Question

A conducting sphere of radius 1.5 m has a total charge $Q = 50 \text{ nC}$. a. Determine the potential at point P, 1 m from the center of the sphere. a. 127 V b. 0 V c. 450 V d. 210 V e. 300 V b. Consider the potential on the surface of the sphere to be $V_o$. If equipotential surfaces are drawn outside the sphere at 50 V intervals, determine the radius of the second equipotential surface $V_2$. (The radius is measured from the center of the conducting sphere). a. 2.25 m b. $\infty$ c. 1.5 m d. 1.7 m e. 3.15 m

          A conducting sphere of radius 1.5 m has a total charge $Q = 50 \text{ nC}$.
a. Determine the potential at point P, 1 m from the center of the sphere.
a. 127 V
b. 0 V
c. 450 V
d. 210 V
e. 300 V
b. Consider the potential on the surface of the sphere to be $V_o$. If equipotential surfaces are drawn outside the sphere at 50 V intervals, determine the radius of the second equipotential surface $V_2$. (The radius is measured from the center of the conducting sphere).
a. 2.25 m
b. $\infty$
c. 1.5 m
d. 1.7 m
e. 3.15 m

A conducting sphere of radius 1.5 m has a total charge Q = 50 nC.
a. Determine the potential at point P, 1 m from the center of the sphere.
a. 127 V
b. 0 V
c. 450 V
d. 210 V
e. 300 V
b. Consider the potential on the surface of the sphere to be Vo. If equipotential surfaces are drawn outside the sphere at 50 V intervals, determine the radius of the second equipotential surface V2. (The radius is measured from the center of the conducting sphere).
a. 2.25 m
b. ∞
c. 1.5 m
d. 1.7 m
e. 3.15 m

Added by Joel J.

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