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Enroll in this Master in Hydrogen Energy and obtain a Own Degree issued by the Catholic University of Murcia in collaboration with Structuralia

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Nuestros alumnos opinan sobre: Master´s Degree in Green Hydrogen Projects + 60 ECTS Credits

4,6
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100%
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Michela Papasidero

Opinión sobre Master´s Degree in Green Hydrogen Projects + 60 ECTS Credits

Michela Papasidero, ¿qué te hizo decidirte por nuestro Master Online?

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CAROLINA

Opinión sobre Master´s Degree in Green Hydrogen Projects + 60 ECTS Credits

Everything has been fantastic; I believe I have learned more than in my university studies. Thank you so much.

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DELAWARE

Opinión sobre Master´s Degree in Green Hydrogen Projects + 60 ECTS Credits

Everything is great. I really liked the course and how the tutors have helped me.

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STATE OF CALIFORNIA

Opinión sobre Master´s Degree in Green Hydrogen Projects + 60 ECTS Credits

Everything has been great for me; I really liked the layout of the syllabus. The structure and organization of the content were excellent.

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WASHINGTON

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I am very glad to know that you found the Master comprehensive and interesting!

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That is great to hear! I am glad the Master went well for you, and you enjoyed the online format.
* Todas las opiniones sobre Master´s Degree in Green Hydrogen Projects + 60 ECTS Credits, aquí recopiladas, han sido rellenadas de forma voluntaria por nuestros alumnos, a través de un formulario que se adjunta a todos ellos, junto a los materiales, o al finalizar su curso en nuestro campus Online, en el que se les invita a dejarnos sus impresiones acerca de la formación cursada.

Plan de estudios de Master online in hydrogen energy

MASTER IN HYDROGEN ENERGY. Don"t hesitate any longer and enroll through Euroinnova in this comprehensive training program that will turn you into a true professional in Green Hydrogen Projects. Obtain an Own Degree issued by the University Isabel I in collaboration with Structuralia with 60 ECTS credits from the comfort of your home.

Resumen salidas profesionales
de Master online in hydrogen energy
The Master’s degree in Hydrogen Energy Projects has been designed to grant students access to cross-cutting knowledge related to key aspects of the hydrogen energy production sector. As a matter of fact, it is intended to help students develop the necessary skills to successfully participate in different projects all the way from the conceptual to the strategic stage. Therefore, and to this end, this program has been structured into 9 modules that progressively delve into the characteristics of hydrogen as an element, as well as into its energy and environmental impact. This program also delves into the context of hydrogen as an energy source by analyzing the associated production technologies and the subsequent conversion process by means of fuel cells. It also goes into the storage and control systems within the supply chain, the repercussions of hydrogen in mobility and infrastructures, and of course, its uses and applications. In addition, other key aspects such as the construction of hydrogen filling stations, the strategic component and geopolitics of the sector, and finally, the economic and business aspects of hydrogen production, are also addressed. Furthermore, the program provides the necessary theoretical framework, case studies, and practical exercises for students to put the acquired knowledge into practice. Finally, at the end of the course, all knowledge and skills learned throughout the duration of the master’s degree will be tested by means of a final project.
Objetivos
de Master online in hydrogen energy
By pursuing this master's degree, the student will be able to:
- Learn about hydrogen in terms of properties as an element, as an energy vector, and its environmental impact.
- Delve into hydrogen production and conversion methods.
- Apply relevant storage and control systems.
- Delve into the associated infrastructure and means of transport.
- Master the use and applications of hydrogen.
- Delve into the fundamental aspects of hydrogen fueling stations.
- Learn about the key players involved through a strategic vision of the sector.
- Master economic and business aspects associated with hydrogen energy projects
Salidas profesionales
de Master online in hydrogen energy
- Project engineer in consulting companies - Energy company manager - Project and technical studies manager in construction firms - Technical staff in public administration agencies - Process engineers - Energy process manager - Economist and developers in the energy sector - Energy operations manager - Energy business development
Para qué te prepara
el Master online in hydrogen energy
Structuralia’s Master’s degree in Hydrogen Energy Projects is the only program that integrates all the different areas involved in the hydrogen energy sector. The main aspects included in this program are strategy design, Hydrogen as a product, associated infrastructures, and financing sources. By pursuing this master’s degree, the student will be able to acquire suitable knowledge and skills that will enable him/her to manage hydrogen-related projects and respond to any situation that may arise while carrying out his/her duties.
A quién va dirigido
el Master online in hydrogen energy
- Professionals in both the public and private sectors who require training in the hydrogen energy sector. - Professionals seeking to boost their careers within the private sector or promote strategic changes within their companies. - Anyone with either undergraduate or graduate education who is interested in learning more about the hydrogen energy sector in order to pursue a professional career in this area. - Management staff who require an overall understanding of the hydrogen sector for strategic decision-making.
Metodología
de Master online in hydrogen energy
Metodología Curso Euroinnova
Carácter oficial
de la formación
La presente formación no está incluida dentro del ámbito de la formación oficial reglada (Educación Infantil, Educación Primaria, Educación Secundaria, Formación Profesional Oficial FP, Bachillerato, Grado Universitario, Master Oficial Universitario y Doctorado). Se trata por tanto de una formación complementaria y/o de especialización, dirigida a la adquisición de determinadas competencias, habilidades o aptitudes de índole profesional, pudiendo ser baremable como mérito en bolsas de trabajo y/o concursos oposición, siempre dentro del apartado de Formación Complementaria y/o Formación Continua siendo siempre imprescindible la revisión de los requisitos específicos de baremación de las bolsa de trabajo público en concreto a la que deseemos presentarnos.

Temario de Master online in hydrogen energy

  1. MODULE 1. HYDROGEN AS AN ENERGY VECTOR
  2. UNIT 1. ENERGY AND HYDROGEN
  3. The hystory of hydrogen
  4. What is hydrogen?
  5. Current electricity and energy matrix
  6. Hydrogen as an energy carrier
  7. Prospects for the hydrogen roadmap
  8. UNIT 2. HYDROGEN GENERATION AND STORAGE
  9. PEM electrolysis
  10. Alkaline electrolysis
  11. SOEC and AEM electrolysis
  12. Hydrogen storage
  13. Hydrogen distribution
  14. UNIT 3. POWER GENERATION AND OTHER APPLICATIONS
  15. Fuel cells
  16. PEM fuel cell
  17. High temperature fuel cell
  18. Hydrogen turbines and engines
  19. Hydrogen vehicles
  20. UNIT 4. HYDROGEN INSTALLATIONS
  21. Refuelling stations
  22. Sizing of main equipment
  23. Safety considerations. Explosive atmospheres
  24. Design of hydrogen and fuel cell installations
  25. Examples of installation calculations
  26. MODULE 2. HYDROGEN CONTEXT
  27. UNIT 1. ENERGY AND PRODUCTION
  28. Energy production and its evolution
  29. Fossil fuels. The change of an era
  30. Strategies for sustainability
  31. Energy demand and transition
  32. Energy and the fuel future
  33. UNIT 2. CLIMATE CHANGE AND ENERGY TRANSITION
  34. Climate change
  35. Effects and strategies related to climate change
  36. The energy transition roadmap
  37. The evolution of the energy transition
  38. Carbon credits and ESG criteria
  39. UNIT 3. TECHNIQUES AND TECHNOLOGIES FOR DECARBONIZATION (I)
  40. Vectors of the energy transition
  41. Renewable electricity generation, electrification, and storage
  42. Mobility and transportation
  43. Carbon capture and storage
  44. Circular economy and new materials
  45. UNIT 4. TECHNIQUES AND TECHNOLOGIES FOR DECARBONIZATION (II)
  46. Hydrogen (H2)
  47. Bioenergy
  48. Integration between bioenergy processes and other technologies
  49. The cities of the future (smart cities)
  50. Entrepreneurship and enabling technologies and developments for decarbonization
  51. MODULE 3. HYDROGEN AND FUEL CELLS PRODUCTION
  52. UNIT 1. HYDROGEN PRODUCTION FROM FOSSIL FUELS
  53. Hydrogen production
  54. Hydrocarbon reforming
  55. Partial oxidation and other hydrocarbon based processes
  56. Coal and biomass gasification
  57. Advantages and disadvantages. Comparison between the different processes
  58. UNIT 2. GREEN HYDROGEN PRODUCTION
  59. Electrolytic processes
  60. Alkaline electrolysers
  61. Polymer electrolyser
  62. Green hydrogen production alternatives
  63. Technological maturity level
  64. UNIT 3. POLYMER FUEL CELLS OPERATION
  65. Origin and operation of fuel cells
  66. Composition and types of fuel cells
  67. Operation of polymer batteries
  68. Polymer battery components
  69. Progress and future expectations
  70. UNIT 4. OTHER TYPES OF FUEL CELLS
  71. Solid oxide fuel cells. Geometries and materials
  72. Fuel cell efficiency
  73. Alkaline, phosphoric acid and molten carbonate batteries
  74. Microbial fuel cell
  75. Fuel cell design and costing
  76. MODULE 4. HYDROGEN SUPPLY CHAIN
  77. UNIT 1. STORAGE AND SUPPLY OF HYDROGEN GAS
  78. Storage systems and their characteristics
  79. Storage in the form of compressed hydrogen gas
  80. Pressure vessels, types, characteristics and development objectives
  81. Specifications of EIHP (European Integrated Hydrogen Project)
  82. Examples of development projects
  83. UNIT 2. STORAGE AND SUPPLY OF LIQUID HYDROGEN
  84. Liquid hydrogen storage systems and characteristics
  85. Storage, distribution and dispensing of liquid hydrogen
  86. Liquid hydrogen storage tanks, types, characteristics and development objectives
  87. Specifications of EIHP (European Integrated Hydrogen Project)
  88. Examples of development projects
  89. UNIT 3. STORAGE AND SUPPLY OF HYDROGEN IN SOLIDS
  90. General concepts
  91. Metal hydrides
  92. Intermetallic compounds
  93. Carbonaceous materials and organic polymers
  94. Glass microspheres
  95. UNIT 4. HYDROGEN SYSTEM CONTROL
  96. Control theory
  97. Model-based Predictive Control (MPC)
  98. Hydrogen system modeling
  99. Control strategies
  100. Associated standards and regulations
  101. MODULE 5. HYDROGEN MOBILITY AND INFRASTRUCTURE
  102. UNIT 1. LAND MOBILITY
  103. Light transport
  104. Heavy duty transport
  105. Captive fleets
  106. Railway sector
  107. Infrastructures
  108. UNIT 2. AIR AND MARITIME MOBILITY
  109. Energy transition in air transport
  110. Sustainable aviation fuels
  111. Energy transition in maritime transport
  112. Sustainable fuels for maritime transport
  113. Evolution of air and maritime transport
  114. UNIT 3. HYDROGEN MANAGEMENT
  115. Risk of hydrogen
  116. Hydrogen detection
  117. Security aspects
  118. Explosive environments
  119. Hydrogen risk assesment
  120. UNIT 4. TRANSPORT AND LOGISTICS
  121. Hydrogen production pathways
  122. Distributed generation systems
  123. Comparison between generation systems
  124. Environmental, health, and safety aspects of the hydrogen production pathways
  125. Safety and risks associated with hydrogen transmissionn, distribution and storage
  126. MODULE 6. HYDROGEN USE AND APPLICATIONS
  127. UNIT 1. STATIONARY APPLICATIONS
  128. Large-scale power production
  129. Decentralized power generation systems
  130. Power microgeneration systems
  131. Uninterruptible Power Supply Systems (UPS)
  132. Heat-energy combined systems
  133. UNIT 2. MOBILE APPLICATIONS
  134. Introduction and future perspectives on mobile applications
  135. Forklift trucks
  136. Passenger cars and buses
  137. Air mobility and maritime mobility
  138. Other vehicles
  139. UNIT 3. PORTABLE APPLICATIONS
  140. Reversible fuel cells
  141. Space applications
  142. Micro fuel cells
  143. Portable generators
  144. Other systems
  145. UNIT 4. POWER-TO-X
  146. Power-to-X. Basis and concepts
  147. Power-to-Gas (PTG)
  148. Power-to-Liquid (PTL)
  149. Power-to-Heat (PTH)
  150. Hydrogen and applications worldwide
  151. MODULE 7. HYDROGEN FILLING STATION
  152. UNIT 1. INFRASTRUCTURE EQUIPMENT AND COMPONENTS
  153. Materials, pipelines, and accessories
  154. Feed systems and storage
  155. Hydrogen compressors
  156. Auxiliary components and systems
  157. Hydrogen dispensers
  158. UNIT 2. SET UP AND OPERATION OF A HYDROGEN FILLING STATION
  159. Set up and operation of a hydrogen filling station
  160. Instrumentation and control systems
  161. Inspections protocols
  162. Filling station operation
  163. Maintenance tasks
  164. UNIT 3. SAFETY ASPECTS
  165. Safety fundamentals
  166. Safety methodologies and risk assesment
  167. Risk mitigation, explosive atmospheres, and the atex
  168. Safety distance in hydrogen facilities
  169. Protection measures against external agents
  170. UNIT 4. APPLICABLE REGULATIONS
  171. ISO 14687. Hydrogen fuel quality
  172. ISO 17268. Hydrogen refuelling devices
  173. ISO 19880-1. Fuelling stations. General requirements
  174. ISO 22734. Electrolyzers
  175. IEC 62282-3-100. Stationary fuel cell power systems
  176. MODULE 8. HYDROGEN GEOPOLITICS
  177. UNIT 1. KEY PLAYERS IN THE HYDROGEN INDUSTRY
  178. The great producers
  179. The great consumers
  180. Engineering, technological, and construction firms
  181. Governments and the hydrogen regulation
  182. The small producer and/or consumer
  183. UNIT 2. THE BUSINESS MODEL
  184. Evolution of renewable energies and their transition into hydrogen
  185. Hydrogen storage or aggregate demand
  186. The uses of hydrogen. Internal and external markets
  187. Hydrogen trading and blending
  188. Business model viability and limitations
  189. UNIT 3. HYDROGEN ROADMAPS
  190. European Hydrogen Roadmap
  191. The Spanish Hydrogen Roadmap
  192. United States Hydrogen Roadmap
  193. China-Japan Hydrogen Roadmaps
  194. Reflections on the hydrogen roadmap
  195. UNIT 4. STRATEGIC ASPECTS
  196. Geopolitical power of hydrogen
  197. Hydrogen and geopolitics of infrastructures
  198. The new energy world order
  199. Fossil vs hydrogen
  200. Geostrategic discourse and metadiscourse
  201. MODULE 9. HYDROGEN ECONOMY
  202. UNIT 1. INVESTMENT DRIVERS
  203. Europe's technological, economic and environmental potential
  204. European deployment plans, the hydrogen valleys
  205. Drivers for hydrogen and fuel cell investment
  206. Supply and demand development initiatives
  207. The route to technology commercialization
  208. UNIT 2. CASE STUDIES
  209. Fuel cell handling equipment
  210. Residential use. Fuel cell cogeneration
  211. Cogeneration CHP
  212. Hydrogen production without CO2 capture. Part I
  213. Hydrogen production with and without CO2 capture. Part II
  214. UNIT 3. ECONOMY VIABILITY
  215. Overview of economic viability
  216. Economic viability plan
  217. Investment and financing plan
  218. Profitability and risks in hydrogen projects: a financial approach
  219. Commercialisation strategies and feasibility in the hydrogen industry: economic and business perspectives
  220. UNIT 4. FINANCING TOOLS
  221. First steps towards the search for capital
  222. Internal financing sources
  223. External financing sources
  224. Mixed financing sources
  225. Financing negotiations
  226. MODULE 10. MFP. MASTER´S DEGREE IN HYDROGEN ENERGY PROJECTS

Titulación de Master online in hydrogen energy

Master Of Professional Development in Green Hydrogen Projects with 60 ECTS Credits awarded by the Catholic University of Murcia in collaboration with Structuralia

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Claustro docente de Master online in hydrogen energy

Miguel Angel Aparicio Jimenez
Tutor
Grado en Biología Máster Universitario en Biotecnología (Rama Industrial) Doctorado en Biociencias y Ciencias Agroalimentarias Curso de Formación E-Learning
Su formación +
Francisco Navarro Martinez
Tutor
Doctor en Ciencias Aplicadas al Medio Ambiente, con especialidad en Recursos Hídricos, por la Universidad de Almería y Perito Ambiental.
Su formación +
Nerea Martin Pavon
Tutor
Grado en Química Especializada en Síntesis Orgánica Aplicada a la Química Médica
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Fabiola Naranjo
Tutor
Licenciada en Biología y Ciencias Ambientales por la Universidad de Córdoba.
Su formación +
Antonio Pérez-luque
Tutor
Doctor en Ecología, Licenciado en Biología y cuenta con un Master en Estadística Aplicada de la Universidad de Granada.
Su formación +

7 razones para realizarel Master online in hydrogen energy

1
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Más de 20 años de experiencia en la formación online.

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Alumnos de los 5 continentes.

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Las cifras nos avalan
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Flexibilidad

Aprendizaje 100% online, flexible, desde donde quieras y como quieras

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Aprendizaje para la vida real, contenidos prácticos, adaptados al mercado laboral y entornos de aprendizaje ágiles en campus virtual con tecnología punta

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Información complementaria

Master Online in Hydrogen Energy

If you are passionate about nature or simply want to contribute to environmental care in a decisive and real way, studying this discipline will be highly satisfying for you. Moreover, with this Master Online in Hydrogen Energy, your entry into the job market will be guaranteed.

By obtaining an Own Degree issued by the Catholic University of Murcia in collaboration with Structuralia with 60 ECTS credits, you will have the opportunity to advance as far as you want in your professional journey.

Interested in learning more about this innovative and necessary discipline? Keep reading.

Request the information you consider necessary at Euroinnova International Online Education!

Specialize in Hydrogen Projects thanks to the leading training school

Green hydrogen, also known as renewable hydrogen, comes from various renewable energy sources that generate zero CO2 emissions. The use of this type of hydrogen, combined with other strategies and techniques, will be fundamental in decarbonization efforts.

How is it produced?

To obtain Green Hydrogen, a chemical process is required to extract it from its natural state. This process involves electrolysis powered by renewable energies, commonly using solar or wind energy. There are two other, less sustainable, ways of obtaining hydrogen:

  1. Molecular transformation: A series of chemical reactions are necessary to obtain hydrogen. This is commonly done through steam methane reforming, using natural gas deposits found in oil-rich areas. Steam at high temperatures dissociates the carbon from hydrogen. This is the most widely used method currently.

  2. Gasification: Using steam and pure oxygen to convert coal into hydrogen. This procedure involves burning coal in a reactor, resulting in the production of carbon monoxide, making it one of the most environmentally harmful techniques.

Currently, only around 1% of global hydrogen production is green hydrogen. However, this is set to change, and soon it will surpass other energy sources due to worldwide plans to combat climate change.

Take advantage of the opportunity that Euroinnova International Online Education offers you to expand your training. With the Master Online in Hydrogen Energy, you can comfortably balance your work and personal life.

Master in Green Hydrogen

Uses Green hydrogen has various applications, with the most well-known being:

  1. Domestic use: One of the main future applications is for heating and providing electricity to homes due to the high temperatures that this type of hydrogen can reach.

  2. Heavy industry: Hydrogen is essential for manufacturing chemicals such as ammonia and fertilizers. It is also widely used in oil refining and steel production.

  3. Clean and renewable fuel: In the coming years, with the help of green hydrogen, decarbonization efforts in long-distance and air transportation will be accelerated. It will also make a significant difference in trains and heavy freight transport.

  4. Energy storage: Due to its high volume and long lifespan, it can be stored safely, resembling natural gas or oil reserves. Apart from the benefits it would bring to the planet, it can be easily and securely stored.

Be part of the most significant energy change you will see in centuries by specializing in this Master in Green Hydrogen. What are you waiting for?

Get to know Euroinnova Play and access the podcasts and webinars made by our experts in different fields and sectors. Boost your professional career with just one play.

The Energy of the Future

In the coming years, green hydrogen, together with other low-carbon energy sources, is estimated to make up between 10 and 20% of the planet's total energy consumption.

Sectors such as maritime and air transport will also adopt fuels produced from renewable hydrogen.

It is recognized as the key to successfully completing the process of decarbonization of planet Earth, thereby achieving the objectives set for 2050 as part of the plan to combat climate change.

At Euroinnova International Online Education, we want to make the world a better place. We also want to help you achieve all your goals and ensure that our training programs truly help you enter the job market in the best possible way.

What are you waiting for to request information? Access our virtual campus and explore our extensive catalog of courses and/or masters. Get in touch with us, and our specialized advisors in the subject you desire will assist you.

That's why we offer this Master in Green Hydrogen, which will make you an accredited professional in Green Hydrogen Projects. Moreover, you will obtain 60 ECTS credits. What more could you want?

Check out our related courses by clicking here and access the most in-demand job market

Enroll as soon as possible in this Master in Green Hydrogen, and if you have any doubts, don't hesitate to contact us through the website.

We are here for you!

Master online in hydrogen ...
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