VECTOR CALCULUS
∇Φ=
∂Φ
∂ρˆeρ+1
ρ∂Φ
∂φˆeφ+∂Φ
∂zˆez∇·a =1
ρ∂
∂ρ(ρaρ)+1
ρ∂aφ
∂φ+
∂az
∂z∇×a =1
ρ∣
∣∣
∣
∣∣
∣
∣
eˆρ ρeˆφ eˆz
∂
∂ρ∂
∂φ∂
∂z
aρ ρaφ az∣
∣∣
∣
∣∣
∣
∣
∇^2 Φ=
1
ρ∂
∂ρ(
ρ∂Φ
∂ρ)
+
1
ρ^2∂^2 Φ
∂φ^2+
∂^2 Φ
∂z^2Table 10.2 Vector operators in cylindrical polar coordinates; Φ is a scalar
field andais a vector field.defined by the vectorsdρˆeρ,ρdφˆeφanddzˆez:
dV=|dρˆeρ·(ρdφeˆφ×dzˆez)|=ρdρdφdz,which again uses the fact that the basis vectors are orthonormal. For a simple
coordinate system such as cylindrical polars the expressions for (ds)^2 anddVare
obvious from the geometry.
We will now express the vector operators discussed in this chapter in termsof cylindrical polar coordinates. Let us consider a vector fielda(ρ, φ, z)anda
scalar field Φ(ρ, φ, z), where we use Φ for the scalar field to avoid confusion with
the azimuthal angleφ. We must first write the vector field in terms of the basis
vectors of the cylindrical polar coordinate system, i.e.
a=aρeˆρ+aφˆeφ+azˆez,whereaρ,aφandazare the components ofain theρ-,φ-andz- directions
respectively. The expressions for grad, div, curl and∇^2 can then be calculated
and are given in table 10.2. Since the derivations of these expressions are rather
complicated we leave them until our discussion of general curvilinear coordinates
in the next section; the reader could well postpone examination of these formal
proofs until some experience of using the expressions has been gained.
Express the vector fielda=yzi−yj+xz^2 kin cylindrical polar coordinates, and hence
calculate its divergence. Show that the sameresult is obtained by evaluating the divergence
in Cartesian coordinates.The basis vectors of the cylindricalpolar coordinate system are given in (10.49)–(10.51).
Solving these equations simultaneously fori,jandkwe obtain
i=cosφeˆρ−sinφˆeφ
j=sinφˆeρ+cosφˆeφ
k=ˆez.