Thanks to this Hybrid Master's Degree, you will lead the most innovative projects in the field of Hydrogen and ensure their adequacy to both technical and regulatory requirements"

In the context of the global search for sustainable alternatives to fossil fuels, Hydrogen Technology emerges as a promising solution due to its potential to provide clean and sustainable energy. Faced with this situation, professionals need to update their knowledge frequently to keep abreast of developments in this emerging and constantly evolving sector. In this way, engineers will be able to incorporate aspects such as recent developments in fuel cells and advanced storage systems into their practice. However, this can be a challenge as most of the educational programs on the market are limited to the mere transmission of knowledge.

However, this can be a challenge as most of the educational programs on the market are limited to the mere transmission of knowledge. The academic itinerary will provide a review of recent innovations in the production, storage and use of Hydrogen, highlighting how these technologies can be integrated into existing energy systems.  At the same time, the syllabus will delve into the regulatory aspects currently in force regarding the use of hydrogen. Thanks to this, graduates will carry out good practices in the implementation of the safety plan. Also the didactic materials will delve into the analysis of Green Hydrogen production plans, so that graduates will be able to develop highly sustainable projects that reinforce their social responsibility.

Regarding the methodology of this university program, it consists of two stages. The first is theoretical and is taught in a convenient 100% online format. In this sense, TECH uses its disruptive Relearning system to guarantee a progressive and natural learning, which does not require extra efforts such as the traditional memorization. Afterwards, the program includes a practical stay of 3 weeks in a reference entity linked to Hydrogen Technology. This will allow graduates to take what they have learned to the practical field, in a real work scenario in the company of a team of experienced professionals in this area.

Are you looking to incorporate into your praxis the most sophisticated tools to perform techno-economic analysis? Thanks to this program you will accurately assess the feasibility of Hydrogen Technologies"

This Hybrid Master's Degree in Hydrogen Technology contains the most complete and up-to-date scientific program on the market. The most important features include:

• Development of more than 100 case studies presented by Hydrogen Technology professionals
• Its graphic, schematic and practical contents provide essential information on those disciplines that are indispensable for professional practice
• Emphasis on the safest techniques for storage, transportation and distribution of Hydrogen
• Highly knowledgeable about current Hydrogen regulatory issues
• Emphasis on sustainable and environmentally friendly practices
• All of this will be complemented by theoretical lessons, questions to the expert, debate forums on controversial topics, and individual reflection assignments
• Content that is accessible from any fixed or portable device with an Internet connection
• Furthermore, you will be able to carry out an internship in one of the best companies

You will have a 3 week internship in a well known company, where you will participate in initiatives of storage, transport and use of Hydrogen"

In this proposal of Master’s Degree, of professionalizing character and blended learning modality, the program is aimed at updating engineers who develop their functions in different industries and require a high level of qualification. The contents are based on the latest scientific evidence, and oriented in a didactic way to integrate theoretical knowledge in the practice of Hydrogen Technology, and the theoretical-practical elements will facilitate the updating of knowledge and allow informed decision making. 

Thanks to its multimedia content elaborated with the latest educational technology, they will allow the engineering professional a situated and contextual learning, that is, a simulated environment that will provide an immersive learning programmed to learn in real situations. This program is designed around Problem-Based Learning, whereby the physician must try to solve the different professional practice situations that arise during the course. For this purpose, students will be assisted by an innovative interactive video system created by renowned and experienced experts.

This university program allows you to practice in simulated environments, which provide immersive learning programmed to prepare in real situations"

You will be able to participate in research and development activities. You will contribute to the advancement of knowledge in Hydrogen Technologies"

The didactic materials that make up this Hybrid Master's Degree are designed by a prestigious teaching staff, made up of specialists with a broad professional background in Hydrogen Technology. In this way, they have created a top quality syllabus that adapts to the demands of the current labor market. In this sense, the syllabus will delve into aspects ranging from Hydrogen Production and Electrolysis or Vehicle Refueling Stations to regulatory aspects. In addition, the program will allow students to develop advanced competencies for the storage, transport and distribution of hydrogen.

This program gives you the opportunity to update your knowledge in a real scenario, with the maximum scientific rigor of an institution at the forefront of technology"

Module 1. Hydrogen as an Energy Vector

1.1. Hydrogen as an Energy Vector. Global Context and Necessity

1.1.1. Political and Social Context
1.1.2. Paris CO2 Emission Reduction Commitment
1.1.3. Circularity

1.2. Hydrogen Development

1.2.1. Discovery and Production of Hydrogen
1.2.2. Role of Hydrogen in Industrial Society
1.2.3. Hydrogen at Present

1.3. Hydrogen as a Chemical Element: Properties

1.3.1. Properties
1.3.2. Permeability
1.3.3. Flammability and Buoyancy Index

1.4. Hydrogen as a Fuel

1.4.1. Hydrogen Production
1.4.2. Hydrogen Storage and Distribution
1.4.3. The Use of Hydrogen as a Fuel

1.5. Hydrogen Economy

1.5.1. Decarbonization of the Economy
1.5.2. Renewable Energy Sources
1.5.3. The Road to the Hydrogen Economy

1.6. Hydrogen Value Chain

1.6.1. Production
1.6.2. Storage and Transportation
1.6.3. End-Uses

1.7. Integration with Existing Energy Infrastructures: Hydrogen as an Energy Vector

1.7.1. Regulations
1.7.2. Problems Associated with Hydrogen Embrittlement
1.7.3. Integration of Hydrogen in Energy Infrastructures. Trends and Realities

1.8. Hydrogen Technologies. Status

1.8.1. Hydrogen Technologies
1.8.2. Technologies under Development
1.8.3. Key Projects for Hydrogen Development

1.9. "Relevant” Type Projects

1.9.1. Production Projects
1.9.2. Flagship Projects in Storage and Transportation
1.9.3. Projects for the Application of Hydrogen as an Energy Vector

1.10. Hydrogen in the Global Energy Mix: Current Situation and Prospects

1.10.1. The Energy Mix. Global Context
1.10.2. Hydrogen in the Energy Mix. Current Situation
1.10.3. Development Pathways for Hydrogen. Perspectives

Module 2. Hydrogen Production and Electrolysis

2.1. Fossil Fuel Production

2.1.1. Hydrocarbon Reforming Production
2.1.2. Generation by Pyrolysis
2.1.3. Coal Gasification

2.2. Production From Biomass

2.2.1. Hydrogen Production by Biomass Gasification
2.2.2. Hydrogen Generation by Biomass Pyrolysis
2.2.3. Aqueous Reforming

2.3. Biological Production

2.3.1. Water Gas Shift Reaction (WGSR)
2.3.2. Dark Fermentation for Biohydrogen Generation
2.3.3. Photofermentation of Organic Compounds for Hydrogen Production

2.4. By-Product of Chemical Processes

2.4.1. Hydrogen as a By-Product of Petrochemical Processes
2.4.2. Hydrogen as a By-Product of Caustic Soda and Chlorine Production
2.4.3. Synthesis Gas as a By-Product Generated in Coke Ovens

2.5. Water Separation

2.5.1. Photolytic Hydrogen Formation
2.5.2. Hydrogen Generation by Photocatalysis
2.5.3. Hydrogen Production by Thermal Separation of Water

2.6. Electrolysis: the Future of Hydrogen Generation

2.6.1. Hydrogen Generation by Electrolysis
2.6.2. Oxidation-Reduction Reaction
2.6.3. Thermodynamics of Electrolysis

2.7. Electrolysis Technologies

2.7.1. Low Temperature Electrolysis: Alkaline and Anionic Technology
2.7.2. Low Temperature Electrolysis: PEM
2.7.3. High Temperature Electrolysis

2.8. Stack: the Heart of an Electrolyzer

2.8.1. Materials and Components in Low-Temperature Electrolysis
2.8.2. Materials and Components in High-Temperature Electrolysis
2.8.3. Stack Assembly in Electrolysis

2.9. Balance of Plant and System

2.9.1. Balance of Plant Components
2.9.2. Balance of Plant Design
2.9.3. Balance of Plant Optimization

2.10. Technical and Economic Characterization of Electrolyzers

2.10.1. Capital and Operating Costs
2.10.2. Technical Characterization of an Electrolyzer Operation
2.10.3. Techno-Economic Modeling

Module 3. Hydrogen Storage, Transportation and Distribution

3.1. Hydrogen Storage, Transportation, and Distribution Forms

3.1.1. Hydrogen Gas
3.1.2. Liquid Hydrogen
3.1.3. Hydrogen Storage in Solid State

3.2. Hydrogen Compression

3.2.1. Hydrogen Compression. Necessity
3.2.2. Problems Associated with the Compression of Hydrogen
3.2.3. Equipment

3.3. Gaseous State Storage

3.3.1. Problems Associated with Hydrogen Storage
3.3.2. Types of Storage Tanks
3.3.3. Storage Tank Capacities

3.4. Transportation and Distribution in Gaseous State

3.4.1. Transportation and Distribution in Gaseous State
3.4.2. Distribution by Road
3.4.3. Use of the Distribution Network

3.5. Hydrogen Storage, Transportation and Distribution as Liquid

3.5.1. Process and Conditions
3.5.2. Equipment
3.5.3. Current State

3.6. Storage, Transportation and Distribution as Methanol

3.6.1. Process and Conditions
3.6.2. Equipment
3.6.3. Current State

3.7. Storage, Transportation and Distribution as Green Ammonia

3.7.1. Process and Conditions
3.7.2. Equipment
3.7.3. Current State

3.8. Storage, Transportation and Distribution as LOHC (Liquid Organic Hydrogen)

3.8.1. Process and Conditions
3.8.2. Equipment
3.8.3. Current State

3.9. Hydrogen Export

3.9.1. Hydrogen Export. Necessity
3.9.2. Green Hydrogen Production Capabilities
3.9.3. Transport Technical Comparison

3.10. Comparative Techno-Economic Analysis of Alternatives for Large Scale Logistics

3.10.1. Cost of Hydrogen Export
3.10.2. Comparison between Different Means of Transportation
3.10.3. The Reality of Large-Scale Logistics

Module 4. Hydrogen End-Uses

4.1. Industrial Uses of Hydrogen

4.1.1. Hydrogen at Industries
4.1.2. Origin of Hydrogen Used in Industry. Environmental Impact
4.1.3. Industrial Uses in the Industry

4.2. Industries and Hydrogen e-Fuels Production

4.2.1. e-Fuel Versus Traditional Fuels
4.2.2. Classification of e-Fuels
4.2.3. Current Status of e-Fuels

4.3. Production of Ammonia: Haber-Bosch Process

4.3.1. Nitrogen in Figures
4.3.2. Haber-Bosch Process. Process and Equipment
4.3.3. Environmental Impact

4.4. Hydrogen in Refineries

4.4.1. Hydrogen in Refineries. Necessity
4.4.2. Hydrogen Used Today. Environmental Impact and Cost
4.4.3. Short- and Long-Term Alternatives

4.5. Hydrogen in Steel Mills

4.5.1. Hydrogen in Steel Mills. Necessity
4.5.2. Hydrogen Used Today. Environmental Impact and Cost
4.5.3. Short- and Long-Term Alternatives

4.6. Natural Gas Substitution: Blending

4.6.1. Mixing Properties
4.6.2. Problems and Required Improvements
4.6.3. Opportunities

4.7. Injection of Hydrogen into the Natural Gas Grid

4.7.1. Methodology
4.7.2. Current Capabilities
4.7.3. Problems

4.8. Hydrogen in Mobility: Fuel Cell Vehicles

4.8.1. Context and Necessity
4.8.2. Equipment and Schemes
4.8.3. Present

4.9. Cogeneration and Production of Electricity with Fuel Cells

4.9.1. Fuel Cell Production
4.9.2. Discharge to the Grid
4.9.3. Microgrids

4.10. Others Hydrogen End-Uses: Chemical, Semiconductor, Glass Industry

4.10.1. Chemical Industry
4.10.2. Semiconductor Industry
4.10.3. Glass Industry

Module 5. Hydrogen Fuel Cells

5.1. PEMFC (Proton-Exchange Membrane Fuel Cell) Fuel Cells

5.1.1. Chemistry Governing PEMFCs
5.1.2. Operation of the PEMFC
5.1.3. PEMFC Applications

5.2. Membrane-Electrode Assembly in PEMFCs

5.2.1. MEA Materials and Components
5.2.2. PEMFC Catalysts
5.2.3. Circularity in PEMFC

5.3. Stack in PEMFC Piles

5.3.1. Stack Architecture
5.3.2. Assembly
5.3.3. Power Generation

5.4. Balance of Plant and PEMFC Stack System

5.4.1. Balance of Plant Components
5.4.2. Balance of Plant Design
5.4.3. System Optimization

5.5. SOFC (Sodium Oxide Fuel Cells) Fuel Cells

5.5.1. Chemistry Governing SOFCs
5.5.2. SOFCs Operation
5.5.3. Applications

5.6. Other Types of Fuel Cells: Alkaline, Reversible, Direct Methanation, etc.

5.6.1. Alkaline Fuel Cells
5.6.2. Reversible Fuel Cells
5.6.3. Direct Methanation Fuel Cells

5.7. Applications of Fuel Cells I. In Mobility, Electric Power Generation, Thermal Generation

5.7.1. Fuel Cells in Mobility
5.7.2. Fuel Cells in Power Generation
5.7.3. Fuel Cells in Thermal Generation

5.8. Fuel Cell Applications II. Techno-Economic Modeling

5.8.1. Technical and Economic Characterization of the PEMFC
5.8.2. Capital and Operating Costs
5.8.3. Technical Characterization of the Operation of a PEMFC
5.8.4. Techno-Economic Modeling

5.9. Dimensioning of PEMFC for Different Applications

5.9.1. Static Modeling
5.9.2. Dynamic Modeling
5.9.3. PEMFC Integration in Vehicles

5.10. Stationary Fuel Cells Grid Integration

5.10.1. Stationary Fuel Cells in Renewable Microgrids
5.10.2. System Modeling
5.10.3. Techno-Economic Study of a Fuel Cell in Stationary Use

Module 6. Hydrogen Refueling Stations

6.1. Hydrogen Vehicle Refueling Corridors and Networks

6.1.1. Hydrogen Vehicle Refueling Networks. Current State
6.1.2. Global Hydrogen Vehicle Refueling Station Deployment Targets
6.1.3. Cross-border Corridors for Hydrogen Refueling.

6.2. Hydrogen Plant Types, Modes of Operation and Dispensing Categories

6.2.1. Types of Hydrogen Refueling Station 
6.2.2. Operating Modes of the Hydrogen Refueling Stations
6.2.3. Dispensing Categories According to Standards

6.3. Design Parameters

6.3.1. Hydrogen Refueling Station. Components
6.3.2. Design Parameters according to Hydrogen Storage Type
6.3.3. Design Parameters according to the Station's Target Use

6.4. Storage and Pressure Levels

6.4.1. Storage of Hydrogen Gas at Hydrogen Refueling Stations
6.4.2. Gas Storage Pressure Levels
6.4.3. Liquid Hydrogen Storage in Hydrogen Refueling Stations

6.5. Compression Stages

6.5.1. Hydrogen Compression. Necessity
6.5.2. Compression Technologies
6.5.3. Optimization

6.6. Dispensing and Precooling

6.6.1. Precooling according to Regulations and Vehicle Type. Necessity
6.6.2. Hydrogen Dispensing Cascade
6.6.3. Thermal Phenomena of Dispensing

6.7. Mechanical Integration

6.7.1. Refueling Stations with On-Site Hydrogen Production
6.7.2. Refueling Stations without Hydrogen Production
6.7.3. Modularization

6.8. Preliminary Design of a Hydrogen Plant

6.8.1. Presentation of the Case Study
6.8.2. Development of the Case Study
6.8.3. Resolution

6.9. Cost Analysis

6.9.1. Capital and Operating Costs
6.9.2. Technical Characterization of a Hydrogen Refueling Station Operation
6.9.3. Techno-Economic Modeling

Module 7. Hydrogen Markets

7.1. Energy Markets

7.1.1. Integration of Hydrogen in the Gas Market
7.1.2. Interaction of Hydrogen Price with Fossil Fuels Prices
7.1.3. Interaction of the Hydrogen Price with the Electricity Market Price

7.2. Calculation of LCOHs and Sales Price Bands

7.2.1. Presentation of the Case Study
7.2.2. Development of the Case Study
7.2.3. Resolution

7.3. Global Demand Analysis

7.3.1. Current Hydrogen Demand
7.3.2. Hydrogen Demand Derived from New Uses
7.3.3. Objectives to 2050

7.4. Analysis of Hydrogen Production and Types of Hydrogen

7.4.1. Current Hydrogen Production
7.4.2. Green Hydrogen Production Plans
7.4.3. Impact of Hydrogen Production on the Global Energy System

7.5. International Roadmaps and Plans

7.5.1. Submission of International Plans
7.5.2. Analysis of International Plans
7.5.3. Comparison between Different International Plans

7.6. Green Hydrogen Market Potential

7.6.1. Green Hydrogen into the Natural Gas Grid
7.6.2. Green Hydrogen in Mobility
7.6.3. Green Hydrogen in Industries

7.7. Analysis of Large-Scale Projects in the Deployment Phase: USA, Japan, Europe, China

7.7.1. Project Selection
7.7.2. Analysis of Selected Projects
7.7.3. Conclusions

7.8. Centralization of Production: Countries with Export and Import Potential

7.8.1. Renewable Hydrogen Production Potential
7.8.2. Renewable Hydrogen Import Potential
7.8.3. Transportation of Large Volumes of Hydrogen

7.9. Guarantees of Origin

7.9.1. Need for a System of Guarantees of Origin
7.9.2. CertifHy
7.9.3. Approved Systems of Guarantees of Origin

7.10. Hydrogen Supply Contracts: Offtake Contracts

7.10.1. Importance of Offtake Contracts for Hydrogen Projects
7.10.2. Keys to Offtake Contracts: Price, Volume and Duration
7.10.3. Review of a Standard Contract Structure

Module 8. Explain the System of Guarantees of Origin and the Need For It

8.1. EU Policies

8.1.1. European Hydrogen Strategy
8.1.2. REPowerEU Plan
8.1.3. Hydrogen Roadmaps in Europe

8.2. Incentive Mechanisms for the Deployment of the Hydrogen Economy

8.2.1. Need for Incentive Mechanisms for the Deployment of the Hydrogen Economy
8.2.2. Incentives at European Level
8.2.3. Examples of Incentives in European Countries

8.3. Regulation Applicable to Production and Storage, Use of Hydrogen in Mobility and in the Gas Grid

8.3.1. Applicable Regulation for Production and Storage
8.3.2. Applicable Regulation for the Use of Hydrogen in Mobility
8.3.3. Regulation Applicable for the Use of Hydrogen in the Gas Grid

8.4. Standards and Best Practices in Security Plan Implementation

8.4.1. Applicable Standards: CEN/CELEC
8.4.2. Good Practices in the Implementation of the Security Plan
8.4.3. Hydrogen Valleys

8.5. Required Project Documentation

8.5.1. Technical Projects
8.5.2. Environmental Documentation
8.5.3. Certification

8.6. European Directives. Application Key: PED, ATEX, LVD, MD and EMC.

8.6.1. Pressure Equipment Regulations
8.6.2. Explosive Atmosphere Regulations
8.6.3. Chemical Storage Regulations

8.7. International Hazard Identification Standards: HAZID/HAZOP Analysis

8.7.1. Hazard Analysis Methodology
8.7.2. Risk Analysis Requirements
8.7.3. Execution of Risk Analysis

8.8. Plant Safety Level Analysis: SIL Analysis

8.8.1. SIL Analysis Methodology
8.8.2. SIL Analysis Requirements
8.8.3. SIL Analysis Execution

8.9. Certification of Installations and CE Marking

8.9.1. Necessity of Certification and CE Marking
8.9.2. Authorized Certification Agencies
8.9.3. Documentation

8.10. Permits and Approval: Case Study

8.10.1. Technical Projects
8.10.2. Environmental Documentation
8.10.3. Certification

Module 9. Hydrogen Project Planning and Management

9.1. Scope Definition: Project Type

9.1.1. Importance of Good Scope Definition
9.1.2. EDP OR WBS
9.1.3. Scope Management in Project Development

9.2. Characterization of Actors and Entities Interested in Hydrogen Project Management

9.2.1. Necessity of Stakeholder Characterization
9.2.2. Stakeholder Classification
9.2.3. Stakeholder Management

9.3. Most Relevant Project Contracts in the Hydrogen Field

9.3.1. Classification of the Most Relevant Contracts
9.3.2. Contracting Process
9.3.3. Contract Content

9.4. Defining Objectives and Impacts for Projects in the Hydrogen Sector

9.4.1. Objectives
9.4.2. Impacts
9.4.3. Objectives vs. Impacts

9.5. Work Plan for a Hydrogen Project

9.5.1. Importance of the Work Plan
9.5.2. Elements that Constitute It
9.5.3. Development

9.6. Key Deliverables and Milestones in Hydrogen Sector Projects

9.6.1. Deliverables and Milestones. Definition of Customer Expectations
9.6.2. Deliverables
9.6.3. Milestones

9.7. Project Schedule in Hydrogen Sector Projects

9.7.1. Preliminary Steps
9.7.2. Definition of Activities. Time Window, PM Efforts and Relationship between Stages
9.7.3. Graphic Tools Available

9.8. Identification and Classification of Risks of Hydrogen Sector Projects

9.8.1. Creation of the Project Risk Plan
9.8.2. Risk Analysis
9.8.3. Importance of Project Risk Management

9.9. Analysis of the EPC Phase of a Hydrogen Type Project

9.9.1. Detailed Engineering
9.9.2. Purchasing and Supplies
9.9.3. Construction Phase

9.10. Analysis of the O&M Phase of a Hydrogen Type Project

9.10.1. Development of the Operation and Maintenance Plan
9.10.2. Maintenance Protocols. Importance of Preventive Maintenance
9.10.3. Management of the Operation and Maintenance Plan

Module 10. Technical-Economic and Feasibility Analysis of Hydrogen Projects

10.1. Green Hydrogen Power Supply 

10.1.1. The Keys to PPAs (Power Purchase Agreement)
10.1.2. Self-Consumption with Green Hydrogen
10.1.3. Hydrogen Production in Off-Grid Configuration

10.2. Technical and Economic Modeling of Electrolysis Plants

10.2.1. Definition of Production Plant Requirements
10.2.2. CAPEX (Capital Expenditure)
10.2.3. OPEX (Operational Expenditure)

10.3. Technical and Economic Modeling of Storage Facilities according to Formats (GH2, LH2, Green Ammonia, Methanol, LOHC)

10.3.1. Technical Assessment of Different Storage Facilities
10.3.2. Cost Analysis
10.3.3. Selection Criteria

10.4. Technical and Economic Modeling of Hydrogen Transportation, Distribution, and End-Use Assets

10.4.1. Transportation and Distribution Cost Assessment
10.4.2. Technical Limitations of Current Hydrogen Transportation and Distribution Methods
10.4.3. Selection Criteria

10.5. Structuring of Hydrogen Projects. Financing Alternatives

10.5.1. Keys to the Choice of Financing
10.5.2. Private Equity Financing
10.5.3. Public Funding

10.6. Identification and Characterization of Project Revenues and Costs

10.6.1. Revenues
10.6.2. Costs
10.6.3. Joint Assessment

10.7. Calculation of Cash Flows and Project Profitability Indicators (IRR, NPV, others).

10.7.1. Cash Flow
10.7.2. Profitability Indicators
10.7.3. Case Study

10.8. Feasibility Analysis and Scenarios

10.8.1. Scenario Design
10.8.2. Scenario Analysis
10.8.3. Scenario Analysis

10.9. Use Case based on Project Finance

10.9.1. Relevant Figure
10.9.2. Development Process
10.9.3. Conclusions

10.10. Assessment of Barriers to Project Feasibility and Future Prospects

10.10.1. Existing Barriers to Hydrogen Project Feasibility
10.10.2. Assessment of the Current Situation
10.10.3. Future Perspectives

With this university program, you will master the most innovative techniques for the storage, distribution and use of Hydrogen as an energy source"