Two metal bars are fixed vertically and are connected on the top by a capacitor `C`. A sliding conductor of length land mass m slides with its ends in contact with the bars. The arrangement is placed in a uniform horizontal magnetic field directed normal to the plane of the figure. The conductor is released from rest. Find the displacement `x(t)` of the conductor as a function of time t.

Two metal bars are fixed vertically and are connected on the top by a

1.	Two metal bars are fixed vertically and are connected on the top by a capacitor `C`. A sliding conductor of length land mass m slides with its ends in contact with the bars. The arrangement is placed in a uniform horizontal magnetic field directed normal to the plane of the figure. The conductor is released from rest. Find the displacement `x(t)` of the conductor as a function of time t.
Answer» Correct Answer - B::C Let `v` be the velocity at some instant. Then motional emf `V=Bvl` Charge stored in capacitor `q=CV=(CBl)v` Current in the wire `=(dq)/(dt)=(CBl)(dv)/(dt)` Magnetic force `F_m=ilB=(CB^2l^2)(dv)/(dt)`(upwards) `:.` Net force `F_("net") = mg - F_(m)` or `m=(dv)/(dt) = mg -(CB^(2)l^(2)) (dv)/(dt)` `:. (dv)/(dt) =`acceleration, `a=(mg)/(m+CB^2l^2)` Since, `a =`constant `:. x=1/2at^2=(mg t^2)/(2(m+CB^2l^2))`

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