Unlocking the Future of Renewable Energy and Chemistry through Catalysis: Studies in Surface Science and Catalysis
Editat de Vasile I. Parvulescu, Bert M. Weckhuysen, Gabriele Centi, Siglinda Perathoneren Limba Engleză Paperback – aug 2025
- Offers an integrated view of the changing outlook for energy and chemistry and the impact on catalysis
- Provides a gaps and opportunity analysis combining the analysis of the transformative scenario to S&T backgrounds and advances
- Written by top scientists and industrial managers to offer a perspective on priorities and bottlenecks to develop a renewables-based economy
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Specificații
ISBN-13: 9780443333316
ISBN-10: 0443333319
Pagini: 450
Dimensiuni: 191 x 235 mm
Editura: ELSEVIER SCIENCE
Seria Studies in Surface Science and Catalysis
ISBN-10: 0443333319
Pagini: 450
Dimensiuni: 191 x 235 mm
Editura: ELSEVIER SCIENCE
Seria Studies in Surface Science and Catalysis
Cuprins
Part 1 - The transformative scenario and S&T backgrounds
Section 1.1: The Changing Scenario for Energy and Chemistry and its Impact on Catalysis
a. Introductory paper addressing (among other aspects): the energy-chemistry nexus, drivers for a new sustainable energy scenario, a new vision for refineries, the role of chemical energy storage, enabling a fossil-free chemical production
b. An industrial-oriented perspective (opportunities and challenges for companies by energy and chemistry transition)
c. New trends and challenges for catalysis
d. Fundamental aspects of catalysis to address the challenges and open new perspectives
Section 1.2: Sustainable Energy, Policy, Societal and Educational Aspects
a. Emerging Sustainable Technologies to reach carbon neutrality
b. Transition governance and socio-technical system innovation for the circular economy and energy/chemistry transition
c. The EU innovation framework to accelerate the transition
d. Policy and large initiatives on renewable energy and chemistry
e. The climate mitigation potential of CO2 Capture and Utilisation (CCU) technologies
f. The roadmaps for innovation and the stakeholder community
g. The challenge of energy transition for chemical industries, the case example of Casale SA
h. Opening new possibilities for startup, the case of Sypox
Part 2 - The science and technology advances
Section 2.1: Catalysis and Technologies for Decarbonisation and Closing the Carbon Cycle
a. Chemical engineering advances to decarbonise and close the carbon cycle in industrial processes
b. Catalysis in process electrification
c. Sustainable catalytic processes based on renewable energy
d. From nanoscale to single atoms in CO2 catalytic conversion
e. Operando methods to study CO2 conversion driven by renewable energy sources
f. Unlocking the potential of plasma catalysis
g. Fundamental challenges for zeolite to address decarbonisation
Section 2.2: Catalysis for harvesting solar energy
a. From lab to large-scale devices for producing solar fuels
b. Water Splitting Using Semiconductor Photocatalysts
c. Molecular Chemistry for Solar Fuels: From Natural to Artificial Photosynthesis
d. Connecting dots between natural and artificial Photosynthesis
e. Photo(electro)catalytic devices for solar fuels
f. Emerging material engineering strategies for photothermal catalysis
g. Metal–organic framework materials in photo (electro) catalytic applications
Section 1.1: The Changing Scenario for Energy and Chemistry and its Impact on Catalysis
a. Introductory paper addressing (among other aspects): the energy-chemistry nexus, drivers for a new sustainable energy scenario, a new vision for refineries, the role of chemical energy storage, enabling a fossil-free chemical production
b. An industrial-oriented perspective (opportunities and challenges for companies by energy and chemistry transition)
c. New trends and challenges for catalysis
d. Fundamental aspects of catalysis to address the challenges and open new perspectives
Section 1.2: Sustainable Energy, Policy, Societal and Educational Aspects
a. Emerging Sustainable Technologies to reach carbon neutrality
b. Transition governance and socio-technical system innovation for the circular economy and energy/chemistry transition
c. The EU innovation framework to accelerate the transition
d. Policy and large initiatives on renewable energy and chemistry
e. The climate mitigation potential of CO2 Capture and Utilisation (CCU) technologies
f. The roadmaps for innovation and the stakeholder community
g. The challenge of energy transition for chemical industries, the case example of Casale SA
h. Opening new possibilities for startup, the case of Sypox
Part 2 - The science and technology advances
Section 2.1: Catalysis and Technologies for Decarbonisation and Closing the Carbon Cycle
a. Chemical engineering advances to decarbonise and close the carbon cycle in industrial processes
b. Catalysis in process electrification
c. Sustainable catalytic processes based on renewable energy
d. From nanoscale to single atoms in CO2 catalytic conversion
e. Operando methods to study CO2 conversion driven by renewable energy sources
f. Unlocking the potential of plasma catalysis
g. Fundamental challenges for zeolite to address decarbonisation
Section 2.2: Catalysis for harvesting solar energy
a. From lab to large-scale devices for producing solar fuels
b. Water Splitting Using Semiconductor Photocatalysts
c. Molecular Chemistry for Solar Fuels: From Natural to Artificial Photosynthesis
d. Connecting dots between natural and artificial Photosynthesis
e. Photo(electro)catalytic devices for solar fuels
f. Emerging material engineering strategies for photothermal catalysis
g. Metal–organic framework materials in photo (electro) catalytic applications