Strategies for an Energy Transition: Planning for a Sustainable Future
Autor Tania Itzel Serrano-Arévalo, Xate Geraldine Sánchez-Zarco, Francisco Javier López-Flores, Luis Fernando Lira-Barragán, Fabricio Nápoles-Rivera, César Ramírez-Márquez, José Maria Ponce-Ortegaen Limba Engleză Paperback – 28 oct 2025
- Covers the role of the latest renewable energy technologies and sustainability practices
- Explains and applies strategic planning and optimization models for sustainable development
- Navigates the complexities of policy, regulation, and market dynamics in the energy sector
- Includes real-world examples and case studies of sustainable energy implementations
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Specificații
ISBN-13: 9780443341113
ISBN-10: 0443341117
Pagini: 408
Dimensiuni: 152 x 229 x 22 mm
Greutate: 0.66 kg
Editura: ELSEVIER SCIENCE
ISBN-10: 0443341117
Pagini: 408
Dimensiuni: 152 x 229 x 22 mm
Greutate: 0.66 kg
Editura: ELSEVIER SCIENCE
Cuprins
1. Transition Towards Sustainable Energy: Approaches in Modelling and Optimization
2. Framework for Sustainable and Equitable Integrated Fuel Production Planning
3. Strategic Planning for Electricity Demand: Balancing Economics, Emissions, and Water Use
4. Designing an Optimal Waste Energy Integration System Between Plants
5. Considering the Water-Energy Nexus in Sustainable Energy Transitions: A Multi-Objective Optimization Approach
6. Equitable Profit Distribution in Waste Heat Integration Across Plants via a Hybrid Methodology
7. Planning for Long-Term Energy Transition: Incorporating Battery Degradation and Replacement Strategies
8. Multi-Objective Optimization of Cogeneration Systems: Economic, Environmental, and Social Perspectives
9. Optimal Integration of Solar Thermal Systems with Process Cogeneration
10. Incorporating Renewable Energy Storage and Hydrogen Production into the Electrical Sector
11. Predictive Planning for Power Sector Expansion in Mexico with Deep Learning
12. A Stakeholder-Driven Approach to Optimal Sustainable Energy System Planning Appendix: Introduction to Optimization and Deep Learning
2. Framework for Sustainable and Equitable Integrated Fuel Production Planning
3. Strategic Planning for Electricity Demand: Balancing Economics, Emissions, and Water Use
4. Designing an Optimal Waste Energy Integration System Between Plants
5. Considering the Water-Energy Nexus in Sustainable Energy Transitions: A Multi-Objective Optimization Approach
6. Equitable Profit Distribution in Waste Heat Integration Across Plants via a Hybrid Methodology
7. Planning for Long-Term Energy Transition: Incorporating Battery Degradation and Replacement Strategies
8. Multi-Objective Optimization of Cogeneration Systems: Economic, Environmental, and Social Perspectives
9. Optimal Integration of Solar Thermal Systems with Process Cogeneration
10. Incorporating Renewable Energy Storage and Hydrogen Production into the Electrical Sector
11. Predictive Planning for Power Sector Expansion in Mexico with Deep Learning
12. A Stakeholder-Driven Approach to Optimal Sustainable Energy System Planning Appendix: Introduction to Optimization and Deep Learning