MCQ Questions for Class 12 Medical Physics Electrostatic Potential And Capacitance Quiz 2

Two charges $$+q$$ and $$-q$$ are kept apart. Then at any point on the right bisector of line joining the two charges

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The electric field strength is zero
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The electric potential is zero
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Both electric potential and electric field strength are zero
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Both electric potential and electric field strength are non-zero

The intensity of electric field E due to charge Q at distance r.

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$$E\propto r$$
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$$E\propto \displaystyle\frac{1}{r^2}$$
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$$E\propto \displaystyle\frac{1}{r}$$
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$$E\propto \displaystyle\frac{1}{r^3}$$

Identify the dimension of electric potential,

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$$L^{2}MT^{-3}I^{-1}$$
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$$L^{1}MT^{-2}I^{-1}$$
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$$L^{-2}MT^{-2}I^{-1}$$
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none of the above

Two charges are separated by a distance d. If the distance between them is doubled, how does the electric potential between them change?

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It is doubled
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It is halved
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It is quartered
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It is quadrupled
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It is unchanged

Capacitance is best described as the:

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Rate of flow of charge
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Energy per unit charge
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Change in electric potential per unit length
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Charge per unit of electric potential difference
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Electric potential difference per unit of electric current

The diagram shows equipotential lines from an unknown charge configuration. Determine where in the diagram, the electric field is the strongest :

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A
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B
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C
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D

When moving electron comes closer to other stationary electron, then its kinetic energy and potential energy respectively _____ and _____.

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Increases, increases
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Increases, decreases
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Decreases, increases
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Decreases, decreases

The dielectric constant of air is.

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$$8.85\times 10^{-12}C^2N^{-1}M^{-2}$$
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$$1$$
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Infinite
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Zero

A method for charging a conductor without bringing a charged body in contact with it is called:

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Magnetization
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Electrification
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Electrostatic induction
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Electromagnetic induction

The retarding potential is generally greater in magnitude than the acceleration potential.

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True
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False

What is not true of equipotential surface?

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The PD between any two points on the surface is zero
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The electric field is always perpendicular to the surface
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Equipotential surfaces are always spherical
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No work is done in moving a charge along the surface

A parallel plate capacitor is charged. If the plates are pulled apart

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The capacitance increases
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The potential difference increases
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The total charge increases
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The charge and potential difference remain the same

What is the unit of electric potential difference?

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Volt
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Coulamb
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Joul
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Watt

The equivalent capacitance between the points A and B in the given diagram is:

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$$

8\mu F

$$
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$$

6\mu F

$$
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$$\dfrac{8}{3}\mu F$$
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$$\dfrac{3}{8}\mu F$$

If the susceptibility of dia, para and ferro magnetic materials are $$Xd. Xp. Xf$$ respectively, then

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$$Xd < Xp < Xf$$
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$$Xf < Xp< Xd$$
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$$Xf < Xd < Xp$$
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$$Xd < Xf < Xp$$

The potential of a sphere of radius $$2\ cm$$ when a charge of $$2\ coulomb$$ is given to it, will be

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$$9\times 10^{3}V$$
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$$9\times 10^{11}V$$
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$$9\times 10^{6}V$$
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$$9\times 10^{16}V$$

Calculate the electrostatic potential energy of two electrons separated bt 3 $$\overset { \circ }{ A } $$ in vacuum

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$$4.81eV$$
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$$5.81eV$$
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$$6.71eV$$
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$$7.82eV$$

Out of the given statements which of the following are true :

A) Work done in moving a charge on equipotential surface is zero.

B) Electric lines of force are always normal to equipotential surface.

C) When two like charges are brought closer, the electrostatic potential energy of the system is decreased.

D) Electric lines of force converge at positive charge and diverge at negative charge.

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A, B, C, D are true
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A, B, C are true
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A, B are true
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A only true

When a dielectric material is introduced between the plates of a charged condenser, after disconnecting the battery, the electric field between the plates:

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decreases
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increases
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does not change
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may increase or decrease

A condenser is charged and then battery is removed. A dielectric plate is put between the plates of condenser, then correct statement is

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Q is constant, V and U decrease
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Q is constant, V increases U decreases
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Q increases, V decreases U increases
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Q, V and U increase

Explanation

Two charges $$q$$ and $$-q$$ are kept apart. Then at any point on the perpendicular bisector of line joining the two charges:

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the electric field strength is zero
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the electric potential is zero
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both electric potential and electric field strength are zero
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both electric potential and electric field strength are non-zero

Statement(A): Negative charges always move from a higher potential to lower potential point

Statement (B): Electric potential is vector.

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A is true but B is false
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B is true but A is false
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Both A and B false
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Both A and R are true

A parallel plate condenser is charged by connecting it to a battery. Without disconnecting the battery, the space between the plates is completely filled with a medium of dielectric constant k. Then:

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potential becomes 1/k times
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charge becomes k times
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energy becomes 1/k times
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electric intensity becomes k times

A parallel plate capacitor, filled with a material of dielectric constant $$K$$, is charged to a certain voltage and is isolated. The dielectric material is removed. Then:
(a) capacitance decreases by a factor $$K$$
(b) electric field reduces by a factor $$K$$
(c) voltage across the capacitor increases by a factor $$K$$
(d) charge stored in the capacitor increases by a factor $$K$$

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(a) and (b) are true
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(a) and (c) are true
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(b) and (c) are true
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(b) and (d) are true

Twenty seven identical mercury drops each charged to $$10V$$, are allowed to form a big drop. The potential of the big drop is

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$$90 V$$
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$$9 V$$
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$$900 V$$
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$$270 V$$

(1): The dielectric medium between the plates of a parallel plate capacitor lowers the potential difference between the plates without a battery.

(2): The maximum electric field that a dielectric can withstand without causing it to break down is dielectric strength.

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Both 1 and 2 are true, 2 is not correct explanation of 1
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Both 1 and 2 are true, 2 is correct explanation of 1.
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1 is false, 2 is true
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1 is true, 2 is false

One plate of parallel plate capacitor is smaller than the other. The charge on the smaller plate:

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will be less than other
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will be more than other
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will be equal to other
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will depend upon the medium between the plates

A dielectric of thickness $$5$$ cm and a dielectric constant $$10$$ is introduced between the plates of a parallel plate capacitor having plate area $$500 sq.$$ cm and separation between the plates $$10cm$$. The capacitance of the capacitor with the dielectric slab is $$\varepsilon _{0}=8.8\times 10^{-12}C^{2}/N-m^{2}$$

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$$4.4 pF$$
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$$6.2 pF$$
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$$8 pF$$
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$$10 pF$$

A highly conducting sheet of aluminium foil of negligible thickness is placed between the plates of a parallel plate capacitor. The foil is parallel to the plates at distance $$\dfrac{d}{2}$$ from positive plate where $$d$$ is distance between plates. If the capacitance before the insertion of foil was $$10 \; \mu F$$ , its value after the insertion of foil will be:

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$$20\; \mu F$$
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$$10 \;\mu F$$
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$$5 \;\mu F$$
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Zero

Charges $$+q$$, $$-4q$$ and $$+2q$$ are arranged at the corners of an equilateral triangle of side $$0.15\ m$$. If $$q=1\ \mu C $$, their mutual potential energy is roughly:

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$$0.4\ J$$
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$$0.5\ J$$
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$$0.6\ J$$
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$$0. 8\ J$$

Calculate the electrostatic potential energy of an electron-proton system of hydrogen atom. In the first Bohr orbit of hydrogen atom, the radius of the orbit is $$5.3\times 10^{-11}m\ $$:

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$$-4.35\times 10^{-18}J$$
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$$-2.175\times 10^{-18}J$$
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$$-4.35\times 10^{-19}J$$
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$$-2.175\times 10^{-19}J$$

An oil condenser has a capacity of $$100\; \mu F$$ . The oil has dielectric constantWhen the oil leaks out , its new capacity is :

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$$200\; \mu F$$
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$$0.02\; \mu F$$
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$$50 \;\mu F$$
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$$0.5 \;\mu F$$

A charge of $$2\ C$$ is moved from a point $$2\ m$$ away from a charge of $$1\ C$$ to a point $$1\ m$$ away from that charge. The work done is:

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$$10^{9}\ J$$
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$$10^{6}\ J$$
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$$9\times 10^{9}\ J$$
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$$10^{10}\ J$$

A positive point charge q is carried from a point B to a point A in the electric field of a point charge +Q. If the permittivity of free space is $$\epsilon _{0}$$ , the work done in the process is given by

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$$\displaystyle \frac{qQ}{4\pi \epsilon _{0}}\left [ \frac{1}{a}-\frac{1}{b} \right ]$$
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$$\displaystyle \frac{qQ}{4\pi \epsilon _{0}}\left [ \frac{1}{a}+\frac{1}{b} \right ]$$
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$$\displaystyle \frac{qQ}{4\pi \epsilon _{0}}\left [ \frac{1}{a^{2}}-\frac{1}{b^{2}} \right ]$$
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$$\displaystyle \frac{qQ}{4\pi \epsilon _{0}}\left [ \frac{1}{a^{2}}+\frac{1}{b^{2}} \right ]$$

A parallel plate capacitor with air between the plates is charged to a potential difference of $$500 V$$ and then insulated. A plastic plate is inserted between the plates filling the whole gap. The potential difference between the plates now becomes $$75V$$. The dielectric constant of plastic is :

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$$10/3$$
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$$5$$
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$$20/3$$
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$$10$$

A, B, C are three points on a circle of radius $$1 cm$$. These points form the corners of an equilateral triangle. A charge $$2C$$ is placed at the centre of the circle. The work done in carrying a charge of $$0.1\mu C$$ from A to B is :

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$$Zero$$
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$$18\times 10^{11}J$$
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$$1.8\times 10^{11}J$$
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$$54\times 10^{11}J$$

The capacity of a parallel plate condenser is $$10 \;\mu F$$ without the dielectric. Material with a dielectric constant of $$2$$ is used to fill half-thickness between the plates. The new capacitance is $$\underline{\hspace{0.5in}} \;\mu F$$ :

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$$10$$
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$$20$$
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$$15$$
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$$13.33$$

The plates of a parallel plate capacitor are charged up to $$200$$ volts. A dielectric slab of thickness 4mm is inserted between the plates. Then, to maintain the same potential difference between the plates of the capacitor, the distance between the plates is increased by $$3.2mm$$. The dielectric constant of a dielectric slab is :

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$$1$$
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$$4$$
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$$5$$
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$$6$$

The capacitance of a capacitor becomes $$\dfrac{7}{6}$$ times its original value if a dielectric slab of thickness, $$t=\dfrac{2}{3}d$$ is introduced in between the plates. d is the separation between the plates. The dielectric constant of the dielectric slab is :

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$$\dfrac{14}{11}$$
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$$\dfrac{11}{14}$$
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$$\dfrac{7}{11}$$
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$$\dfrac{11}{7}$$

The potential difference across $$3 \mu F$$ condenser is :

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$$40 Volt$$
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$$60 Volt$$
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$$80 Volt$$
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$$120 Volt$$

The equivalent capacitance of three capacitors of capacitance $$C_{1}, C_{2}$$ and $$C_{3}$$ connected in parallel is 12 units and the product $$C_{1}C_{2}C_{3}=48$$. When the capacitors $$C_{1}$$ and $$C_{2}$$ are connected in parallel the equivalent capacitance is 6 units. Then the capacitance are :

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$$1.5, \ 2.5, \ 8$$
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$$2,\ 3, \ 7$$
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$$4, \ 2, \ 6$$
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$$1, \ 5, \ 6$$

Two condensers of capacitance $$4\mu F$$ and $$5\mu F$$ are joined in series. If the potential difference across $$5\mu F$$ is $$10V$$, then the potential difference across $$4\mu F$$ condenser is :

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$$22.5V$$
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$$10V$$
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$$12.5V$$
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$$25V$$

In the capacitor of capacitance $$20\ \mu F$$, the distance between plates is $$2\ mm$$. If a material of dielectric constant $$ 2$$ is inserted between the plates, then the capacitance of the system is :

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$$20 \mu F$$
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$$30 \mu F$$
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$$22 \times 5 \mu F$$
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$$40 \mu F$$

A charge $$3$$ coulomb experiences a force $$3000\ N$$ when placed in a uniform electric field. The potential difference between two points seperated by a distance of $$1\ cm$$ along the field lines is :

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$$10\ V$$
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$$90\ V$$
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$$1000\ V$$
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$$9000\ V$$

Two metal plates are separated by a distance $$d$$ in a parallel plate condenser. A metal plate of thickness $$t$$ and of the same area is inserted between the condenser plates. The value of capacitance increases by a factor of :

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$$\dfrac{d-t}{d}$$
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$$\left ( 2-\dfrac{t}{d} \right )$$
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$$\left ( t-\dfrac{t}{d} \right )$$
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$$\dfrac{1}{\left ( 1-\dfrac{t}{d} \right )}$$

Three capacitors $$2\mu F, 3\mu F$$ and $$5\mu F$$ are connected in parallel. The capacitance of the combination:

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$$\dfrac{30}{31}\mu F$$
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$$\dfrac{31}{30}\mu F$$
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$$ 10 \mu F$$
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$$2.5 \mu F$$

The equivalent capacity between the points X and Y in the circuit with $$C=1\ \mu F$$ is:

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$$2\ \mu F$$
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$$3\ \mu F$$
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$$1\ \mu F$$
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$$0.5\ \mu F$$

A capacitor of $$10 \mu F$$ capacitance is charged by a $$12 V$$ battery. Now the space between the plates of capacitors is filled with a dielectric of dielectric constant $$K = 3$$ and again it is charged. The magnitude of the charge is :

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$$120 \mu C$$
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$$240 \mu C$$
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$$360 \mu C$$
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$$480 \mu C$$

Three capacitors $$2\mu F, 3\mu F$$ and $$6\mu F$$ are connected in series. The effective capacitance of the combination is:

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$$11\ \mu F$$
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$$1\ \mu F$$
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$$1.2\ \mu F$$
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$$2\ \mu F$$

A neutral hydrogen molecule has two protons and two electrons. If one of the electrons is removed we get a hydrogen molecular ion $$\left ( H_{2}^{+} \right )$$ . In the ground state of $$ H_{2}^{+} $$ the two protons are separated by roughly $$1.5$$$$\ A^o$$ and the electrons is roughly $$1$$ $$A^o$$ from each proton. The potential energy of the system is :

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$$-38.4\ eV$$
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$$-19.2\ eV$$
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$$-9.6\ eV$$
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$$zero$$

CBSE Questions for Class 12 Medical Physics Electrostatic Potential And Capacitance Quiz 2 - MCQExams.com

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Practice Class 12 Medical Physics Quiz Questions and Answers

CBSE Questions for Class 12 Medical Physics Electrostatic Potential And Capacitance Quiz 2 - MCQExams.com

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Practice Class 12 Medical Physics Quiz Questions and Answers

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