Lectures related to Atmospheric Models: Homogeneous & Constant Gradient

Explores fundamental thermodynamics concepts, laws, energy transfer, and system analysis.

Explores evaluating properties of substances, including liquids, solids, ideal gases, and real gases, emphasizing specific heat and enthalpy.

Earth's Climate System: Components and Interactions

Covers the Earth's climate system components, interactions, and energy balance, including the impact of anthropogenic forcings and the role of the biosphere.

Calorimetry: Properties of Ideal Gases

Provides an overview of calorimetry and the thermodynamic properties of ideal gases, including their state equations and heat capacities.

Kinetic Theory of Gases: Ideal and Van der Waals Models

Explains the kinetic theory of gases, focusing on ideal gas behavior and the van der Waals model.

Earth's Atmosphere: Evolution and Impact

Delves into the evolution of Earth's atmosphere and its impact on climate.

Thermodynamics: Heat Capacity of Ideal and Van der Waals Gases

Discusses the heat capacity of ideal gases and solids, and the Van der Waals equation's implications for real gases.

Chemical Equilibria and Reactivity

Explores gas properties, pressure, ideal and real gases, energy in reactions, and gas laws.

Introduction to Astrophysics: Hydrostatic Equilibrium

Covers hydrostatic equilibrium, pressure profile, mean molecular mass, and atmosphere retention conditions in astrophysics.

Atmospheric Boundary Layer

Explains the vertical structure of the atmosphere, focusing on the atmospheric boundary layer and its key features.

Buoyancy and Thermodynamic Principles: Understanding Pressure and Temperature

Discusses buoyancy, pressure, temperature, and their interrelations in thermodynamics.

First Principle of Thermodynamics

Explains the conservation of energy in thermodynamic systems during heat and work exchange processes.

Chemical Potential and Thermodynamic Functions in Mixtures

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

Entropy and the Second Law of Thermodynamics

Covers entropy, its definition, and its implications in thermodynamics.

Chemistry: Atomic Structure and Thermodynamics

Covers atomic structure, thermodynamics, material properties, and ideal gas law.

Gas Laws: Dynamics

Delves into gas dynamics, exploring momentum changes during collisions and the principles of temperature and kinetic energy.

Thermodynamics: Real Gases and Phase Transitions

Discusses the thermodynamic behavior of real gases and phase transitions, including the Joule-Thomson effect and latent heat values.

Ideal Gas Laws

Explores ideal gas laws, entropy, internal energy, and specific heat capacities, emphasizing Mayer's relations and adiabatic reversible processes.

Thermodynamics: Entropy and Ideal Gases

Explores entropy, ideal gases, and TDS equations in thermodynamics, emphasizing the importance of the Clausius inequality and the Carnot cycle.

Specific Heat Capacity at Constant Volume

Explains the quantification of temperature changes and heat exchange in gases, focusing on specific heat capacity at constant volume.