VECTOR CALCULUS
∇(φ+ψ)=∇φ+∇ψ
∇·(a+b)=∇·a+∇·b
∇×(a+b)=∇×a+∇×b
∇(φψ)=φ∇ψ+ψ∇φ
∇(a·b)=a×(∇×b)+b×(∇×a)+(a·∇)b+(b·∇)a
∇·(φa)=φ∇·a+a·∇φ
∇·(a×b)=b·(∇×a)−a·(∇×b)
∇×(φa)=∇φ×a+φ∇×a
∇×(a×b)=a(∇·b)−b(∇·a)+(b·∇)a−(a·∇)bTable 10.1 Vector operators acting on sums and products. The operator∇is
defined in (10.25);φandψare scalar fields,aandbare vector fields.Therefore the curl of the velocity field is a vector equal to twice the angular
velocity vector of the rigid body about its axis of rotation. We give a full
geometrical discussion of the curl of a vector in the next chapter.
10.8 Vector operator formulaeIn the same way as for ordinary vectors (chapter 7), for vector operators certain
identities exist. In addition, we must consider various relations involving the
action of vector operators on sums and products of scalar and vector fields. Some
of these relations have been mentioned earlier, but we list all the most important
ones here for convenience. The validity of these relations may be easily verified
by direct calculation (a quick method of deriving them using tensor notation is
given in chapter 26).
Although some of the following vector relations are expressed in Cartesiancoordinates, it may be proved that they are all independent of the choice of
coordinate system. This is to be expected since grad, div and curl all have clear
geometrical definitions, which are discussed more fully in the next chapter and
which do not rely on any particular choice of coordinate system.
10.8.1 Vector operators acting on sums and productsLetφandψbe scalar fields andaandbbe vector fields. Assuming these fields
are differentiable, the action of grad, div and curl on various sums and products
of them is presented in table 10.1.
These relations can be proved by direct calculation.