Electrostatic Potential And Capacitance MCQs With Answers – Part 2 (Class 12 Physics)
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Electrostatic Potential and Capacitance MCQs with Answers – Part 2 (Class 12 Physics)

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101. A row in the table gives the correct connection between field situation and equipotential surface.
RowField or source situationEquipotential surface
PSingle point chargeConcentric spheres centred at the charge
QUniform electric fieldSpheres centred at every point of the field
RSingle point chargePlanes parallel to the radial field everywhere
SUniform electric fieldClosed spheres around the negative side only
ⓐ. Row Q
ⓑ. Row R
ⓒ. Row P
ⓓ. Row S
102. A positive charge is moved from point \(P\) to point \(Q\), both lying on the same equipotential surface. The electric field may be non-zero along the region, yet the electrostatic work is zero because:
ⓐ. The endpoints have no potential difference
ⓑ. Work is always zero for every motion of a positive charge
ⓒ. Electric field cannot exist near an equipotential surface
ⓓ. The charge becomes neutral during the motion
103. Read the graph description below.
A two-dimensional drawing shows several curves representing equal potential values around a point charge. Curves farther from the charge are labelled with smaller magnitudes of \(V\), taking \(V=0\) at infinity.
What does each curve in this drawing represent?
ⓐ. A line on which force is zero at every point
ⓑ. An equipotential line in a plane drawing
ⓒ. A path along which potential changes most rapidly
ⓓ. A field line showing the direction of \(\vec{E}\)
104. Two points lie on the same equipotential surface of potential \(40\,\text{V}\). A charge \(-3\,\text{C}\) is moved slowly from one point to the other. The change in potential energy is:
ⓐ. \(+120\,\text{J}\)
ⓑ. \(0\,\text{J}\)
ⓒ. \(-120\,\text{J}\)
ⓓ. \(-40\,\text{J}\)
105. Assertion: No work is done by the electrostatic field when a charge moves along an equipotential surface. Reason: Along an equipotential surface, the potential difference between any two points is zero.
ⓐ. Both Assertion and Reason are true, and Reason explains Assertion
ⓑ. Assertion is true, but Reason is false
ⓒ. Assertion is false, but Reason is true
ⓓ. Both Assertion and Reason are true, but Reason does not explain Assertion
106. Equipotential surfaces of different potential values cannot intersect because:
ⓐ. Electric field must be zero wherever two surfaces meet
ⓑ. Potential becomes a vector at the crossing point
ⓒ. Work is always positive at an intersection
ⓓ. One point cannot have two potential values
107. The best comparison between an electric field line and an equipotential line in a two-dimensional drawing is:
ⓐ. Both always show the same curve with the same meaning
ⓑ. A field line shows direction of \(\vec{E}\), while an equipotential line joins points of equal \(V\)
ⓒ. Both can intersect freely because they are only drawings
ⓓ. A field line joins equal potential points, while an equipotential line shows force direction
108. A region contains three marked surfaces \(S_1\), \(S_2\), and \(S_3\). A charge moved along \(S_1\) needs no electrostatic work, along \(S_2\) also needs no electrostatic work, and along \(S_3\) also needs no electrostatic work. The most reasonable classification is:
ⓐ. All three are equipotential surfaces
ⓑ. All three must have the same shape and same potential value
ⓒ. All three must be electric field lines
ⓓ. All three must be surfaces where electric field is zero
109. At any point on an equipotential surface, the electric field is directed:
ⓐ. Randomly because potential is scalar
ⓑ. Along the surface
ⓒ. Opposite to the surface only for negative charges
ⓓ. Perpendicular to the surface
110. A small positive test charge is placed between two nearby equipotential surfaces marked \(80\,\text{V}\) and \(60\,\text{V}\). The electric field direction is:
ⓐ. Along the \(80\,\text{V}\) surface
ⓑ. From the \(80\,\text{V}\) surface toward the \(60\,\text{V}\) surface
ⓒ. From the \(60\,\text{V}\) surface toward the \(80\,\text{V}\) surface
ⓓ. Along the \(60\,\text{V}\) surface
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