart from the data validation the primary research also helps in performing the fill gap research, i.e. providing solutions for the unmet needs of the research which helps in enhancing the reports quality.
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We extend our support to 6 months post sale. A post sale customization is also provided to cover your unmet needs in the report.
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We provide a free 15% customization on every purchase. This requirement can be fulfilled for both pre and post sale. You may send your customization requirements through email at info@strategymrc.com or call us on +1-301-202-5929.
Note: This customization is absolutely free until it falls under the 15% bracket. If your requirement exceeds this a feasibility check will be performed. Post that, a quote will be provided along with the timelines.
WHY CHOOSE US ?
Assured Quality
Best in class reports with high standard of research integrity
24X7 Research Support
Continuous support to ensure the best customer experience.
Free Customization
Adding more values to your product of interest.
Safe & Secure Access
Providing a secured environment for all online transactions.
Trusted by 600+ Brands
Serving the most reputed brands across the world.
