A small metal sphere, carrying a net charge `q_1 = -2 mu C`, is held in a stationary position by insulating supports. A second small metal sphere, with a net charge of `q_2 = -8 mu C` and mass `1.50 g`, is projected toward `q_1`. When the two spheres are `0.800 m` apart, `q_2` is moving toward `q_1` with speed `20 ms^-1` as shown in (Fig. 3.151). Assume that the two spheres can be treated as point charges. You can ignore the force of gravity. . The speed of `q_2` when the spheres are `0.400 m` apart is.A. `2 sqrt(10) ms^-1`B. `2 sqrt(6) ms^-1`C. `4 sqrt(10) ms^-1`D. `4 sqrt(6) ms^-1`

A small metal sphere, carrying a net charge `q_1 = -2 mu C`, is held i

1.	A small metal sphere, carrying a net charge `q_1 = -2 mu C`, is held in a stationary position by insulating supports. A second small metal sphere, with a net charge of `q_2 = -8 mu C` and mass `1.50 g`, is projected toward `q_1`. When the two spheres are `0.800 m` apart, `q_2` is moving toward `q_1` with speed `20 ms^-1` as shown in (Fig. 3.151). Assume that the two spheres can be treated as point charges. You can ignore the force of gravity. . The speed of `q_2` when the spheres are `0.400 m` apart is.A. `2 sqrt(10) ms^-1`B. `2 sqrt(6) ms^-1`C. `4 sqrt(10) ms^-1`D. `4 sqrt(6) ms^-1`
Answer» Correct Answer - C `E_i = K_i + U_i = (1)/(2) (0.0015 kg)(20.0 ms^-1)^2+(k (2.00 xx 10^-6 C)(8.00 xx 10^-6 C))/(0.800 m)` =`0.48 J` `E_i = E_f = (1)/(2) mv_f^2 + (k q_1 q_2)/(r_f)` `v_f = sqrt((2(0.48 J - 0.3t6 J))/(0.0015 kg)) = 4 sqrt(10) ms^-1` At the closest point, the velocity is zero. `0.48 J = (kq_1 q_2)/(r)` or `r = (k(2.00 xx 10^-6 C)(8.00 xx 10^-6 C))/(0.48 J) =0.30 m`.

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