Entropy, Expansion, and the Second Law

In-class Content

Activity: Free Expansion Not-Quiz and Discussion

Link to Free Expansion Not-Quiz and Discussion Activity

Activity Highlights

  1. This integrated laboratory activity is designed to help students understand heat, heat capacity and entropy.
  2. Students use a water proof resistor to heat ice water while measuring the temperature.
  3. In the lab write-up, students analyze their data to find heat capacity, latent heat, and changes in entropy.

Homework

  1. (FreeExpansion) What goes here?

    The internal energy is of any ideal gas can be written as \begin{align} U &= U(T,N) \end{align} meaning that the internal energy depends only on the number of particles and the temperature, but not the volume.\footnote{This relationship happens to be linear at low temperatures, where “low” is defined relative to the energy of the excited states of the molecules or atoms.} The ideal gas law \begin{align} pV &= Nk_BT \end{align} defines the relationship between $p$, $V$ and $T$. You may take the number of molecules $N$ to be constant. Consider the free adiabatic expansion of an ideal gas to twice its volume. “Free expansion” means that no work is done, but also that the process is also neither quasistatic nor reversible.

    1. What is the change in temperature of the gas?

    2. What is the change in entropy of the gas? How do you know this?


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