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Course on New Green Technologies

Why this course?

The New Green Technologies

course

Immerse yourself in the innovative solutions driving a sustainable future. Learn about renewable energies, such as solar, wind, and hydropower, and how to optimize their implementation. Master the principles of the circular economy and its application in waste management and product design. Explore the latest trends in sustainable mobility, from electric vehicles to smart infrastructure. This program will provide you with the tools and knowledge needed to be a change agent in the transition to a green economy.

Differential Advantages

  • Real-World Case Studies: Analysis of successful green technology projects worldwide.
  • Practical Approach: Development of skills for evaluating, selecting, and implementing sustainable solutions.
  • Industry Experts: Classes taught by leading professionals in the field of green technologies.
  • Networking: Opportunities to connect with other professionals and companies committed to sustainability.
  • Certification: Obtain a certificate that validates your knowledge and skills in green technologies.
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Price: 722,00 £

Course on New Green Technologies

  • Modality: Online
  • Level: Cursos
  • Hours: 150 H
  • Start date: 26-07-2026

Availability: 1 in stock

Who is it aimed at?

  • Energy professionals seeking to update their knowledge of renewable energy sources and energy efficiency.
  • Engineers and technicians wishing to specialize in the design, installation, and maintenance of green technologies.
  • Companies and entrepreneurs interested in implementing sustainable practices and developing businesses in the renewable energy sector.
  • Sustainability and environmental managers needing tools for environmental impact assessment and resource management.
  • Students and recent graduates aspiring to a career in the clean energy sector and technological innovation.

Learning flexibility
Adapted to your needs: 24/7 accessible online content, discussion forums for sharing experiences, and personalized tutoring.

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Objectives and competencies

Implement innovative solutions:

Develop and integrate emerging technologies (AI, Machine Learning, IoT) to optimize existing processes and create new functionalities.

Evaluate and adapt existing infrastructures:

Analyze capacity, obsolescence and scalability, proposing technical improvements and resource optimization.

Promote interdisciplinary collaboration:

“Actively participate in the planning of the voyage, integrating the experience of the bridge team, engineers, and deck personnel.”

Promote energy efficiency and sustainability:

Implement technologies and practices to optimize fuel consumption, reducing emissions and operating costs.

Develop specialized technical skills:

Interpret electronic charts (ECDIS) accurately, integrating information from various sources (AIS, radar, GPS) and proactively applying corrections.

Understanding and mitigating environmental impact:

“Manage waste on board and prevent marine pollution (MARPOL) with diligence and proactivity.”

Curriculum - Modules

  1. Comprehensive Maritime Incident Management: protocols, roles, and chain of command for coordinated response
  2. Operational Planning and Execution: briefing, routes, weather windows, and go/no-go criteria
  3. Rapid Risk Assessment: criticality matrix, scene control, and decision-making under pressure
  4. Operational Communication: VHF/GMDSS, standardized reports, and inter-agency liaison
  5. Tactical Mobility and Safe Boarding: RHIB maneuvers, approach, mooring, and recovery
  6. Equipment and Technologies: PPE, signaling, satellite tracking, and field data logging
  7. Immediate Care of the Affected: primary assessment, hypothermia, trauma, and stabilization for evacuation
  8. Adverse Environmental Conditions: swell, Visibility, flows, and operational mitigation

    Simulation and training: critical scenarios, use of VR/AR, and exercises with performance metrics

    Documentation and continuous improvement: lessons learned, indicators (MTTA/MTTR), and SOP updates

  1. Introduction to Sustainability: Definitions, Principles, and Frameworks.
  2. Product Life Cycle: Analysis and Eco-design.
  3. Sustainable Materials: Selection, Properties, and Applications.
  4. Renewable Energies: Technologies, Integration, and Storage.
  5. Energy Efficiency: Process and Building Optimization.
  6. Waste Management: Reduction, Reuse, and Recycling.
  7. Environmental Impact Assessment: Methodologies and Tools.
  8. Circular Economy: Business Models and Strategies.
  9. Green Technological Innovation: Trends and Opportunities.
  10. Environmental Regulation: Regulations and international standards.

  1. Introduction to Digital Sustainability: Definition, scope, and importance.
  2. Digital Carbon Footprint: Measurement, analysis, and reduction strategies.
  3. Sustainable Infrastructures: Green data centers, energy-efficient networks.
  4. Digital Circular Economy: Eco-design, reuse, and recycling of devices.
  5. Sustainable Software and Applications: Development, optimization, and energy consumption.
  6. Responsible Artificial Intelligence: Ethics, biases, and resource consumption.
  7. Blockchain and Sustainability: Applications for traceability and transparency.
  8. Sustainable Cybersecurity: Data protection and environmental impact reduction.
  9. Legal Framework and Regulatory: Environmental regulations and digital sustainability standards.

    Success Stories: Leading companies and organizations in Digital Sustainability.

  1. Introduction to Sustainability: Definitions, Dimensions, and Importance.
  2. Principles of the Circular Economy: Reduce, Reuse, Recycle, Recover.
  3. Life Cycle Assessment (LCA): Methodology and Applications.
  4. Ecodesign: Strategies for Designing Sustainable Products.
  5. Sustainable Materials: Types, Properties, and Applications.
  6. Renewable Energies: Technologies, Efficiency, and Storage.
  7. Efficient Water Management: Technologies and Strategies.
  8. Climate Change Mitigation Technologies: Carbon Capture and Storage.
  9. Sustainability Indicators: KPIs, Reporting, and Standards (GRI, SASB).
  10. Social Innovation and Business Models sustainable.

  1. Introduction to Digital Sustainability: Definition, scope, and benefits.
  2. Circular Economy and Digitalization: Technology-enabled circular business models.
  3. Digital Life Cycle Assessment (LCA): Tools and methodologies for evaluating the environmental impact of digital products and services.
  4. Sustainable Design of Digital Products and Services: Ecodesign, accessibility, and usability.
  5. Energy Efficiency in Digital Infrastructure: Data centers, networks, and devices.
  6. Dematerialization and Resource Optimization Strategies: Cloud computing, virtualization, and software as a service.
  7. E-waste Management: Recycling, reuse, and reverse logistics.
  8. Blockchain for the Traceability and Transparency: Applications in the supply chain and the circular economy.

    Key Performance Indicators (KPIs) for Digital Sustainability: Metrics and reporting.

    Success Stories and Best Practices: Leading companies in digital sustainability and the circular economy.

  1. System Architecture and Components: Structural design, materials, and subsystems (mechanical, electrical, electronic, and fluid) with selection and assembly criteria for marine environments
  2. Fundamentals and Principles of Operation: Physical and engineering foundations (thermodynamics, fluid mechanics, electricity, control, and materials) that explain performance and operating limits
  3. Safety and Environmental (SHE): Risk analysis, PPE, LOTO, hazardous atmospheres, spill and waste management, and emergency response plans
  4. Applicable Regulations and Standards: IMO/ISO/IEC requirements and local regulations;
  5. Conformance criteria, certification, and best practices for operation and maintenance
  6. Inspection, testing, and diagnostics: Visual/dimensional inspection, functional testing, data analysis, and predictive techniques (vibration, thermography, fluid analysis) to identify root causes
  7. Preventive and predictive maintenance: Hourly/cycle/seasonal plans, lubrication, adjustments, calibrations, consumable replacement, post-service verification, and operational reliability
  8. Instrumentation, tools, and metrology: Measuring and testing equipment, diagnostic software, calibration and traceability; selection criteria, safe use, and storage
  9. Onboard integration and interfaces: Mechanical, electrical, fluid, and data compatibility; Sealing and watertightness, EMC/EMI, corrosion protection, and interoperability testing.

    Quality, acceptance testing, and commissioning: process and materials control, FAT/SAT, bench and sea trials, go/no-go criteria, and evidence documentation.

    Technical documentation and integrated practice: logs, checklists, reports, and a complete case study (safety → diagnosis → intervention → verification → report) applicable to any system.

Plan de estudio - Módulos

  1. Comprehensive Maritime Incident Management: protocols, roles, and chain of command for coordinated response
  2. Operational Planning and Execution: briefing, routes, weather windows, and go/no-go criteria
  3. Rapid Risk Assessment: criticality matrix, scene control, and decision-making under pressure
  4. Operational Communication: VHF/GMDSS, standardized reports, and inter-agency liaison
  5. Tactical Mobility and Safe Boarding: RHIB maneuvers, approach, mooring, and recovery
  6. Equipment and Technologies: PPE, signaling, satellite tracking, and field data logging
  7. Immediate Care of the Affected: primary assessment, hypothermia, trauma, and stabilization for evacuation
  8. Adverse Environmental Conditions: swell, Visibility, flows, and operational mitigation

    Simulation and training: critical scenarios, use of VR/AR, and exercises with performance metrics

    Documentation and continuous improvement: lessons learned, indicators (MTTA/MTTR), and SOP updates

  1. Introduction to Sustainability: Definitions, Principles, and Frameworks.
  2. Product Life Cycle: Analysis and Eco-design.
  3. Sustainable Materials: Selection, Properties, and Applications.
  4. Renewable Energies: Technologies, Integration, and Storage.
  5. Energy Efficiency: Process and Building Optimization.
  6. Waste Management: Reduction, Reuse, and Recycling.
  7. Environmental Impact Assessment: Methodologies and Tools.
  8. Circular Economy: Business Models and Strategies.
  9. Green Technological Innovation: Trends and Opportunities.
  10. Environmental Regulation: Regulations and international standards.

  1. Introduction to Digital Sustainability: Definition, scope, and importance.
  2. Digital Carbon Footprint: Measurement, analysis, and reduction strategies.
  3. Sustainable Infrastructures: Green data centers, energy-efficient networks.
  4. Digital Circular Economy: Eco-design, reuse, and recycling of devices.
  5. Sustainable Software and Applications: Development, optimization, and energy consumption.
  6. Responsible Artificial Intelligence: Ethics, biases, and resource consumption.
  7. Blockchain and Sustainability: Applications for traceability and transparency.
  8. Sustainable Cybersecurity: Data protection and environmental impact reduction.
  9. Legal Framework and Regulatory: Environmental regulations and digital sustainability standards.

    Success Stories: Leading companies and organizations in Digital Sustainability.

  1. Introduction to Sustainability: Definitions, Dimensions, and Importance.
  2. Principles of the Circular Economy: Reduce, Reuse, Recycle, Recover.
  3. Life Cycle Assessment (LCA): Methodology and Applications.
  4. Ecodesign: Strategies for Designing Sustainable Products.
  5. Sustainable Materials: Types, Properties, and Applications.
  6. Renewable Energies: Technologies, Efficiency, and Storage.
  7. Efficient Water Management: Technologies and Strategies.
  8. Climate Change Mitigation Technologies: Carbon Capture and Storage.
  9. Sustainability Indicators: KPIs, Reporting, and Standards (GRI, SASB).
  10. Social Innovation and Business Models sustainable.

  1. Introduction to Digital Sustainability: Definition, scope, and benefits.
  2. Circular Economy and Digitalization: Technology-enabled circular business models.
  3. Digital Life Cycle Assessment (LCA): Tools and methodologies for evaluating the environmental impact of digital products and services.
  4. Sustainable Design of Digital Products and Services: Ecodesign, accessibility, and usability.
  5. Energy Efficiency in Digital Infrastructure: Data centers, networks, and devices.
  6. Dematerialization and Resource Optimization Strategies: Cloud computing, virtualization, and software as a service.
  7. E-waste Management: Recycling, reuse, and reverse logistics.
  8. Blockchain for the Traceability and Transparency: Applications in the supply chain and the circular economy.

    Key Performance Indicators (KPIs) for Digital Sustainability: Metrics and reporting.

    Success Stories and Best Practices: Leading companies in digital sustainability and the circular economy.

  1. System Architecture and Components: Structural design, materials, and subsystems (mechanical, electrical, electronic, and fluid) with selection and assembly criteria for marine environments
  2. Fundamentals and Principles of Operation: Physical and engineering foundations (thermodynamics, fluid mechanics, electricity, control, and materials) that explain performance and operating limits
  3. Safety and Environmental (SHE): Risk analysis, PPE, LOTO, hazardous atmospheres, spill and waste management, and emergency response plans
  4. Applicable Regulations and Standards: IMO/ISO/IEC requirements and local regulations;
  5. Conformance criteria, certification, and best practices for operation and maintenance
  6. Inspection, testing, and diagnostics: Visual/dimensional inspection, functional testing, data analysis, and predictive techniques (vibration, thermography, fluid analysis) to identify root causes
  7. Preventive and predictive maintenance: Hourly/cycle/seasonal plans, lubrication, adjustments, calibrations, consumable replacement, post-service verification, and operational reliability
  8. Instrumentation, tools, and metrology: Measuring and testing equipment, diagnostic software, calibration and traceability; selection criteria, safe use, and storage
  9. Onboard integration and interfaces: Mechanical, electrical, fluid, and data compatibility; Sealing and watertightness, EMC/EMI, corrosion protection, and interoperability testing.

    Quality, acceptance testing, and commissioning: process and materials control, FAT/SAT, bench and sea trials, go/no-go criteria, and evidence documentation.

    Technical documentation and integrated practice: logs, checklists, reports, and a complete case study (safety → diagnosis → intervention → verification → report) applicable to any system.

  1. Introduction to Sustainability: Definitions, dimensions, and importance.
  2. Principles of the Circular Economy: Reduce, Reuse, Recycle, Recover.
  3. Life Cycle Assessment (LCA): Methodology and tools for evaluating environmental impact.
  4. Ecodesign: Design for sustainability and minimizing environmental impact.
  5. Sustainable Materials: Types, properties, and applications in innovation.
  6. Renewable Energies: Technologies, potential, and role in the energy transition.
  7. Clean Technologies: Innovation for emissions reduction and resource efficiency.
  8. Waste Management: Strategies and technologies for recovery and treatment.
  9. Indicators of Sustainability: Measuring and monitoring environmental performance.

    Case Studies: Examples of sustainable innovation in different sectors.

  1. Introduction to Sustainability: Key Concepts and Sustainable Development Goals (SDGs)
  2. Fundamentals of Sustainable Digitalization: Environmental Impact of ICTs and Mitigation Strategies
  3. Energy Transition: Current Landscape and Future of Renewable Energies
  4. Photovoltaic Solar Energy: Principles, Technologies, Applications, and Efficiency
  5. Wind Energy: Types of Wind Turbines, Onshore and Offshore Wind Farms, Environmental Impact
  6. Energy Storage: Batteries, Hydrogen, Pumped Storage Systems, and Other Technologies
  7. Smart Grids: Optimizing Consumption, Demand Management, and Grid Digitalization
  8. Energy Digitalization: Sensors, IoT, Big Data, and Analytics for Energy Efficiency

    Success Stories: Innovative Companies and Projects in Digitalization and Clean Energy

    Regulatory Framework and Public Policies: Incentives, Regulations, and Trends in Sustainability

  1. Introduction to Digital Sustainability: Key Concepts and Definitions
  2. Digital Carbon Footprint: Measurement, Analysis, and Reduction Strategies
  3. Circular Economy and ICT: Sustainable Business Models and Digitalization
  4. Sustainable Software and Hardware Design: Ecodesign Principles in the Digital Sphere
  5. Sustainable Digital Infrastructures: Green Data Centers, Efficient Networks, and Renewable Energies
  6. Electronic Waste Management: Recycling, Reuse, and Extended Producer Responsibility
  7. Sustainable Public and Private Procurement in the ICT Sector: Environmental and Social Criteria in Contracting
  8. Standards and Certifications of Digital Sustainability: ISO 14001, EMAS, and other relevant standards.

    Technological Innovation for Environmental Sustainability: Application examples and success stories.

    Digital Sustainability Legislation and Public Policies: Legal and regulatory framework at the national and international levels.

  1. Introduction to Sustainability: Definitions, dimensions, and importance.
  2. Principles of the Circular Economy: Reduce, reuse, recycle, and recover.
  3. Life Cycle Assessment (LCA): Methodology and applications for environmental impact assessment.
  4. Ecodesign: Strategies for the design of sustainable products and services.
  5. Disruptive and Sustainable Innovation: Opportunities and challenges for value creation.
  6. Sustainable Business Models: Creating shared value and the triple bottom line.
  7. Clean Technologies: Renewable energies, energy efficiency, and waste management.
  8. Sustainability Indicators: Measuring and monitoring environmental, social, and economic performance.
  9. Regulatory Framework and Sustainability Policies: National and international regulations.

    Case Studies: Examples of sustainable innovation in different sectors.

Career opportunities

  • Renewable Energy Consultant: Advising companies and governments on the implementation of green technologies and sustainability strategies.
  • Energy Efficiency Technician: Energy audits, consumption optimization, and design of energy-saving systems.
  • Renewable Energy Project Manager: Planning, development, and execution of wind, solar, hydroelectric, or biomass projects.
  • Researcher in New Green Technologies: Development of new materials, processes, and devices for the generation and storage of clean energy.
  • Sustainable Mobility Specialist: Design and implementation of public and private transportation solutions based on electric, hybrid, or hydrogen vehicles.
  • Life Cycle Assessment (LCA) Analyst: Evaluation of the environmental impact of products and services, from raw material extraction to final disposal.
  • Circular Economy Expert: Developing business models that minimize resource use and maximize reuse.
  • Corporate Sustainability Manager: Implementing sustainable policies and practices in companies across various sectors.
  • Environmental Educator: Raising awareness and providing training on sustainability issues for diverse audiences.

“`

Admission requirements

Academic/professional profile:

Degree/Bachelor's degree in Nautical Science/Maritime Transport, Naval/Marine Engineering, or a related field; or proven professional experience in bridge/operations.

Language proficiency:

Recommended functional maritime English (SMCP) for simulations and technical materials.

5. Induction

Updated resume, copy of degree or seaman's book, ID card/passport, letter of motivation.

Technical requirements (for online):

Equipment with camera/microphone, stable connection, ≥ 24” monitor recommended for ECDIS/Radar-ARPA.

Admission process and dates

1. Online
application

(form + documents).

2. Academic review and interview

(profile/objectives/schedule compatibility).

3. Admission decision

(+ scholarship proposal if applicable).

4. Reservation of place

(deposit) and registration.

5. Induction

(access to campus, calendars, simulator guides).

Scholarships and grants

  • Master the technologies of the future: Learn about renewable energy, energy efficiency, and sustainable resource management.
  • Contribute to a sustainable future: Acquire the skills needed to design and implement eco-innovative solutions.
  • Boost your career: Stand out in a booming sector with high demand for specialized professionals.
  • Apply innovative methodologies: Experiment with practical case studies and real-world projects for effective learning.
  • Networking with experts: Connect with leading professionals and build a network of contacts in the field of green technologies.
Get ready to lead the transformation towards a greener and more sustainable economy!

Testimonials

During my training in New Green Technologies, I developed a prototype smart irrigation system that reduces water consumption by 30% using moisture sensors and a predictive algorithm. This project was selected for presentation at the regional sustainability conference, generating investor interest and opening doors to future collaborations in the sector.

Luisa FernandezFirst mate
Luisa Fernandez

The Renewable Energy and Efficiency course provided me with the tools and knowledge necessary to design and implement a photovoltaic system in my community, significantly reducing our energy costs and carbon footprint. The hands-on training and focus on real-world case studies were fundamental to the project’s success.

SofiaHernandezCaptain
SofiaHernandez

During my training in New Green Technologies, I developed a prototype smart irrigation system that reduces water consumption by 30% using moisture sensors and a predictive algorithm. This project allowed me to apply my knowledge of renewable energy, IoT, and data analytics, and it was selected for presentation at the sustainable innovation fair, where it received excellent reviews for its potential impact on agriculture.

Luisa FernándezVTS Supervisor
Luisa Fernández

I implemented a smart irrigation system with humidity sensors and solar panels on a farm, which reduced water consumption by 40% and energy use by 60%, increasing tomato production by 15% by optimizing growing conditions.

Ignacio HernándezAspiring practical worker
Ignacio Hernández

Frequently asked questions

New green technologies, by promoting renewable energy, energy efficiency and sustainable resource management, contribute significantly to reducing the carbon footprint.

Yes. The itinerary includes ECDIS/Radar-ARPA/BRM with harbor, ocean, fog, storm, and SAR scenarios.

Online with live sessions; hybrid option for simulator/practical placements through agreements.

New green technologies, such as renewable energy, energy efficiency, and carbon capture, contribute significantly to reducing the carbon footprint by decreasing greenhouse gas emissions and promoting sustainability.

Recommended functional SMCP. We offer support materials for standard phraseology.

Yes, with a relevant degree or experience in maritime/port operations. The admissions interview will confirm suitability.

Optional (3–6 months) through Companies & Collaborations and the Alumni Network.

Simulator practice (rubrics), defeat plans, SOPs, checklists, micro-tests and applied TFM.

A degree from Navalis Magna University + operational portfolio (tracks, SOPs, reports and KPIs) useful for audits and employment.

  1. Introduction to Sustainability: Definitions, dimensions, and importance.
  2. Principles of the Circular Economy: Reduce, reuse, recycle, and recover.
  3. Life Cycle Assessment (LCA): Methodology and applications for environmental impact assessment.
  4. Ecodesign: Strategies for the design of sustainable products and services.
  5. Disruptive and Sustainable Innovation: Opportunities and challenges for value creation.
  6. Sustainable Business Models: Creating shared value and the triple bottom line.
  7. Clean Technologies: Renewable energies, energy efficiency, and waste management.
  8. Sustainability Indicators: Measuring and monitoring environmental, social, and economic performance.
  9. Regulatory Framework and Sustainability Policies: National and international regulations.

    Case Studies: Examples of sustainable innovation in different sectors.

Request information

  1. Complete the Application Form
  2. Attach your CV/Qualifications (if you have them to hand).
  3. Indicate your preferred cohort (January/May/September) and whether you want the hybrid option with simulator sessions.
An academic advisor will contact you within 24–48 hours to guide you through the admission process, scholarships, and compatibility with your professional schedule. Translated with DeepL.com (free version)
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Teachers

Eng. Tomás Riera

Full Professor

Eng. Tomás Riera

Full Professor

Naval engineer specializing in the selection, integration, and optimization of propulsion systems for yachts, high-speed craft, and service vessels.
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Eng. Sofía Marquina

Full Professor

Eng. Sofía Marquina

Full Professor

Materials engineer specializing in marine composites and corrosion protection systems for ships, yachts, and port structures.
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Eng. Javier Bañuls

Full Professor

Eng. Javier Bañuls

Full Professor

Naval electrical engineer with over fifteen years of experience in the design, integration, and operation of power and automation systems.
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Dr. Nuria Llobregat

Full Professor

Dr. Nuria Llobregat

Full Professor

Specialist in meteorological and operational decision-making for coastal and offshore navigation, integrating wind, wave, and current models.
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Dr. Pau Ferrer

Full Professor

Dr. Pau Ferrer

Full Professor

Naval engineer with a PhD in applied hydrodynamics and over a decade of experience designing high-performance hulls and marine structures.
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Cap. Javier Abaroa (MCA)

Full Professor

Cap. Javier Abaroa (MCA)

Full Professor

MCA-certified captain with command of ocean-going vessels, specializing in advanced maneuvering, navigation management, and bridge safety.
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