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In the rectangle of the above figure, the sides have lengths $$5.0 \ cm$$ and $$15 \ cm$$, $$q_1 = -5.0 \ \mu C$$, and $$q_2 = +2.0 \ \mu C$$. With $$V=0$$ at infinity, what is the electric potential at
(a) corner A and
(b) corner B
(c) How much work is required to move a charge $$q_3 = +3.0 \ \mu C$$ from B to A along a diagonal of the rectangle?
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Q1
In the rectangle of the above figure, the sides have lengths $$5.0 \ cm$$ and $$15 \ cm$$, $$q_1 = -5.0 \ \mu C$$, and $$q_2 = +2.0 \ \mu C$$. With $$V=0$$ at infinity, what is the electric potential at
(a) corner A and
(b) corner B
(c) How much work is required to move a charge $$q_3 = +3.0 \ \mu C$$ from B to A along a diagonal of the rectangle?
(a) corner A and
(b) corner B
(c) How much work is required to move a charge $$q_3 = +3.0 \ \mu C$$ from B to A along a diagonal of the rectangle?
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Q2
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Q4
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Q5
In the rectangle , shown below , the two corners have charges q1=5μC and q2=+2.0μC.. The work done in moving a charge +3.0μC. from B to A is
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