If an imaginary test charge is placed on an equipotential line, if it moves with the...
Equipotential surfaces A positive point charge is surrounded by an equipotential surface A, which has a radius of rA. A positive test charge moves from surface A to another equipotential surface B, which has a radius rB. In the process, the electric force does negative work (a) Does the electric force acting on the test charge have the same or opposite direction as the displacement of the test charge? O The electric force has the same direction as the displacement...
How much work is done moving a charge along an equipotential surface (line)? Explain.
Question 3 (#859685) Equipotential Lines) Which of the following statements is NOT true about equipotential lines? Select the correct answer O All points on an equipotential line are at the same voltage. A positively charged particle loses potential energy as it moves from one equipotential line to another equipotential line of a lower voltage. Your Answer Equipotential lines run perpendicular to the electric field lines on a 2- dimensional surface. For a charged particle on an equipotential line, there is...
A positive point charge (q = +6.2 10-8 C) is surrounded by an equipotential surface A, which has a radius of rA = 1.7 m. A positive test charge (q0 = +3.0 10-11 C) moves from surface A to another equipotential surface B, which has a radius rB. The work done by the electric force as the test charge moves from surface A to surface B is WAB = -8.6 10-9 J. Find rB.
A positive point charge (q = +5.97 x 10-8 C) is surrounded by an equipotential surface A, which has a radius of rA = 1.52 m. A positive test charge (q0 = +4.61 x 10-11 C) moves from surface A to another equipotential surface B, which has a radius rB. The work done by the electric force as the test charge moves from surface A to surface B is WAB = -8.39 x 10-9 J. Find rB.
A positive point charge (q = +9.18 x 10-8 C) is surrounded by an equipotential surface A, which has a radius of rA = 1.85 m. A positive test charge (q0 = +4.62 x 10-11 C) moves from surface A to another equipotential surface B, which has a radius rB. The work done by the electric force as the test charge moves from surface A to surface B is WAB = -9.30 x 10-9 J. Find rB
A positive point charge (q = +5.40 x 10-8 C) is surrounded by an equipotential surface A, which has a radius of rA = 2.86 m. A positive test charge (q0 = +4.11 x 10-11 C) moves from surface A to another equipotential surface B, which has a radius rB. The work done by the electric force as the test charge moves from surface A to surface B is WAB = -5.25 x 10-9 J. Find rB.
A positive point charge (q = +5.00 times 10-8 C) is surrounded by an equipotential surface A, which has a radius of rA = 1.72 m. A positive test charge (q0 = +3.33 x 10"11 C) moves from surface A to another equipotential surface B, which has a radius rB. The work done by the electric force as the test charge moves from surface A to surface B is WAB = -7.47 x 10"9 J. Find rB.
A positive point charge (q = +7.55 x 10-8 C) is surrounded by an equipotential surface A, which has a radius of rA = 2.99 m. A positive test charge (q0 = +3.53 x 10-11 C) moves from surface A to another equipotential surface B, which has a radius rB. The work done by the electric force as the test charge moves from surface A to surface B is WAB = -9.38 x 10-9 J. Find rB.
A positive point charge (q = +6.99 x 10^(-8) C) is surrounded by an equipotential surface A, which has a radius of rA = 2.63 m. A positive test charge (q0 = +3.62 x 10^(-11) C) moves from surface A to another equipotential surface B, which has a radius rB. The work done by the electric force as the test charge moves from surface A to surface B is WAB = -8.22 x 10^(-9) J. Find rB.