our different configurations show charge distributions and closed Gaussian surfaces. Assume that the surface normals are directed outward for each closed surface. If a charge appears to be located within a Gaussian surface, then it is, as opposed to being in the foreground or the background. The charges have the following values: q1= -22.6 nC q2= +32.7 nC q3= +3.58 nC q4= -3.29 nC q5= +5.41 nC Part (a) What is the total electric flux, in newtons squared meters per coulomb, through the closed surface shown in drawing (a) of the figure? Part (b) What is the total electric flux, in newtons squared meters per coulomb, through the closed surface shown in drawing (b) of the figure? Part (c) What is the total electric flux, in newtons squared meters per coulomb, through the closed surface shown in drawing (c) of the figure? Part (d) Drawing (d) of the figure shows a portion of an infinite conductng plane viewed edge-on. The Gaussian surface is a "Gaussian pillbox" whose sides are perpendicular to the infinite plane, but the end cap, with an area of 4.0 x 10^-4 m^2, is parallel to the plane. The conductor has a charge per unit area of o= 2.0 uC/m^2. What is
Four different configurations show charge distributions and closed Gaussian surfaces. Assume that the surface normals are directed outward for each closed surface. If a charge appears to be located within a Gaussian surface, then it is, as opposed to being in the foreground or the background. The charges have the following values:
q1= -22.6 nC
q2= +32.7 nC
q3= +3.58 nC
q4= -3.29 nC
q5= +5.41 nC
Part (a) What is the total electric flux, in newtons squared meters per coulomb, through the closed surface shown in drawing (a) of the figure?
Part (b) What is the total electric flux, in newtons squared meters per coulomb, through the closed surface shown in drawing (b) of the figure?
Part (c) What is the total electric flux, in newtons squared meters per coulomb, through the closed surface shown in drawing (c) of the figure?
Part (d) Drawing (d) of the figure shows a portion of an infinite conductng plane viewed edge-on. The Gaussian surface is a "Gaussian pillbox" whose sides are perpendicular to the infinite plane, but the end cap, with an area of 4.0 x 10^-4 m^2, is parallel to the plane. The conductor has a charge per unit area of o= 2.0 uC/m^2. What is the total electric flux, in newton squared meters per coulomb, through the Gaussian surface?
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