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9.7 Divergence and Curl. Vector Fields :. F(x,y)= P(x,y) i + Q(x,y) j F(x,y,z) = P(x,y,z) i + Q(x,y,z) j + R(x,y,z) k. Example 1 : Graph the 2-dim vector field F(x,y)= -y i + x j. Draw vectors of the same length. Download m-file. Divergence. Scalar. Example 2.
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9.7 Divergence and Curl Vector Fields: F(x,y)= P(x,y) i + Q(x,y) j F(x,y,z) = P(x,y,z) i + Q(x,y,z) j + R(x,y,z) k Example 1: Graph the 2-dim vector field F(x,y)= -y i + x j
Draw vectors of the same length Download m-file
Divergence Scalar Example 2 IF Find div F
Curl vector Example 2 IF Find curl F
Curl Cross product of the del operator and the vector F Remarks: 1) 2)
WHY Vector Fields The motion of a wind or fluid can be described by a vector field. The concept of a force field plays an important role in mechanics, electricity, and magnetism.
Physical Interpretations Curl was introduced by Maxwell James Clerk Maxwell (1831-1879) Scottish Physicist [b. Edinburgh, Scotland, June 13, 1831, d. Cambridge, England, November 5, 1879] He published his first scientific paper at age 14, entered the University of Edinburgh at 16, and graduated from Cambridge University.
Physical Interpretations • Curl is easily understood in connection with the flow of fluids. If a paddle device, such as shown in fig, is inserted in a flowing fluid, the the curl of the velocity field F is a measure of the tendency of the fluid to turn the device about its vertical axis w. • If curl F = 0 then flow of the fluid is said to be irrotational. Which means that it is free of vortices or whirlpools that would cause the paddle to rotate. • Note: “irrotational” does not mean that the fluid does not rotate.
Physical Interpretations • The volume of the fluid flowing through an element of surface area per unit time that is , the flux of the vector field F through the area. • The divergence of a velocity field F near a point p(x,y,z) is the flux per unit volume. • If div F(p) > 0 then p is said to be a source for F. since there is a net outward flow of fluid near p • If div F(p) < 0 then p is said to be a sink for F. since there is a net inward flow of fluid near p • If div F(p) = 0 then there are no sources or sinks near p. • The divergence of a vector field can also be interpreted as a measure of the rate of change of the density of the fluid at a point. • If div F = 0 the fluid is said to be incompressible