• Visualization of divergence and curl.

• Definition of divergence and curl.
• Geometry of divergence and curl, either through a geometric definition or through Stokes' Theorem and the Divergence Theorem.

• Students may need to be reminded what circulation is.
• Students may not have seen flux in 2 dimensions.

• whiteboards and pens
• formula sheet for div and curl in spherical and cylindrical coordinates (Each group may need its own copy.)
• divergence and curl transparency (master available here)
• blank transparencies and pens

• Discuss the effect of choosing loops of different shapes, especially those adapted to the given vector field.
• Talk about the geometry of sinks and sources (for divergence) and paddlewheels (for curl).

• While students are working on this activity, draw the vector fields on the board to use during the wrapup. Alternatively, bring an overhead transparency showing the vector fields (and blank transparencies for students to write on).
• Students like this lab; it should flow smoothly and quickly.
• Students may need to be reminded what $\OINT$ means, and that the positive orientation in the plane is counterclockwise.
• Yes, two pairs of questions are really the same.
• Make sure the paths do not go around the origin.
• Encourage each group to work on at least two vector fields, which are in different rows and columns. Include one vector field from the third column if time permits.
• Encourage each group to consider, for a single vector field, moving their loop to another location. This is especially effective (and in fact essential) for the two vector fields in the third column.
• See the discussion of using transparencies for the hill activity
• Students may eventually realize that the vector fields in the middle column are linear combinations of the vector fields in the first column, which are in turn “pure curl” and “pure divergence”, respectively.

• Divergence and curl are not just about the behavior near the origin. Derivatives are about change — the difference between nearby vectors.

(MHG refers to McCallum, Hughes-Hallett, Gleason, et al. [3].)

• MHG §19.1:20
• MHG §20.2:16
• MHG §20.3:10,12,20
• MHG §20.4:22

(none yet)

• Emphasize the importance of divergence and curl in applications.
• Ask students how to determine which vector fields are conservative! (A single closed path with nonzero circulation suffices to show that a vector field is not conservative. The best geometric way we know to show that a vector field is conservative is to try to draw the level curves for which the given vector field would be the gradient.)
• Discuss the fact that $\rhat\over r$ and $\phat\over r$ are both curl-free and divergence-free; this is counterintuitive, but crucial for electromagnetism. (These are, respectively, the electric/magnetic field of a charged/current-carrying wire along the $z$-axis.)
• Discuss the behavior of $\rhat\over r^n$ and $\phat\over r^n$, emphasizing that both the divergence and curl vanish when $n=1$.
• Relate these examples to the magnetic field of a wire ($\BB={\phat\over r}$) and the electric field of a point charge ($\EE={\rhat\over r^2}$; this is the spherical $r$).
• Show students how to compute divergence and curl of these vector fields in cylindrical coordinates.
• Trying to estimate divergence and curl from a single plot of a vector field confronts students with the need to zoom in. Technology can be useful here.
• An excellent JAVA applet for analyzing the geometry of vector fields, including the capability to zoom in, is Matthias Kawski's Vector Field Analyzer, available at http://math.la.asu.edu/~kawski/vfa2.
• Point students to our paper on Electromagnetic Conic Sections which appeared in Am. J. Phys. 70, 1129–1135 (2002), and which is also available on the Bridge Project website.
• Most physical applications of the divergence are 3-dimensional, rather than 2-dimensional. Each vector field in this activity could be regarded as a horizontal 3-dimensional vector field by assuming that there is no $z$-dependence, in which case the flux can be computed through a 3-dimensional box whose cross-section is the loop, and whose horizontal top and bottom do not contribute.