A -7.8 C charge is moving in a electric potential given by V(x) = 6 x4 (V). The particle begins at x = 9 m and ends at x = 19 m. Calculate the change in electrical potential energy of the charge, in J. (Please answer to the fourth decimal place - i.e 14.3225)
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A -7.8 C charge is moving in a electric potential given by V(x) = 6 x4 (V). The particle begins at x = 9 m and ends at x = 19 m. Calculate the change in electrical potential energy of the charge, in J.
(Please answer to the fourth decimal place - i.e 14.3225)
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- Consider two separate systems with four charges of the same magnitude q = 16 µC arranged in the vertexes of a square of length h = 35 cm, see the picture below. Calculate the electric potential at the center of the square (points A and C) and at the middle of the bottom side of the square (points B and D). y y h h А. C. h В D b- The potential at point A, VA = 2320457.1x Units v The potential at point B, Vg = 2378380.8 Units V The potential at point C, Vc = 0 Units V The potential at point D, V, = -908380.8: Units v How much work is required to move a -12 µC charge from point A to point B? The work required, WAs =|-0.7349 X Units J How much work is required to move a -12 µC charge from point C to point D? The work required, Wc-o = 10.90 Units J(a) The electric potential in a region is given by the equation V(x, y) = (1.00) xyz +2.00v. sin (3.00-x). What is the force on a 65.4 mC located at position (3.30 m, 4.21 m,-1.80 m)? Give your answer in vector component notation. (b) The electric potential in a region is given by the equation V(x, y, z) = (2.40)x²y + (1.5 V)e (1.002). What is the force on a 12.6 mC located at position (-1.30 m, 2.48 m,-2.10 m)? Give your answer in vector component notation.A thin plastic rod 8.2 cm long carrying charge -0.022 µC is bent into a circular ring. What is the electric potential at the center of the ring, assuming V = 0 at infinity? Express your answer in kV, to at least one digit after the decimal point.
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- How to solve this questionPlease don't provide handwritten solution ..... The electric potential V(x, y, z) in a region of space is given by V(x, y, z) = V0(6x2 − 3y2 − z2), where V0 = 18.0 V and x, y, and z are measured in meters. Find the electric field at the point (1.40 m, 1.40 m, 0). (Express your answer in vector form.)Problem 7: Consider two points in an electric field. The potential at point 1, V1, is 26 V. The potential at point 2, V2, is 159 V. An electron at rest at point 1 is accelerated by the electric field to point 2. Part (a) Write an equation for the change of electric potential energy ΔU of the electron in terms of the symbols given. Part (b) Find the numerical value of the change of the electric potential energy in electron volts (eV). Part (c) Express v2, the speed of the electron at point 2, in terms of ΔU, and the mass of the electron me. Part (d) Find the numerical value of v2 in m/s.
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