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Estimated Time: 50 minutes (includes 20 min. wrap-up)
This activity works well as a follower of the Calculating a Total Differential activity. Many of the concepts of taking a total differential and using a chain rule diagram to keep track of differentials will apply to this activity as well. Students are placed into small groups and asked to find expressions for the differentials $$-V \left(\frac{\partial p}{\partial V}\right)_{T}$$ and $$-V \left(\frac{\partial p}{\partial V}\right)_S .$$
We use this activity early in the course to give students practice working with partial derivatives, and to demonstrate mathematically that the “thing held constant” really does make a difference. Finding the isothermal bulk modulus is pretty easy. Finding the adiabatic bulk modulus requires figuring out how to hold entropy fixed. There are two distinct approaches that one can use for this problem. One is to apply rules for partial derivatives and changes of variables, which is the traditional approach. The other (which I lean towards) is to use total differentials alone (plus algebra) to solve this problem.
The total differential approach requires that one look for an equation that looks like: \[ dp = A dV + B dS \] where $A$ and $B$ are quantities to solve for. Once we have an equation that looks like this, we can immediately identify \[ A = \left(\frac{\partial p}{\partial V}\right)_S \] and we are done. We find an equation in this form by constructing total differentials of the equations provided and algebraically eliminating the differentials we don't want in the final equation. The only requirement is that we never divide by an infinitesimal quantity.