Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

10.7 VECTOR OPERATORS


10.7.3 Curl of a vector field

Thecurlof a vector fielda(x, y, z) is defined by


curla=∇×a=

(
∂az
∂y


∂ay
∂z

)
i+

(
∂ax
∂z


∂az
∂x

)
j+

(
∂ay
∂x


∂ax
∂y

)
k,

whereax,ayandazare thex-,y-andz- components ofa. The RHS can be


written in a more memorable form as a determinant:


∇×a=









ijk

∂x


∂y


∂z
ax ay az









, (10.35)

where it is understood that, on expanding the determinant, the partial derivatives


in the second row act on the components ofain the third row. Clearly,∇×ais


itself a vector field. Any vector fieldafor which∇×a= 0 is said to beirrotational.


Find the curl of the vector fielda=x^2 y^2 z^2 i+y^2 z^2 j+x^2 z^2 k.

The curl ofais given by


∇φ=

∣∣



∣∣



∣∣


ijk

∂x


∂y


∂z
x^2 y^2 z^2 y^2 z^2 x^2 z^2

∣∣



∣∣



∣∣


=− 2


[


y^2 zi+(xz^2 −x^2 y^2 z)j+x^2 yz^2 k

]


.


For a vector fieldv(x, y, z) describing the local velocity at any point in a fluid,

∇×vis a measure of the angular velocity of the fluid in the neighbourhood of


that point. If a small paddle wheel were placed at various points in the fluid then


it would tend to rotate in regions where∇×v= 0 , while it would not rotate in


regions where∇×v= 0.


Another insight into the physical interpretation of the curl operator is gained

by considering the vector fieldvdescribing the velocity at any point in a rigid


body rotating about some axis with angular velocityω.Ifris the position vector


of the point with respect to some origin on the axis of rotation then the velocity


of the point is given byv=ω×r. Without any loss of generality, we may take


ωto lie along thez-axis of our coordinate system, so thatω=ωk. The velocity


field is thenv=−ωyi+ωxj. The curl of this vector field is easily found to be


∇×v=









ijk

∂x


∂y


∂z
−ωy ωx 0









=2ωk=2ω. (10.36)
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