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Beyond operational energy use in buildings, embodied carbon is also a concern
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Classroom Contents
Composite Materials for Energy-efficient Buildings: Thermal Energy Storage and Sustainable Construction
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- 1 Intro
- 2 Global energy and water demand are projected to increase significantly
- 3 Understanding the water - energy nexus
- 4 Heat is the dominant form of energy use in the buildings sector
- 5 Renewable electrification is promising for decarbonization, but there is a mismatch
- 6 Thermal batteries (energy storage) can be used to decarbonize heat
- 7 Thermochemical energy storage in buildings
- 8 Limitations of salt hydrates include material instability during hygrothermal cycling
- 9 Particle size of the salt has an impact on the reaction kinetics
- 10 Dehydration and hydration kinetics are also influenced by the porosity of the salt
- 11 Composite materials can overcome inherent limitations of pristine salts
- 12 Beyond operational energy use in buildings, embodied carbon is also a concern
- 13 Establishing a wood-based building materials economy in Georgia
- 14 Engineered wood as a structural and thermally insulating material
- 15 High-temperature TES can be used to decarbonize industry Electrical
- 16 Ceramic-graphite composites for thermal storage using sintering
