The Waste to Energy market in the Asia-Pacific region is forecast to grow at the CAGR of around 10.75% during 2020-2025.

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Document Outline
Table of Content
Market Segmentation, Scope of Work
05
Research Process & Methodology
Primary Research, Secondary Research, Companies Interviewed, Respondent Profile, Research
Methodology, Forecasting
13
Introduction
About Us, Key Questions Answered In This Study
02
Sample Pages
Asia Pacific Waste to Energy Market Analysis, 2020
21
Commercials 44
Disclaimer 46

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Market Segmentation-
• Thermal
o Incineration
o Pyrolysis
o Gasification
• Biological
• Physical
Asia Pacific Waste to Energy Technologies Market
By Technology
• Municipal Waste
• Agricultural Waste
• Industrial Waste
By Type of Waste
• China
• India
• Japan
• South Korea
• Thailand
• Indonesia
• Philippines
• Malaysia
• Australia
• Vietnam
• Others
By Country
• Suez S.A.
• Veolia Environment C&G
Limited
• Waste Management Inc.
• Keppel Seghers
• Babcock & Wilcox
Company
• Hitachi Zosen Corporation
• Covanta Energy
Corporation
• Amec Foster Wheeler
• Evoqua Water
Technologies
• Others
By Company

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Table of Content (1/6)
Historical Year: 2015
Base Year: 2019
Forecast Year: 2025
Table of Content
1. Introduction
1.1. Market Segmentation
1.2. Product Definition
1.3. Research Process
1.4. Assumptions
2. Executive Summary
3. Expert Verbatim- What our Experts Say?
4. Asia-Pacific Waste to Energy Market Outlook, 2015-2025F
4.1. Market Size & Analysis
4.1.1. Market Revenues
4.1.2. Volume
4.2. Market Share & Analysis
4.2.1. By Technology
4.2.1.1. Thermal
4.2.1.2. Biological
4.2.1.3. Physical
4.2.2. By Thermal Technology
4.2.2.1. Incineration
4.2.2.2. Pyrolysis
4.2.2.3. Gasification

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Table of Content (2/6)
Historical Year: 2015
Base Year: 2019
Forecast Year: 2025
Table of Content
4.2.3. By Type of Waste
4.2.3.1. Municipal Waste
4.2.3.2. Agricultural Waste
4.2.3.3. Industrial Waste
4.2.4. By Country
4.2.4.1. China
4.2.4.2. India
4.2.4.3. Japan
4.2.4.4. South Korea
4.2.4.5. Thailand
4.2.4.6. Indonesia
4.2.4.7. Philippines
4.2.4.8. Malaysia
4.2.4.9. Australia
4.2.4.10. Vietnam
4.2.4.11. Others
5. Japan Waste to Energy Market Outlook, 2015-2025F
5.1. Market Size & Analysis
5.1.1. Market Revenues
5.1.2. Volume

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Table of Content (3/6)
Historical Year: 2015
Base Year: 2019
Forecast Year: 2025
Table of Content
5.2. Market Size & Analysis
5.2.1. By Technology
5.2.2. By Type of Waste
6. China Waste to Energy Market Outlook, 2015-2025F
6.1. Market Size & Analysis
6.1.1. Market Revenues
6.1.2. Volume
6.2. Market Size & Analysis
6.2.1. By Technology
6.2.2. By Type of Waste
7. India Waste to Energy Market Outlook, 2015-2025F
7.1. Market Size & Analysis
7.1.1. Market Revenues
7.1.2. Volume
7.2. Market Size & Analysis
7.2.1. By Technology
7.2.2. By Type of Waste
8. South Korea Waste to Energy Market Outlook, 2015-2025F
8.1. Market Size & Analysis
8.1.1. Market Revenues

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Table of Content (4/6)
Historical Year: 2015
Base Year: 2019
Forecast Year: 2025
Table of Content
8.1.2. Volume
8.2. Market Size & Analysis
8.2.1. By Technology
8.2.2. By Type of Waste
9. Singapore Waste to Energy Market Outlook, 2015-2025F
9.1. Market Size & Analysis
9.1.1. Market Revenues
9.1.2. Volume
9.2. Market Size & Analysis
9.2.1. By Technology
9.2.2. By Type of Waste
10. Asia Pacific Waste to Energy TechnologiesMarket Trends & Insights
11. Asia Pacific Waste to Energy Technologies Market Dynamics
11.1. Growth Drivers
11.2. Challenges
11.3. Impact Analysis
12. Asia Pacific Waste to Energy Technologies Market White Spaces, Hotspot & Opportunities
13. Asia Pacific Waste to Energy Technologies Market- Value Chain
14. Asia Pacific Waste to Energy Technologies Market Key Strategic Imperatives for Success & Growth
15. Asia Pacific Waste to Energy Technologies Market Policies & Regulations

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Table of Content (5/6)
Historical Year: 2015
Base Year: 2019
Forecast Year: 2025
Table of Content
16. Asia Pacific Waste to Energy Technologies Market Porters Five Forces Analysis
17. Asia Pacific Waste to Energy Technologies Market Competition Outlook
17.1. Competition Matrix
17.1.1. Product Portfolio
17.1.2. Manufacturing Facilities
17.1.3. Target Region
17.1.4. Strategic Alliances
17.1.5. Strategic Initiatives
17.2. Company Profiles of top companies (Business Description, Product Segments, Business Segments, Financials, Strategic Alliances/
Partnerships, Future Plans)
17.2.1. Hitachi Zosen Corporation
17.2.2. Babcock & Wilcox Company
17.2.3. Amec Foster Wheeler
17.2.4. Veolia Environment S.A.
17.2.5. Suez S.A.
17.2.6. Waste Management Inc.
17.2.7. C&G Limited
17.2.8. Keppler Seghers
17.2.9. Covanta Energy Corporation
17.2.10. Evoqua Water Technologies
17.2.11. Xcel Energy, Inc.

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Table of Content (6/6)
Historical Year: 2015
Base Year: 2019
Forecast Year: 2025
Table of Content
17.2.12. Abu Dhabi National Energy Company PJSC
17.2.13. MVV Energie AG
17.2.14. China Jinjiang Environment Holding Co. Limited
17.2.15. A2A SpA
17.2.16. SCHMACK BIOGAS GMBH
17.2.17. China Everbright International Limited
17.2.18. Mitsubishi Heavy Industries Limited
17.2.19. Shandong Wheelabrator Technologies Inc.
17.2.20. Doosan Lentjes GmbH
18. Disclaimer

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Document Outline
Table of Content
Market Segmentation, Scope Of Work
05
Research Process & Methodology
Primary Research, Secondary Research, Companies Interviewed, Respondent Profile, Research
Methodology, Forecasting
13
Introduction
About Us, Key Questions Answered In This Study
02
Sample Pages
Asia Pacific Waste to Energy Market Analysis, 2020
21
Commercials 44
Disclaimer 46

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Asia Pacific Waste to Energy Technologies Overview

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Waste to Energy Technologies Overview
Source: XXX
Type of
Technology
Incineration with
energy recovery
Gasification Pyrolysis Composting Anaerobic Digestion
Description
Direct combustion of
waste between 750 and
1100ºC in the presence
of oxygen.
Partial oxidation of waste
between 800 and 1200ºC
in the presence of a
controlled amount of
oxygen
Thermal degradation
of waste between 300
& 1300ºC in the
absence of oxygen
Aerobic bioconversion of
organic wastes
Biodegradation of
organic wastes in the
absence of
oxygen, with anaerobic
microorganisms
Products/
Byproducts
Steam for electricity
and/ or heat generation
in a boiler
Produces synthetic gas
for further combustion
or conversion to
chemical feedstock
Produces liquid fuel
for further
combustion or
conversion to
chemical feedstock
Produces compost which
can serve as a soil
conditioner, mitigate
erosion, sequester
carbon in soil, be used in
land reclamation and as a
final cover for landfills
Produces biogas and
digestate. Digestate can
be composted for use as
a soil conditioner or
dewatered and used as
low calorific value
refuse-derived fuel
Waste Input
Mixed MSW or refuse-
derived fuel
Wood waste, agricultural
residues, sewage sludge
& plastic waste
Wood waste,
agricultural residues,
sewage sludge &
plastic waste
Separated organic
fraction of MSW, food
waste, or other solid
organic waste
Separated organic
fraction of MSW, food
waste, animal excreta,
liquids and sludge
Volume
Reduction
75-90% 75-90% 50-90% 95-100% 45-50%
Pollution control
Requirement
High Medium Medium Low Low-Medium
Cost (USD/Ton) 95-190 95-190 95-190 0-70 65-120
Scale of Plant
Available from small to
large scales. A large
scale plant is common
Available from small to
large scales
Available from small
to large scales
For small scale
composting
For centralized facilities
on a moderately large
scale
Extent of Use Europe, Japan & the US Japan and South Korea Not Widely Used Asia Not Widely Used

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Asia Pacific Waste to Energy Market Overview

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Waste to Energy Market Overview
• More than 215 million tons of solid waste is incinerated in an year and only 15% of the overall waste incinerated is subjected to energy
recovery. In Asia-Pacific region, thermal waste to energy plants account for 29% of the overall incinerated waste and the number is 25% in
Europe. Also, landfill and open dumping accounts for the majority share in waste treatment methods, globally. Furthermore, >90% waste
collected in Africa and South America is still discarded in either landfills or open dumps
• Still, there are more than 200 number of incineration plants under construction globally which are expected to be online by 2023. Thermal
plants are still coming up in emerging economies of China, Thailand, the Philippines, Indonesia and Myanmar
S. No. Country Target Main Support Scheme
1 China Non-Fossil Fuel Capacity to exceed 770 GW by 2020 Feed-in Tariff
2 Japan
22-24% of the total electricity generation to be met by
renewable sources by 2030
Feed-in Tariff and auction scheme for large
solar PV projects
3 France
32% of gross final energy consumption to be comprised of
renewable sources
Feed-in Tariffs and auction system
4 Russia 4.5% of the total energy generation from renewable sources Capacity auctions
5 India
Solar PV: 100 GW; Wind: 60 GW; Biomass: 10 GW; Small
Hydropower: 5 GW by 2022
Capacity auctions, feed-in tariffs and
accelerated depreciation tax benefits
6 Sweden 49% of renewable sources in gross final energy consumption Norway-Sweden Green Certificate Scheme
7 United States No national renewable energy target; delegated to states in renewable Portfolio Standards (RPS)
Source: IEA
Renewable Energy Targets of Leading Waste Treating Countries,

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Asia Pacific Waste to Energy Market Outlook, 2015-2025F

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Asia-Pacific Waste to Energy Market Outlook, By Revenues, By Volume
Figure 27: Asia-Pacific Waste to Energy Market Revenues (USD Million), Volumes (Million Tons), 2015- 2025F
Source: MarkNtel Advisors
• Asia-Pacific region has emerged as the major hub for the waste to energy technology during the historic period. Increasing adoption of
sources providing renewable energy and emerging economies of India and China are propelling the growth in Waste to Energy Market in
the region. Moreover, economies such as China and Japan are focusing on investing in research and development activities in order to
develop new and more efficient technologies to treat municipal solid waste in the region, thereby, driving growth in the Waste to Energy
Market in the region. In addition, Government across the countries in Asia are focusing on reduction of their carbon footprints to ensure
energy security, thereby propelling the demand for waste to energy technologies in the region. As a result,, Asia-Pacific waste to energy
market is poised to grow at a CAGR of ~XX%, in value terms during the forecast period

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Asia-Pacific Waste to Energy Market Revenue Share, By Technology
Figure 28: Asia-Pacific Waste to Energy Market Revenue Share (Percentage), By Technology, 2019 & 2025F
• Biological technology holds a market share of approximately XX%, in value terms in the Asia-Pacific waste to energy market and the
technology is anticipated to witness fastest growth in the market over the next five years on account of advantages associated with use of
these technologies over its counterparts, in terms of treatment efficiency and environmental concerns. As a result, the technology is
expected to witness fastest growth and hold an increased share of X%, in value terms, by the end of the forecast period
• However, thermal technology holds the largest share in the market owing to the technology being proven, tested and installed in most
number of plants operating in the region
• In the last few years, a lot of chemical, rubber and
automotive manufacturing industries have shifted
their base to the Asia-Pacific region to capitalize on
the availability of cheap labour and abundance of
natural resources, thereby, increasing basic energy
requirements and emanating the need for improved
waste disposal methods and high demand for
renewable energy sources

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Asia-Pacific Waste to Energy Market Revenue Share, By Technology
Figure 29: Asia-Pacific Thermal Waste to Energy Market Revenue Share (Percentage), By Technology, 2019 & 2025F
• Incineration is the most widely adopted thermal waste to energy technology as it reduces the waste to ashes and the discard does not
require large piece of land to be decomposed. Moreover, less time consuming and high energy generating process of incineration held the
largest share in the market and the trend is anticipated to follow, during the next five years on account of decreasing preference for
pyrolysis and gasification technologies.
• Challenges associated with waste transfer and waste sorting also promote the use of incineration technology for the treatment of solid
municipal waste in the region.
• South Korea and Japan are among the mature markets
for waste to energy technologies in the region and are
pioneers in terms of technology development in the
region.
• Hitachi Zosen, C&G Limited, XXXXXXX, XXXXXX are
leading companies facilitating the investments in
research and development of waste to energy
technologies in the region

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Asia-Pacific Waste to Energy Market Revenue Share, By Type of Waste
Figure 30: Asia-Pacific Waste to Energy Market Revenue Share, By Type of Waste, 2019 & 2025F
Source: MarkNtel Advisors

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Asia-Pacific Waste to Energy Market Revenue Share, By Country
Sr.No Name of the Country
Market Share
2019
Market Share
2019
1 China X% X%
2 India X% X%
3 Japan X% X%
4 South Korea X% X%
5 Thailand X% X%
6 Indonesia X% X%
7 Philippines X% X%
8 Malaysia X% X%
9 Australia X% X%
10 Vietnam X% X%
11 Others X% X%
Source: MarkNtel Advisors

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Japan Waste to Energy Market Outlook, 2015-2025F

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Japan Waste to Energy Market Outlook, By Revenues, By Volume
Figure 32: Japan Waste to Energy Market Revenues (USD Million), Volumes (Million Tons), 2015- 2025F
• Japan is the largest market for waste to energy technologies in the region. The country has hundreds of waste to energy plants operational,
as of 2019 and the country has the best infrastructure for energy generation from waste in Asia-Pacific
• Low availability of land for waste disposal and pressing needs for energy security to cater to the growing demand from ever increasing
population and vast industrial base has been driving the growth in demand for waste to energy technologies in the country, during the
forecast period
• Sustainable development goals, PPPs and government initiatives to promote the use of renewable energy are further pushing the demand
for waste to energy technologies in Japan. Hence, the market is poised to grow at a CAGR of XX%, in value terms, till 2025

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Japan Waste to Energy Market Revenue Share, By Technology
Figure 33: Japan Waste to Energy Market Revenue Share (Percentage), By Technology, 2019 & 2025F
• Japan has the best and most efficient technologies for the treatment of residual waste and the country is also engaged in outsourcing these
technologies to the developing nations to enhance their waste to energy infrastructure. The Japanese government adopted the 3R initiative
and enforced laws to reduce waste and encourage capturing landfill gas
• Although thermal technology hold the largest share owing to incineration of high quantities of organic waste matter, biological treatment
methods are witnessing fastest growth on account of increasing focus on generation of biogas
• Japan aggressively promote the recycling of municipal
solid waste and the government urges the food &
beverage and other manufacturing industries and the
customers to recycle plastic and other food packaging
materials to reduce the reliance on landfills and waste
to energy incineration plants

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Japan Waste to Energy Market Revenue Share, By Type of Waste
Figure 34: Japan Waste to Energy Market Revenue Share, By Type of Waste, 2019 & 2025F
Source: MarkNtel Advisors

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