Fundamental Equations: Conservation and Thermodynamics

Related lectures (27)

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Explores entropy, state functions, reversible processes, and the Carnot cycle in thermodynamics.

Explores energy conservation in open systems, analyzing mass and energy transfer in turbines, compressors, and heat exchangers.

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

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

Introduces continuum mechanics, focusing on conservation laws and kinematics for continuous media.

Discusses thermodynamic systems, the first principle of thermodynamics, and energy conservation in various contexts.

Covers the governing equations for forces and motion in continua, including stress, energy conservation, solid deformation, and fluid motion.

Explores thermodynamics, state functions, internal energy, and enthalpy, emphasizing energy conservation and heat exchange in various systems.

Explores calorimetric coefficients for ideal gases, focusing on specific heat capacities and their relationships.

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