Flux of a vector and parametric equation

AI Thread Summary
The discussion focuses on computing the flux of the vector field v = 3xy i + xz^2 j + y^3 k through the unit sphere using Gauss's Law. The initial calculation leads to the integral of 3y over the volume, which is evaluated as zero due to the symmetry of the integrand over a symmetric region. Participants note that while the spherical parametrization is not necessary, the radial part of the integral should be considered, although it remains constant for the unit sphere. There is a consensus that the symmetry of the field allows for a straightforward conclusion without detailed calculations. The importance of correctly applying the divergence theorem in this context is emphasized, highlighting the conceptual understanding of the problem.
Xsnac
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Homework Statement



Compute the flux of a vector field ##\vec{v}## through the unit sphere, where

$$ \vec{v} = 3xy i + x z^2 j + y^3 k $$

Homework Equations



Gauss Law:
$$ \int (\nabla \cdot \vec{B}) dV = \int \vec{B} \cdot d\vec{a}$$

The Attempt at a Solution


Ok so after applying Gauss Law, one gets
$$ \int 3y dV $$
and after converting it into a spherical integral I get
$$3 \int_0^{ \pi} \sin^2 \theta d \theta \int_0^{2 \pi} \sin \phi d \phi = 0$$ since integral of sin over a full period is. Is this correct? or if not, where did I go wrong?
 
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It looks fine, but you do not need to actually do the spherical parametrisation. You could just use that the integrand is asymmetric over a symmetric region so the result must be zero.

Edit: Also, you are missing the radial part of the integral, but it will not matter.
 
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Xsnac I've been making the transformation right now and seems me that your work is ok.
 
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Orodruin said:
It looks fine, but you do not need to actually do the spherical parametrisation. You could just use that the integrand is asymmetric over a symmetric region so the result must be zero.

Edit: Also, you are missing the radial part of the integral, but it will not matter.
Thanks. Regarding the radial part, it specified it's unit sphere therefore constant, and = 1 so I neglected it.
 
Orodruin said:
It looks fine, but you do not need to actually do the spherical parametrisation. You could just use that the integrand is asymmetric over a symmetric region so the result must be zero.

Edit: Also, you are missing the radial part of the integral, but it will not matter.
Yes, visualizing the field in the space there are a symetry in the plane XZ, then like the volume has also spherical symetry around the point (0,0,0) we don't need to calculate anything. So is more fun! :woot::woot:
 
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Xsnac said:
Thanks. Regarding the radial part, it specified it's unit sphere therefore constant, and = 1 so I neglected it.
This is conceptually wrong, even if the result is the same. Your original surface of integration was the unit sphere. In using the divergence theorem, you rewrite the closed surface integral as a volume integral over the enclosed volume, in this case the unit ball.
 

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