+353-1-416-8900REST OF WORLD
+44-20-3973-8888REST OF WORLD
1-917-300-0470EAST COAST U.S
1-800-526-8630U.S. (TOLL FREE)

PRINTER FRIENDLY

Green Ammonia Market by Technology (Alkaline Water Electrolysis (AWE), Proton Exchange Membrane (PEM), and Solid Oxide Electrolysis (SOE)), End User (Transportation, Power Generation, and Industrial Feedstock), and Region - Global Forecast to 2030

  • ID: 5130124
  • Report
  • July 2020
  • Region: Global
  • 155 Pages
  • Markets and Markets
The Global Green Ammonia Market is Projected to Reach USD 852 Million by 2030 from an Estimated USD 11 Million in 2020, at a CAGR of 54.9%

FEATURED COMPANIES

  • Aquahydrex
  • Enapter
  • Green Hydrogen Systems
  • Hydrogenics
  • MCPHY Energy
  • Siemens

The global green ammonia market is projected to grow at a CAGR of 54.9% from 2020 to 2030

Rising obligations to reduce greenhouse gas emissions from traditional ammonia methods have driven the global green ammonia market growth. Furthermore, increased agriculture production and subsequent rise in fertilizer consumption is driving the green ammonia market. However, higher initial capital requirements for green ammonia plant infrastructures is likely to hamper the growth of green ammonia market.  

The power generation segment, by end-user, is expected to be the largest and the fastest-growing market from 2020 to 2030

The end-user segment is categorized as transportation, power generation, and industrial feedstock. The power generation segment is expected to grow at the highest CAGR during the forecast period, as electricity generated by using green ammonia is observed to be the cleaner version of gas. By using the electrolysis process, surplus renewable energy generated at isolated locations can be used to produce carbon-free ammonia, which can act as a sustainable fuel for power generation. Furthermore, the need for long term storage of renewable energy generated at isolated wind farms and solar panels drives the growth of green ammonia market. Europe is expected to hold the largest power generation market. This growth is owing to the favourable government initiatives and plans to produce green ammonia in the Netherlands.

The Solid Oxide Electrolysis segment, by technology, is expected to be the fastest-growing market from 2020 to 2030

The SOE segment is expected to be the fastest-growing technology sub-segment during the forecast period, owing to the increasing demand for fuel cells. The SOE process is used to produce green hydrogen from surplus electricity generated from renewable sources. Such green hydrogen can be synthesised further in ammonia synthesis plant to produce green ammonia by using SOE technology. Moreover, the green hydrogen produced by the process can be stored and used as a fuel cell, and reconverted into electricity again when the demand arises. This allows the storage of electricity when production exceeds demand. This is driving the growth of the SOE segment in the global green ammonia market. Europe is projected to hold the largest SOE market by 2030, owing to the rising demand for fuel cells in Germany.

Europe: The largest and the fastest-growing region in the green ammonia market

Europe is expected to dominate the global green ammonia market between 2020 and 2030. The increasing number of fuel cell projects and European government initiatives for the deployment of fuel cells in the residential and commercial sectors are likely to provide growth opportunities for the growth of the green ammonia market in the region. Fuel cells are an efficient and clean energy alternative, which has the potential to address the energy challenges of the region. The Fuel Cells and Hydrogen Joint Undertaking is the primary body that supports R&D for fuel cell and hydrogen technologies in Europe.
 
Breakdown of Primaries:

In-depth interviews have been conducted with various key industry participants, subject-matter experts, C-level executives of key market players, and industry consultants, among other experts, to obtain and verify critical qualitative and quantitative information, as well as to assess future market prospects. The distribution of primary interviews is as follows:

  • By Company Type: Technology Providers- 60%, Ammonia Producers- 25%, and Ammonia Plant EPC companies- 15%
  • By Designation: C-Level- 30%, Director Level- 25%, and Others- 45%
  • By Region: Asia Pacific- 30%, Europe- 25%, North America- 25%, and Rest of the World- 20%

Note: Others includes sales managers, marketing managers, product managers, and product engineers.

The green ammonia market is dominated by a few major players that have a wide regional presence. The leading players in the green ammonia market are Siemens (Germany), MAN Energy Solutions (Germany), ITM Power (UK), Nel Hydrogen Solutions (Norway), Yara International (Norway) and Haldor Topsoe (Denmark).

Study Coverage:

The report defines, describes, and forecasts the green ammonia market, by technology, end-user and region. It also offers a detailed qualitative and quantitative analysis of the market. The report provides a comprehensive review of the major market drivers, restraints, opportunities, and challenges. It also covers various important aspects of the market, which include the analysis of the competitive landscape, market dynamics, market estimates in terms of value, and future trends in the green ammonia market.

Key Benefits of Buying the Report

1. The report identifies and addresses the key markets for green ammonia operations and services, which would help equipment manufacturers and service providers review the growth in demand.

2. The report helps system providers understand the pulse of the market and provides insights into drivers, restraints, opportunities, and challenges.

3. The report will help key players understand the strategies of their competitors better and help them in making better strategic decisions

Note: Product cover images may vary from those shown

FEATURED COMPANIES

  • Aquahydrex
  • Enapter
  • Green Hydrogen Systems
  • Hydrogenics
  • MCPHY Energy
  • Siemens

1 Introduction
1.1 Study Objectives
1.2 Definition
1.2.1 Green Ammonia Market: Inclusions and Exclusions
1.3 Market Scope
1.3.1 Market Segmentation
1.3.2 Regions Covered
1.3.3 Years Considered
1.4 Currency
1.5 Limitations
1.6 Stakeholders

2 Research Methodology
2.1 Research Data
Figure 1 Green Ammonia Market: Research Design
2.1.1 Secondary Data
2.1.1.1 Key Data from Secondary Sources
2.1.2 Primary Data
2.1.2.1 Key Data from Primary Sources
2.1.2.2 Breakdown of Primaries
Table 1 Green Ammonia Market: Players/Companies Connected
2.2 Scope
2.3 Market Size Estimation
2.3.1 Demand-Side Analysis
2.3.1.1 Assumptions
2.3.1.2 Limitations
2.3.1.3 Calculation
2.3.2 Supply-Side Analysis
2.3.2.1 Assumptions
2.3.2.2 Calculation
Figure 2 Ranking of Key Players & Industry Concentration, 2019
2.3.3 Forecast
2.3.3.1 Assumptions
2.3.3.2 Calculation
2.4 Market Breakdown and Data Triangulation
Figure 3 Data Triangulation Methodology
2.5 Primary Insights
2.5.1 Key Players’ Point of View

3 Executive Summary
3.1 Green Ammonia Market Snapshot
Figure 4 Europe Held Largest Share of Green Ammonia Market in 2019
Figure 5 Alkaline Water Electrolysis is Expected to Dominate Technology Landscape of Green Ammonia Market During Forecast Period
Figure 6 Power Generation Segment Led Green Ammonia Market, by End User, in 2019

4 Premium Insights
4.1 Attractive Opportunities in Green Ammonia Market
Figure 7 High Demand for Long-Term Power Storage Solutions to Supplement Green Ammonia Market Growth During 2020–2030
4.2 Green Ammonia Market, by Technology
Figure 8 Solid Oxide Electrolysis Technology is Expected to Record Highest CAGR from 2020 to 2030
4.3 Green Ammonia Market, by End User
Figure 9 Power Generation Segment is Expected to Capture Highest CAGR During Forecast Period
4.4 Green Ammonia Market, by Region
Figure 10 Green Ammonia Market in Europe is Expected to Grow at Highest CAGR During Forecast Period
4.5 Europe Green Ammonia Market, by End User & Country
Figure 11 Power Generation Segment, by End User, and Germany, by Country Dominated Europe Green Ammonia Market in 2019

5 Market Overview
5.1 Introduction
5.2 Covid-19 Health Assessment
Figure 12 Covid-19 Global Propagation
Figure 13 Covid-19 Propagation in Select Countries
5.3 Road to Recovery
Figure 14 Recovery Road for 2020
5.4 Covid-19 Economic Assessment
Figure 15 Revised GDP Forecast for Select G20 Countries in 2020
5.5 Market Dynamics
Figure 16 Green Ammonia Market: Drivers, Restraints, Opportunities, and Challenges
5.5.1 Drivers
5.5.1.1 Demand for Long-Term Storage of Renewable Energy
Figure 17 Global Renewable Energy Capacity Trend, by Source, 2010 - 2019
Table 2 Falling Power Generation Costs, 2010–2019
5.5.1.2 Obligations to Reduce Greenhouse Emissions from Traditional Ammonia Methods
Figure 18 Global Greenhouse Gas Emissions, by Sector, 2016
5.5.1.3 Increased Agricultural Production and Subsequent Rise in Fertilizers Consumption
Figure 19 Global Fertilizer Demand, by Nutrient Source, 2015–2020
5.5.2 Restraint
5.5.2.1 Higher Initial Capital Requirements for Green Ammonia Plant Infrastructure
5.5.3 Opportunities
5.5.3.1 Ammonia as Maritime Fuel
5.5.3.2 Increasing Focus On Hydrogen-Based Economy
5.5.4 Challenges
5.5.4.1 Low Awareness About Green Ammonia

6 Global Green Ammonia Market, by Technology
6.1 Introduction
Figure 20 by Technology, Solid Oxide Electrolysis is Expected to Grow at Highest CAGR from 2020 to 2030
Table 3 Global Green Ammonia Market, by Technology, 2018–2030 (USD Thousand)
6.2 Alkaline Water Electrolysis (Awe)
6.2.1 Low Capital Cost of Alkaline Water Electrolysis Systems Drives Market Growth
Table 4 Alkaline Water Electrolysis: Global Green Ammonia Market, by Region, 2018–2030 (USD Thousand)
6.3 Proton Exchange Membrane (Pem)
6.3.1 High-Purity Hydrogen Produced by PEM Process Drives Market Growth
Table 5 Proton Exchange Membrane: Global Green Ammonia Market, by Region, 2018–2030 (USD Thousand)
6.4 Solid Oxide Electrolysis (Soe)
6.4.1 Increasing Demand for Fuel Cells Boosts Demand for Solid Oxide Electrolysis
Table 6 Solid Oxide Electrolysis: Global Green Ammonia Market, by Region, 2018–2030 (USD Thousand)

7 Global Green Ammonia Market, by End User
7.1 Introduction
Figure 21 Power Generation Expected to Lead Global Green Ammonia Market, by End User, from 2020 to 2030
Table 7 Global Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
7.2 Transportation
7.2.1 Adoption of Fuel Cell in Transportation Drives Green Ammonia Market
Table 8 Transportation: Global Green Ammonia Market, by Region, 2018–2030 (USD Thousand)
7.3 Power Generation
7.3.1 Need for Long-Term Storage of Renewable Energy Generated at Isolated Wind Farms and Solar Panels Drives Growth of Green Ammonia Market
Table 9 Power Generation: Global Green Ammonia Market, by Region, 2018–2030 (USD Thousand)
7.4 Industrial Feedstock
7.4.1 Increasing Demand for Food Products Drives Demand for Green Fertilizers
Table 10 Industrial Feedstock: Global Green Ammonia Market, by Region, 2018–2030 (USD Thousand)

8 Global Green Ammonia Market, by Region
8.1 Introduction
Figure 22 European Countries Are Expected to Exhibit Relatively Higher Growth Rate During Forecast Period
Table 11 Green Ammonia Market, by Region, 2018–2030 (USD Thousand)
8.2 Europe
Figure 23 Europe: Green Ammonia Market Overview, 2019
8.2.1 Macro Factors
8.2.1.1 Ammonia Production
Table 12 Europe: Ammonia Production, by Country, 2015–2019(Thousand Tons)
8.2.1.2 Hydrogen Generation
Table 13 Europe: Hydrogen Generation, by Country, 2013–2017 (Million Standard Cubic Feet Per Day)
8.2.1.3 Installed Renewable Capacity
Table 14 Europe: Installed Renewable Capacity, by Country, 2015–2019 (MW)
8.2.1.4 Greenhouse Gas Emissions
Table 15 Europe: Greenhouse Gas Emissions, by Country, 2013–2017 (Million Tons of Co2)
8.2.2 by Technology
Table 16 Europe: Green Ammonia Market: by Technology, 2018–2030 (USD Thousand)
8.2.3 by End User
Table 17 Europe: Green Ammonia Market: by End User, 2018–2030 (USD Thousand)
8.2.3.1 End User by Country
Table 18 Transportation: Europe Green Ammonia Market: by Country, 2018–2030 (USD Thousand)
Table 19 Power Generation: Europe Green Ammonia Market: by Country, 2018–2030 (USD Thousand)
Table 20 Industrial Feedstock: Europe Green Ammonia Market: by Country, 2018–2030 (USD Thousand)
8.2.4 by Country
Table 21 Europe: Green Ammonia Market: by Country, 2018–2030 (USD Thousands)
8.2.4.1 Germany
8.2.4.1.1 Increase in Demand for Energy Storage Systems,
Such as Fuel Cells, Expected to Drive Green Ammonia Market in Germany
8.2.4.1.2 Macro Factors
Table 22 Germany: Ammonia Production, 2015–2019 (Thousand Tons)
Table 23 Germany: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 24 Germany: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 25 Germany: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.2.4.1.3 by End User
Table 26 Germany: Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.2.4.2 Uk
8.2.4.2.1 Investments in Green Fuel, Zero-Carbon Aviation, and Agriculture Drive Demand for Green Ammonia
8.2.4.2.2 Macro Factors
Table 27 Uk: Ammonia Production, 2015–2019 (Thousand Tons)
Table 28 Uk: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 29 Uk: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 30 Uk: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.2.4.2.3 by End User
Table 31 Uk: Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.2.4.3 Norway
8.2.4.3.1 Efforts for Decarbonizing Maritime Industry Drives
Green Ammonia Market in Norway
8.2.4.3.2 Macro Factors
Table 32 Norway: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 33 Norway: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.2.4.3.3 by End User
Table 34 Norway: Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.2.4.4 Denmark
8.2.4.4.1 Investments in Green Fuel and Large-Scale Green Energy Plans Drive Green Ammonia Market in Denmark
8.2.4.4.2 Macro Factors
Table 35 Denmark: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 36 Denmark: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.2.4.4.3 by End User
Table 37 Denmark: Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.2.4.5 Netherlands
8.2.4.5.1 Favorable Government Policies and Initiatives to Produce Green Hydrogen Expected to Drive Demand for Green Ammonia
8.2.4.5.2 Macro Factors
Table 38 Netherlands: Ammonia Production, 2015–2019 (Thousand Tons)
Table 39 Netherlands: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 40 Netherlands: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 41 Netherlands: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.2.4.5.3 by End User
Table 42 Netherlands: Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.3 Asia Pacific
8.3.1 Macro Factors
8.3.1.1 Ammonia Production
Table 43 Asia Pacific: Ammonia Production, by Country, 2015–2019 (Thousand Tons)
8.3.1.2 Hydrogen Generation
Table 44 Asia Pacific: Hydrogen Generation, by Country, 2013–2017 (Million Standard Cubic Feet Per Day)
8.3.1.3 Installed Renewable Capacity
Table 45 Asia Pacific: Installed Renewable Capacity, by Country, 2015–2019 (MW)
8.3.1.4 Greenhouse Gas Emissions
Table 46 Asia Pacific: Greenhouse Gas Emissions, by Country, 2013–2017 (Million Tons of Co2)
8.3.2 by Technology
Table 47 Asia Pacific: Green Ammonia Market: by Technology, 2018–2030 (USD Thousand)
8.3.3 by End User
Table 48 Asia Pacific: Green Ammonia Market: by End User, 2018–2030 (USD Thousand)
8.3.3.1 End User, by Country
Table 49 Transportation: Asia Pacific Green Ammonia Market: by Country, 2018–2030 (USD Thousand)
Table 50 Power Generation: Asia Pacific Green Ammonia Market: by Country, 2018–2030 (USD Thousand)
Table 51 Industrial Feedstock: Asia Pacific Green Ammonia Market: by Country, 2018–2030 (USD Thousand)
8.3.4 by Country
Table 52 Asia Pacific: Green Ammonia Market: by Country, 2018–2030 (USD Thousands)
8.3.4.1 Australia
8.3.4.1.1 Increase in Demand for Low-Carbon Green Hydrogen Driving Growth of Green Ammonia Market
8.3.4.1.2 Macro Factors
Table 53 Australia: Ammonia Production, 2015–2019 (Thousand Tons)
Table 54 Australia: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 55 Australia: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 56 Australia: Greenhouse Gas Emissions, 2013–20
(Million Tons of Co2)
8.3.4.1.3 by End User
Table 57 Australia: Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.3.4.2 Japan
8.3.4.2.1 Increase in Demand for Alkaline Electrolyzers to Conduct Water Electrolysis Driving Growth of Green Ammonia Market
8.3.4.2.2 Macro Factors
Table 58 Japan: Ammonia Production, 2015–2019 (Thousand Tons)
Table 59 Japan: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 60 Japan: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 61 Japan: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.3.4.2.3 by End User
Table 62 Japan: Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.3.4.3 New Zealand
8.3.4.3.1 Increasing Adoption of Electric Vehicles Leads to Renewable Energy Deployment at Larger Scale, Which Brings Opportunities for Green Ammonia Market
Table 63 New Zealand: Ammonia Production, 2015–2019 (Thousand Tons)
Table 64 New Zealand: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 65 New Zealand: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 66 New Zealand: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.3.4.3.2 by End User
Table 67 New Zealand: Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.4 North America
8.4.1 Macro Factors
8.4.1.1 Ammonia Production
Table 68 North America: Ammonia Production, by Country, 2015–2019 (Thousand Tons)
8.4.1.2 Hydrogen Generation
Table 69 North America: Hydrogen Generation, by Country, 2013–2017 (Million Standard Cubic Feet Per Day)
8.4.1.3 Installed Renewable Capacity
Table 70 North America: Installed Renewable Capacity, by Country, 2015–2019 (MW)
8.4.1.4 Greenhouse Gas Emissions
Table 71 North America: Greenhouse Gas Emissions, by Country, 2013–2017 (Million Tons of Co2)
8.4.2 by Technology
Table 72 North America: Green Ammonia Market: by Technology, 2018–2030 (USD Thousand)
8.4.3 by End User
Table 73 North America: Green Ammonia Market: by End User, 2018–2030 (USD Thousand)
8.4.3.1 End User, by Country
Table 74 Transportation: North America Green Ammonia Market: by Country, 2018–2030 (USD Thousand)
Table 75 Power Generation: North America Green Ammonia Market: by Country, 2018–2030 (USD Thousand)
Table 76 Industrial Feedstock: North America Green Ammonia Market: by Country, 2018–2030 (USD Thousand)
8.4.4 by Country
Table 77 North America: Green Ammonia Market: by Country, 2018–2030 (USD Thousands)
8.4.4.1 US
8.4.4.1.1 Increasing Government Support and Developing Hydrogen Infrastructure Fueling Green Ammonia Market Growth
8.4.4.1.2 Macro Factors
Table 78 Us: Ammonia Production, 2015–2019 (Thousand Tons)
Table 79 Us: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 80 Us: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 81 Us: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.4.4.1.3 by End User
Table 82 Us: Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.4.4.2 Canada
8.4.4.2.1 Increasing Fuel Cell Power Generation Boosting Demand for Green Hydrogen in Canada
Table 83 Canada: Ammonia Production, 2015–2019 (Thousand Tons)
Table 84 Canada: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 85 Canada: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 86 Canada: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.4.4.2.2 by End User
Table 87 Canada: Global Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.4.4.3 Mexico
8.4.4.3.1 Large Scale Refining Operations Expected to Drive Demand for Green Ammonia Market.
8.4.4.3.2 Macro Factors
Table 88 Mexico: Ammonia Production, 2015–2019 (Thousand Tons)
Table 89 Mexico: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 90 Mexico: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 91 Mexico: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.4.4.3.3 by End User
Table 92 Mexico: Global Green Ammonia Market, by End User, 2018–2030 (USD Thousand)
8.5 Rest of the World
8.5.1 Macro Factors
8.5.1.1 Ammonia Production
Table 93 Rest of the World: Ammonia Production, by Country, 2015–2019 (Thousand Tons)
8.5.1.2 Hydrogen Generation
Table 94 Rest of the World: Hydrogen Generation, by Country, 2013–2017 (Million Standard Cubic Feet Per Day)
8.5.1.3 Installed Renewable Capacity
Table 95 Rest of the World: Installed Renewable Capacity, by Country, 2015–2019 (MW)
8.5.1.4 Greenhouse Gas Emissions
Table 96 Rest of the World: Greenhouse Gas Emissions, by Country, 2013–2017 (Million Tons of Co2)
8.5.2 by Technology
Table 97 Rest of the World: Green Ammonia Market: by Technology, 2018–2030 (USD Thousand)
8.5.3 by End User
Table 98 Rest of the World: Green Ammonia Market: by End User, 2018–2030 (USD Thousand)
8.5.4 by Country
8.5.4.1 China
Figure 24 Fuel Cell Electric Vehicle Targets for China, 2018-2030
8.5.4.1.1 Macro Factors
Table 99 China: Ammonia Production, 2015–2019 (Thousand Tons)
Table 100 China: Hydrogen Generation, 2013–2017 (Million Standardcubic Feet Per Day)
Table 101 China: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 102 China: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.5.4.2 India
8.5.4.2.1 Macro Factors
Table 103 India: Ammonia Production, 2015–2019 (Thousand Tons)
Table 104 India: Hydrogen Generation, 2013–2017 (Million Standard
Cubic Feet Per Day)
Table 105 India: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 106 India: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.5.4.3 Russia
Figure 25 Share of Major Russian Ammonia Producers, 2019
8.5.4.3.1 Macro Factors
Table 107 Russia: Ammonia Production, 2015–2019 (Thousand Tons)
Table 108 Russia: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 109 Russia: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 110 Russia: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.5.4.4 France
8.5.4.4.1 Macro Factors
Table 111 France: Ammonia Production, 2015–2019 (Thousand Tons)
Table 112 France: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 113 France: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 114 France: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.5.4.5 Austria
8.5.4.5.1 Macro Factors
Table 115 Austria: Ammonia Production, 2015–2019 (Thousand Tons)
Table 116 Austria: Hydrogen Generation, 2013–2017 (Million Standard Cubic Feet Per Day)
Table 117 Austria: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 118 Austria: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.5.4.6 Chile
8.5.4.6.1 Macro Factors
Table 119 Chile: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 120 Chile: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)
8.5.4.7 Morocco
8.5.4.7.1 Macro Factors
Table 121 Morocco: Installed Renewable Capacity, by Source, 2015–2019 (MW)
Table 122 Morocco: Greenhouse Gas Emissions, 2013–2017 (Million Tons of Co2)

9 Competitive Landscape
9.1 Overview
Figure 26 Key Developments in Global Green Ammonia Market, 2018–June 2020
9.2 Industry Concentration, 2019
Figure 27 Ranking of Key Players & Industry Concentration, 2019
9.3 Competitive Scenario
Table 123 Developments of Key Players in Market, 2018–2020
9.3.1 Product Launches
9.3.2 Contracts & Agreements
9.3.3 Partnerships/Joint Ventures/Collaborations
9.4 Winners Vs. Tail-Enders
9.4.1 Winners
9.4.2 Tail Enders

10 Company Profiles
10.1 Technology Providers
(Business Overview, Products/Solutions/Services Offered, Recent Developments, SWOT Analysis, and Mnm View)*
10.1.1 Siemens
Figure 28 Siemens: Company Snapshot
Figure 29 Siemens: SWOT Analysis
10.1.2 Man Energy Solutions
Figure 30 Man Energy Solutions: SWOT Analysis
10.1.3 NEL Hydrogen
Figure 31 NEL Hydrogen: Company Snapshot
Figure 32 NEL Hydrogen: SWOT Analysis
10.1.4 Thyssenkrupp
Figure 33 Thyssenkrupp: Company Snapshot
Figure 34 Thyssenkrupp: SWOT Analysis
10.1.5 ITM Power
Figure 35 ITM Power: Company Snapshot
Figure 36 ITM Power: SWOT Analysis
10.1.6 Green Hydrogen Systems
10.1.7 MCPHY Energy
Figure 37 MCPHY Energy: Company Snapshot
10.1.8 Electrochaea
10.1.9 Hydrogenics
10.1.10 Aquahydrex
10.1.11 Exytron
10.1.12 Uniper
Figure 38 Uniper: Company Snapshot
10.1.13 Enapter
10.1.14 Starfire Energy
10.1.15 Engie
Figure 39 Engie: Company Snapshot
10.2 Chemical Providers
10.2.1 Yara International
Figure 40 Yara International: Company Snapshot
10.2.2 BASF
Figure 41 BASF: Company Snapshot
10.2.3 Queensland Nitrates
10.3 Ammonia Plant Epc Companies
10.3.1 Haldor Topsoe
Figure 42 Haldor Topsoe: Company Snapshot
10.3.2 Hiringa Energy
* Business Overview, Products/Solutions/Services Offered, Recent Developments, SWOT Analysis, and Mnm View Might Not Be Captured in Case of Unlisted Companies.

11 Appendix
11.1 Insights of Industry Experts
11.2 Discussion Guide
11.3 Knowledge Store: Subscription Portal
11.4 Available Customizations
11.5 Related Reports
11.6 Author Details

Note: Product cover images may vary from those shown

Loading
LOADING...

  • Aquahydrex
  • BASF
  • Electrochaea
  • Enapter
  • Engie
  • Exytron
  • Green Hydrogen Systems
  • Haldor Topsoe
  • Hiringa Energy
  • Hydrogenics
  • ITM Power
  • Man Energy Solutions
  • MCPHY Energy
  • NEL Hydrogen
  • Queensland Nitrates
  • Siemens
  • Starfire Energy
  • Thyssenkrupp
  • Uniper
  • Yara International
Note: Product cover images may vary from those shown

Loading
LOADING...

Adroll
adroll