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10: The Joule and Joule-Thomson Experiments

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    • 10.1: Introduction
      This page covers adiabatic expansion of gases, highlighting the differences when expanding against external pressure versus into a vacuum. It explains that while gases perform external work, causing temperature drops, expanding into a vacuum keeps ideal gases at constant temperature. Non-ideal gases may experience slight temperature variations due to intermolecular forces. The discussion connects these concepts to the Joule and Joule-Thomson experiments.
    • 10.2: The Joule Experiment
      This page explains Joule's experiment, highlighting that ideal gases maintain a constant internal energy without temperature drop during expansion. It contrasts this with real gases, which experience a slight temperature decrease quantified by the Joule coefficient. The page also covers the derivation of the Joule coefficient, its connections to internal energy and enthalpy in PVT-space, and provides calculations for van der Waals gases alongside practical examples.
    • 10.3: The Joule-Thomson Experiment
      This page discusses the Joule-Kelvin experiment, highlighting the relationship between temperature and pressure of gases at constant enthalpy through the Joule-Thomson coefficient (µ). It covers mathematical derivations related to internal energy, enthalpy, and entropy, explaining that the Joule-Thomson effect can either cool or heat gases based on their initial temperature relative to the inversion temperature. This effect is crucial for gas liquefaction techniques.
    • 10.4: CP Minus CV
      This page derives expressions for the difference in heat capacities \(C_P - C_V\) for non-ideal gases, starting with the ideal gas relationship \(C_P - C_V = R\). It explores how this discrepancy can be expressed using partial derivatives, leading to alternative expressions based on different equations of state.
    • 10.5: Blackbody Radiation
      This page explores the application of thermodynamics to electromagnetic radiation, intertwining quantum theory and classical thermodynamics. It reviews historical perspectives on blackbody radiation, highlighting classical theory limitations and introducing Kirchhoff's radiation law.

    This page titled 10: The Joule and Joule-Thomson Experiments is shared under a CC BY-NC 4.0 license and was authored, remixed, and/or curated by Jeremy Tatum.