Global Hydrogen Market Outlook - Overview & Analysis of Entire Value Chain, including 29 National Hydrogen Strategies & 39 Large-scale Hydrogen Valleys, plus 10 Leading Companies & Profiles of Electrolyzers, Compressors, and Fuel Cell Manufacturers

Description

Hydrogen is the most abundant naturally occurring element in the universe which can be produced at a large scale using renewable energy. It is emerging as an efficient and alternate fuel and will play a key role in achieving the climate pledge of net zero emissions by 2050. As hydrogen has potential applications in several sectors, its demand is increasing day and day, which is inadvertently causing an abrupt increase in the production of hydrogen. Several hydrogen valleys have been announced around the world which when completed, will play a major role in meeting the global hydrogen demand. Several countries around the world have come up with policy frameworks termed national hydrogen strategies to support and accelerate the adoption of hydrogen technologies. As the hydrogen economy continues to grow globally, not only the existing players are expanding their footprint in the hydrogen value chain but also new players are entering the market, therefore, it is imperative to understand the capabilities of companies involved in the hydrogen value chain.

‘The Global Hydrogen Market Outlook Report’ provides a holistic overview of the hydrogen market across the world. The report is divided into four sections: Hydrogen Market Overview, National Hydrogen Strategies, Hydrogen Valleys, and Company Profiles. It provides a global outlook of the hydrogen market, covering Asia-Pacific (APAC), Europe, Middle-East and Africa (MEA), and the North and South American regions. 29 National Hydrogen Strategies, 39 Hydrogen Valleys and 10 company profiles each of electrolyzer, compressor, and fuel cell manufacturers have been highlighted in the report along with a detailed analysis of the entire value chain of hydrogen from hydrogen production to its end-use.

Facts/Data points:

Project completions involving electrolyzer installations for energy purposes reached an estimated 65 MWe globally in 2020 and grew exponentially to 286 MWe in 2021.

Planned small-scale projects pipeline in almost 30 countries indicate global electrolyzer capacity could reach approximately 17 GW by 2026.

Planned large-scale projects pipeline indicates that global electrolyzer capacity could reach 8.7 GW by 2026.

If planned projects are commissioned by 2026, China, Chile, Spain, and Australia could together bring 85% of the additional 18 GW of renewable capacity dedicated to green hydrogen production.

Within Europe there are over 750 announced projects from all parts of the value chain that are expected to enter operation by 2025.

Global hydrogen demand has increased with a CAGR of 2% from 60 Mt to 90 Mt since the start of this century.

Global hydrogen demand from all sources of hydrogen production is expected to be approximately 500 Mt by 2050.

The European continent leads other regions when it comes to published national hydrogen strategies as 18 countries in the European continent have published their respective national hydrogen strategy.

Europe is followed by APAC (5), the Americas (4), and Middle East and African (2) regions.

There are 39 hydrogen valleys in 21 countries around the world.

Hydrogen Valleys act as a platform for the emerging hydrogen economy with 97% of the hydrogen production being focused on producing hydrogen through electrolysis using renewables.

Polymer Electrolyte Membrane (PEM) technology is the most employed electrolysis technology for green hydrogen production in these valleys which makes up 50% of the total share followed by Alkaline electrolysis technology at 13%.

88% of the hydrogen produced in these valleys is preferred to be stored in the form of compressed hydrogen gas or liquid hydrogen.

85% of hydrogen will be transported through trucks and pipelines whereas 50% of it will be used in chemical, refinery, and steel industries whereas the rest of it is expected to be used in other industries such as mobility, power generation, etc.

Countries Covered:

1. Global

2. Americas

i. Canada
ii. Chile
iii. Colombia
iv. Uruguay
v. USA

3. Asia-Pacific (APAC)

i. Australia
ii. China
iii. India
iv. Japan
v. New Zealand
vi. South Korea

5. Middle-East and Africa (MEA)

i. Morocco
ii. South Africa

4. Europe

i. Austria
ii. Belgium
iii. Czech Republic
iv. Denmark
v. Finland
vi. France
vii. Hungary
viii. Italy
ix. Netherlands
x. Norway
xi. Poland
xii. Portugal
xiii. Russia
xiv. Slovakia
xv. Spain
xvi. Sweden
xvii. United Kingdom

Product Code: S3000

1. Overview

i. Properties of Hydrogen
ii. Hydrogen as Energy Vector. Why Now?

2. Value Chain Analysis

i. Production
- i. Types of Hydrogen
- ii. The Different Colors of Hydrogen
- iii. Hydrogen Production Process
- iv. Hydrogen Production Technologies
- v. Blue Hydrogen: A Scam or Savior?
- vi. Green Hydrogen Prodcution Through Electrolysis
- vii. Comparative Analysis of Electrolyzer Technologies
- viii. Key Global Electrolyzer Manufacturing Sites
ii. Storage
- a. Established Technologies for Hydrogen Storage
- b. Emerging Technologies for Hydrogen Storage
iii. Transportation
- a. Overview of Hydrogen Transportation Methods
- b. Comparison of Potential Hydrogen Carriers
- c. Cost Comparison of Potential Hydrogen Carriers
iv. End-Use Consumption
- a. Hydrogen in Refining Operations
  - I. Hydrogen Production and Consumption in Refining Operations
  - II. Hydrogen Process Flow Chart in Refining Operations
  - III. Hydrogen Compressors in Refining Operations
- b. Hydrogen in Ammonia Production
  - I. Ammonia Production through Haber-Bosch Process
- c. Hydrogen in Steel Making
  - I. Steel Making through Direct Reduced Iron (DRI) Method
  - II. Outotec - Reduced Direct Iron Process
  - III. Midrex H2 Direct Reduced Iron Process
- d. Hydrogen in Petrochemical Industry
- e. Hydrogen in Buildings
- f. Hydrogen in Power Sector
- g. Hydrogen in Mobility (Road Transport)
  - I. Comparative Analysis of of BEVs and Hydrogen FCEVs
  - II. Constraints and Advantages of FCEVs as compared to BEVs
- h. Hydrogen in Aviation
- i. Hydrogen in Rail
- j. Hydrogen in Maritime

3. Hydrogen Demand Forecast: An Overview of Next 30 Years

i. Global Hydrogen Demand Driving Factors
ii. Global Hydrogen Demand Outlook-2021
iii. Key Inhibitors and Accelerators to the Hydrogen Market
iv. Global Hydrogen Demand Forecast
- a. High Case Scenario
- b. Base Case Scenario
- c. Low Case Scenario
- v. Analysis of Hydrogen Demand Over Next 30 Years

4. Geographical Significance of Hydrogen

i. Hydrogen Potential Across the World
ii. Global Overview of National Hydrogen Strategies
iii. Hydrogen Valleys Across the Globe
iv. Key Players Across the Globe

5. National Hydrogen Strategies

i. Americas
- a. Regional Overview
- b. Country-Specific Overview
  - I. Canada
  - II. Chile
  - III. Colombia
  - IV. Uruguay
ii. Asia-Pacific (APAC)
- a. Regional Overview
- b. Country-Specific Overview
  - I. Australia
  - II. India
  - III. Japan
  - IV. South Korea
iii. Europe
- a. Regional Overview
  - I. European Union
- b. Country-Specific Overview
  - I. Austria
  - II. Belgium
  - III. Czech Republic
  - IV. Denmark
  - V. Finland
  - VI. France
  - VII. Hungary
  - VIII. Italy
  - IX. Netherlands
  - X. Norway
  - XI. Poland
  - XII. Portugal
  - XIII. Russia
  - XIV. Slovakia
  - XV. Spain
  - XVI. Sweden
  - XVII. United Kingdom
iv. Middle-East and Africa (MEA)
- a. Regional Overview
- b. Country-Specific Overview
  - I. Morocco
  - II. South Africa
v. Strategies Under Preparation
- a. China
- b. New Zealand
- c. USA

6. Large-Scale Hydrogen Valleys

i. Americas
- a. Detailed Overview of Hydrogen Valleys
- b. Hydrogen Valleys by Application
ii. Asia-Pacific (APAC)
- a. Detailed Overview of Hydrogen Valleys
- b. Hydrogen Valleys by Application
iii. Europe
- a. Detailed Overview of Hydrogen Valleys
- b. Hydrogen Valleys by Application
iv. Middle-East and Africa (MEA)
- a. Detailed Overview of Hydrogen Valleys
- b. Hydrogen Valleys by Application

7. Company Profiles

i. Electrolyzer Manufacturers
- a. Enapter
- b. NEL Hydrogen
- c. ITM Power
- d. Plug Power
- e. Sunfire
- f. McPhy
- g. Elogen
- h. Green Hydrogen Systems
- i. Ohmium
- j. Thyssenkrupp
ii. Compressor Manufacturers
- a. PDC Machines
- b. Sundyne
- c. NASH
- d. Baker Hughes
- e. Burckhardt Compression
- f. Linde
- g. Neuman & Esser (NEA) Group
- h. Howden
- i. Ariel Corporation
- j. MAN Energy Solutions
iii. Fuel Cell Manufacturers
- a. Ballard Power Systems
- b. Bloom Energy
- c. GenCell
- d. Toshiba Energy Systems & Solutions
- e. Bosch
- f. Panasonic
- g. Loop Energy
- h. AFC Energy
- i. Advent Technologies
- j. FuelCell Energy

8. About PTR

Table of Exhibits*

1.Properties of Hydrogen
2.The Hydrogen Value Chain
3.Hydrogen Pathways
4.Types of Hydrogen
5.The Different Colors of Hydrogen
6.Hydrogen Production Process
7.Characteristics of Electrolyzer Technologies
8.Advantages of Electrolyzer Technologies
9.Disadvantages of Electrolyzer Technologies
10.Capacity of Electrolyzers for Hydrogen Production by Commissioning Year, By Intended Use of Hydrogen (2010-2021)
11.Capacity of Electrolyzers for Hydrogen Production in 2021, By Intended Use of Hydrogen
12.Small Electrolysis Projects 2020-2026 (1-10 MW)
13.Large Electrolysis Announced Projects 2021-2026 (10-100 MW)
14.Key Global Electrolyzer Manufacturing Sites
15.Electrolyzer Capacity by Region (2030, 2050)
16.Types of Hydrogen Storage Techniques
17.Established Technologies for Hydrogen Storage
18.Emerging Technologies for Hydrogen Storage
19.Types of Hydrogen Transportation Methods
20.Comparison of Potential Hydrogen Carriers
21.Cost Comparison of Potential Hydrogen Carriers
22.Simplified Flow Diagram of Auto-Thermal Reforming with a Carbon Capture and Storage (ATR-CCS) Plant.
23.Simplified Flow Diagram of Steam Methane Reforming with a Carbon Capture and Storage (SMR-CCS) Plant.
24.Hydrogen Process Flow Chart in Refining Operations
25.Hydrogen in Ammonia Production
26.Direct Reduced Iron (DRI) Method: Blast Furnace Route & Hybrit Route
27.Outotec DRI Method
28.Midrex H2 DRI Method
29.Hydrogen in Petrochemical Industry
30.Technical comparison of BEVs and Hydrogen FCEVs
31.Constraints and advantages of BEVs and Hydrogen FCEVs
32.Global Hydrogen Demand (2000-2020)
33.Global Hydrogen Demand by Region-2021
34.Global Hydrogen Demand by Application-2021
35.Key Inhibitors and Accelerators to the Hydrogen Market
36.High Case Scenario Global Temperature less than 1.8°C (2030-2050)
37.Base Case Scenario Global Temperature 1.8-2.3°C (2030-2050)
38.Low Case Scenario Global Temperature greater than 2.3°C (2030-2050)
39.Hydrogen Potential Across the World
40.Global Overview of National Hydrogen Strategies
41.Hydrogen Valleys Across the Globe
42.Key Players Across the Globe
43.Regional Overview of National Strategies: Americas
44.Regional Overview of National Strategies: APAC
45.Regional Overview of National Strategies: Europe
46.Regional Overview of National Strategies: MEA
47.Hydrogen Valleys by Application: Americas
48.Hydrogen Valleys by Application: APAC
49.Hydrogen Valleys by Application: Europe
50.Hydrogen Valleys by Application: MEA