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Solar Energy Conversion: Nanomaterials and Photoelectrochemistry
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Related lectures (32)
Solar Fuels: Conversion Pathways and Reactor Concepts
Explores solar energy conversion into fuels, reactor concepts, stringent material requirements, proposed devices, efficiency considerations, and net value per energy.
Solar Fuels: Conversion Pathways and Reactor Concepts
Explores solar energy conversion into fuels, reactor concepts, and material requirements for efficient photoelectrochemistry.
Solar Fuels: Reactor Concepts and Conversion Pathways
Explores reactor designs, conversion pathways, and materials for solar fuel production, emphasizing solar thermolysis and thermochemical cycles.
Solar Fuels: Conversion Pathways and Reactor Concepts
Explores solar fuel conversion pathways, reactor designs, and challenges in sustainable solar-to-fuel technologies.
Photovoltaic Efficiency: Technologies and Calculations
Discusses photovoltaic efficiency calculations and technologies, focusing on silicon solar cells and their impact on renewable energy production.
Chemical Reaction Engineering: Conversion and Reactor Sizing
Explores the algorithm for solving chemical reaction engineering problems, focusing on conversion and reactor sizing.
Conversion and Reactor Sizing
Explores conversion, reactor sizing, and series reactors with practical examples.
Reactor Technology: Reactivity Variations and Control
Explores reactivity variations in reactor technology, covering short-term, medium-term, and long-term effects, means of control, and consequences.
Chemical Reaction Engineering: Reactor Design
Explores chemical kinetics, reactor design, and critical thinking in chemical reaction engineering.
Modified One Group Theory: Media Containing Fuel
Explores the modified one group theory for thermal reactors, focusing on media containing fuel and resonance treatment.
Multiplying media: Analytical Solutions and Non-leakage Probability
Covers media containing fuel, analytical solutions, and non-leakage probability for thermal and fast neutrons.
Nuclear Reactors: Concepts and Analysis
Explores nuclear reactor physics, covering basic principles, specific reactor types, accidents like Chernobyl, and advanced technologies.
Chemical Reaction Engineering
Focuses on chemical kinetics, reactor design, and problem-solving skills with interactive modules for active participation.
Nuclear Reactor Criticality Analysis
Covers the formalism and criticality analysis of nuclear reactors, focusing on mathematical equations and reactor stability.
Introduction to Nuclear Engineering
Covers various topics in nuclear engineering, including reactor technology, nuclear physics, and safety analysis assumptions.
Chemical Reaction Engineering: Algorithm and Stoichiometry
Explores the Chemical Reaction Engineering algorithm in batch reactors and CSTRs, focusing on stoichiometry and rate laws.
Chemical reaction engineering: reactor design
Explores the Chemical Reaction Engineering algorithm applied to isothermal reactor design, with examples on SO2 oxidation and N2O4 decomposition.
Neutron chain-reacting systems
Explores chain reactions, multiplication factor, fuel cycles, reactor design, and types of nuclear reactors, ending with a summary of key concepts.
Nuclear Reactor Accidents: TMI2 and Chernobyl
Explores the TMI2 and Chernobyl nuclear reactor accidents, safety features, and Generation IV reactors.
Chemical reaction engineering: reactor design
Focuses on isothermal reactor design, covering mole balances, rate laws, stoichiometry, and pressure drop effects.
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