Lectures related to Hydrogen Evolution Catalysis

Molecular Catalysts: Design and Applications

Explores the design and advantages of molecular catalysts, focusing on their applications for hydrogen evolution reactions and the concept of overpotential.

Phase Transitions: Understanding Thermodynamic Stability

Explores phase transitions in thermodynamics, focusing on stability criteria and real-world applications.

Thermodynamic Functions and Equilibria: Mathematical Tools

Discusses thermodynamic functions, their mathematical tools, and key relationships between state variables in thermodynamics.

Thermodynamics: Exploring Thermodynamic Potentials and Equilibrium States

Covers thermodynamic potentials and their role in system equilibrium with reservoirs.

Open Systems, Thermodynamic Potentials

Explores state variables, homogeneous functions, chemical potential, and thermodynamic potentials in open systems.

Phase Transitions: Stability Criteria

Explores phase transitions and stability criteria in thermodynamics, emphasizing entropy, internal energy, and thermodynamic potentials.

Heat Transfer: Equilibrium Approach and Thermodynamic Potentials

Reviews heat transfer mechanisms, entropy, and thermodynamic potentials in relation to equilibrium and Carnot cycles.

H2 Production: Catalysis for Emission Control and Energy Production

Explores the role of hydrogen in low-emissions production and the different reforming processes involved.

Approach to Thermodynamic Equilibrium: Electrolysis of Water

Explores the application of thermodynamic potentials through the example of electrolysis of water.

Applications of Thermodynamic Potentials: Statistical View and Chemical Mixtures

Delves into the relationship between chemical potential and entropy in mixtures.

Thermodynamic Systems: First Principle and Applications

Covers thermodynamic systems, the first principle, and their applications in physics.

Thermodynamic Functions and Calorimetric Coefficients

Discusses thermodynamic functions, calorimetric coefficients, and their relationships in physical systems.

Thermodynamics Basics

Introduces the fundamental concepts of thermodynamics, including energy conservation, system definitions, and different forms of work.

Thermodynamic Principles: Equilibrium, Constraints, and Potentials

Explores internal constraints, equilibrium, variational principles, thermodynamic potentials, and Maxwell relations in classical thermodynamics.

Thermodynamic Potentials

Explains the concept of energy minimization and the role of free energies as thermodynamic potentials in closed systems.

Curvature of State Functions

Explores the concavity of entropy in isolated systems with two subsystems and the curvature of potentials.

Potentials: Introduction

Introduces thermodynamic potentials and their application in equilibrium problems and heat transfer.

Approach to Thermodynamic Equilibrium in Closed Systems

Explores the rules for approaching equilibrium in closed systems and the minimization of thermodynamic potentials.

Thermodynamic Potentials

Explains thermodynamic potentials and their significance in thermodynamics.

Chemical Potential and Thermodynamic Functions in Mixtures

Covers chemical potential variations and thermodynamic functions in mixtures, emphasizing their implications in real and ideal gases.