+4.8 µC is placed at (-1.6 cm, 0.0 cm) and a -2.7 µC charge is placed at (0.0 cm, -3.1 cm) as shown in the igure below. Calculate the electric potential at the origin due to the two charges. How fast must a +1.2 µC charge be moving very far away from the charge distribution shown below so that E comes to rest at the origin. Assume the mass of the charge is 0.02 g. If a proton is released from rest at the origin, how fast is it moving when it is very far away from the origin?

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+4.8 µC is placed at (-1.6 cm, 0.0 cm) and a -2.7 µC charge is placed at (0.0 cm, -3.1 cm) as shown in the
figure below.
Calculate the electric potential at the origin due to the two charges.
How fast must a +1.2 µC charge be moving very far away from the charge distribution shown below so that
t comes to rest at the origin. Assume the mass of the charge is 0.02 g.
If a proton is released from rest at the origin, how fast is it moving when it is very far away from the origin?
Transcribed Image Text:+4.8 µC is placed at (-1.6 cm, 0.0 cm) and a -2.7 µC charge is placed at (0.0 cm, -3.1 cm) as shown in the figure below. Calculate the electric potential at the origin due to the two charges. How fast must a +1.2 µC charge be moving very far away from the charge distribution shown below so that t comes to rest at the origin. Assume the mass of the charge is 0.02 g. If a proton is released from rest at the origin, how fast is it moving when it is very far away from the origin?
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