Heat flux Suppose a solid object in ¡ 3 has a temperature distribution given by T ( x, y, z ). The heat flow vector field in the object is F = –k ▿ T, where the conductivity k > 0 is a property of the material. Note that the heat flow vector points in the direction opposite that of the gradient, which is the direction of greatest temperature decrease. The divergence of the heat flow vector is ▿· F = – k ▿·▿ T = –k ▿ 2 T (the Laplacian of T). Compute the heat flow vector field and its divergence for the following temperature distributions. 57. T ( x , y , z ) = 100 e − x 2 + y 2 + z 2
Heat flux Suppose a solid object in ¡ 3 has a temperature distribution given by T ( x, y, z ). The heat flow vector field in the object is F = –k ▿ T, where the conductivity k > 0 is a property of the material. Note that the heat flow vector points in the direction opposite that of the gradient, which is the direction of greatest temperature decrease. The divergence of the heat flow vector is ▿· F = – k ▿·▿ T = –k ▿ 2 T (the Laplacian of T). Compute the heat flow vector field and its divergence for the following temperature distributions. 57. T ( x , y , z ) = 100 e − x 2 + y 2 + z 2
Solution Summary: The author explains the heat flow vector field and its divergence. If nablacdot F=0, the vector is source free.
Heat fluxSuppose a solid object in ¡3has a temperature distribution given by T(x, y, z). The heat flow vector field in the object isF= –k▿T, where the conductivity k > 0 is a property of the material. Note that the heat flow vector points in the direction opposite that of the gradient, which is the direction of greatest temperature decrease. The divergence of the heat flow vector is ▿·F = –k ▿·▿T = –k▿2T (the Laplacian of T). Compute the heat flow vector field and its divergence for the following temperature distributions.
Suppose that over a certain region of space the electrical potential V is given by the following equation.
V(x, y, z) = 5x² - 3xy + xyz
(a) Find the rate of change of the potential at P(5, 2, 5) in the direction of the vector v = i + j - k.
(b) In which direction does V change most rapidly at P?
73°F
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(c) What is the maximum rate of change at P?
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Find the maximum rate of change of f at the given point and the direction in which it occurs.
f(x, y, z) = x ln(yz), ( 2, 7, 1/7).
maximum rate of change =
direction vector =
The temperature on a cubic box [0, 4] × [0, 4] × [0, 4] (measured in meters) can be describedby the function T (x, y, z) = x2y + y2z degrees F◦. A fly is in position (1, 2, 1) and takesoff in a straight line to the corner (4, 0, 4). Use directional derivatives to calculate the changein temperature the fly experiences as she takes off. Give your answer with 2 decimal digitscorrect.
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