Given five charges of values q1 = q4 = +2.8 nC, q2 = q5 = –5.3 nC, and q3 = –3.4 nC, find the net electric flux through the Gaussian surface shown in the figure.
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Given five charges of values q1 = q4 = +2.8 nC, q2 = q5 = –5.3 nC, and q3 = –3.4 nC, find the net electric flux through the Gaussian surface shown in the figure.
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- A charge q = 2.00 µC is placed at the origin in a region where there is already a uniform electric field É = (100 N/C) i . Calculate the flux of the net electric field through a Gaussian sphere of radius R = 10.0 cm centered at the origin. (Eo = 8.85 x 10-12 C²/N • m2) O 2.26 x 105 N • m²/C zero O 5.52 x 105 N • m?/C O 1.13 x 105 N • m²/CGiven the two charged particles shown in the figure below, find the electric field at the origin. (Let q₁ = -30.00 nC and 92 = 9.00 nC. Express your answer in vector form.) N/C E = -4 92 -2 y (cm) 4 2 -2 -4 2 4 91 x (cm)An unknown charge sits on a conducting solid sphere of radius 9.5 cm. If the electric field 13 cm from the center of the sphere has magnitude 4.3 × 103 N/C and is directed radially inward, what is the net charge on the sphere?
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