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PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359186 A combination of parallel plate capacitors is maintained at a certain potential difference. When a 3 $m m$ thick slab is introduced between all the plates, in order to maintain the same potential difference, the distance between plates in increased by 2.4 $m m$ . Find the dielectric constant of the slab.
supporting img

1 6

2 4

3 3

4 5

Explanation:

$C_{1} = \frac{ε_{0} A}{3}$ before
After inserting the slab the capacitances are
$\frac{K ε_{0} A}{3} & \frac{ε_{0} A}{2.4}$
As capacitance remains same
$\frac{ε_{0} A}{3} = \frac{\frac{k ε_{0} A}{3} . \frac{ε_{0} A}{2.4}}{\frac{k ε_{0} A}{3} + \frac{ε_{0} A}{2.4}} \Rightarrow k = \frac{3}{0.6} = 5$

JEE - 2017

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359187 In a parallel plate air capacitor the distance between plates is reduced to one fourth and the space between them is filled with a dielectric medium of constant 2. If the initial capacity of the capacitor is $4 μ F$ , then its new capacity is

1

32 μ F

2

18 μ F

3

8 μ F

4

44 μ F

Explanation:

The capacitance of a parallel plate air capacitor is given by
$C_{0} = \frac{ε_{0} A}{d} (1)$
Where, $ε_{0} =$ vacum permitivity $\approx$ permitivity of air
A = area of plates and d = distance between the plates
When the distance between plates is reduced and a dielectric slab is introduced, then the capacitance becomes $C = \frac{K ε_{0} A}{d_{1}} (2)$
Where, $K =$ dielectric constant of medium
$Here, K = 2, d_{1} = \frac{d}{4} and C_{0} = 4 μ F$
From eq.(2), we get
$C = (\frac{K ε_{0} A}{d / 4}) = 4 K (\frac{ε_{0} A}{d})$
$= 4 K C_{0} (3)$
[ from eq.(1)]
Substituting the given values in eq.(3), we get
$C = 4 \times 2 \times 4 = 32 μ F$

MHTCET - 2019

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359188 A parallel plate capacitor of area $A$ , plate separation $d$ and capacitance $C$ is filled with three different dielectric material having dielectric constants $K_{1}, K_{2}$ and $K_{3}$ as shown. If a single dielectric material is to be used to have the same capacitance $C$ in this capacitor, then its dielectric constant $k$ is given by
supporting img

1

K = K_{1} + K_{2} + 2 K_{3}

2

K = \frac{K_{1} K_{2}}{K_{1} + K_{2}} + 2 K_{3}

3

K = \frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}

4

\frac{1}{K} = \frac{1}{K_{1}} + \frac{1}{K_{2}} + \frac{1}{2 K_{3}}

Explanation:

The given system should be assumed as a combination of four capacitors.
supporting img
$C_{1} = \frac{K_{1} ε_{o} \frac{A}{2}}{\frac{d}{2}}, C_{2} = \frac{K_{2} ε_{o} \frac{A}{2}}{\frac{d}{2}} & C_{3} = \frac{K_{3} ε_{o} \frac{A}{2}}{\frac{d}{2}}$
$C_{e q} = \frac{C_{1} C_{3}}{C_{1} + C_{3}} + \frac{C_{2} C_{3}}{C_{2} + C_{3}}$
$= (\frac{K_{1} K_{3}}{K_{1} + K_{3}}) \frac{ε_{o} A}{d} + (\frac{K_{2} K_{3}}{K_{2} + K_{3}}) \frac{ε_{o} A}{d}$
$C_{e q} = \frac{ε_{o} A}{d} [\frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}] = \frac{K ε_{o} A}{d}$
$\Rightarrow K = \frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}$

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359189 If a capacitor $C_{0}$ has plate area $A$ and distance between plates is $‘ d^{'}$ . Now a dielectric of dielectric constant $‘ k^{'}$ is placed between capacitor as shown in figure. Find new capacitance :
supporting img

1

\frac{4 k C_{0}}{(k + 3)}

2

\frac{3 k C_{0}}{(k + 4)}

3

\frac{(k + 3) C_{0}}{4 k}

4

\frac{3 k C_{0}}{(k + 4)}

Explanation:

$C_{0} = \frac{\in_{0} A}{d}$
$C_{e q} = \frac{C_{1} C_{2}}{C_{1} + C_{2}} = \frac{\frac{k \in_{0} A}{3 \frac{d}{4}} \times \frac{\in_{0} A}{\frac{d}{4}}}{\frac{k \in_{0} A}{3 \frac{d}{4}} + \frac{\in_{0} A}{\frac{d}{4}}} = \frac{\frac{k \in_{0} A \times 16}{3 d}}{(\frac{k}{3} + 1) \times 4}$
$= \frac{4 k \in_{0} A}{d (k + 3)} = \frac{4 k C_{0}}{(k + 3)}$

JEE - 2021

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359186 A combination of parallel plate capacitors is maintained at a certain potential difference. When a 3 $m m$ thick slab is introduced between all the plates, in order to maintain the same potential difference, the distance between plates in increased by 2.4 $m m$ . Find the dielectric constant of the slab.
supporting img

1 6

2 4

3 3

4 5

Explanation:

$C_{1} = \frac{ε_{0} A}{3}$ before
After inserting the slab the capacitances are
$\frac{K ε_{0} A}{3} & \frac{ε_{0} A}{2.4}$
As capacitance remains same
$\frac{ε_{0} A}{3} = \frac{\frac{k ε_{0} A}{3} . \frac{ε_{0} A}{2.4}}{\frac{k ε_{0} A}{3} + \frac{ε_{0} A}{2.4}} \Rightarrow k = \frac{3}{0.6} = 5$

JEE - 2017

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359187 In a parallel plate air capacitor the distance between plates is reduced to one fourth and the space between them is filled with a dielectric medium of constant 2. If the initial capacity of the capacitor is $4 μ F$ , then its new capacity is

1

32 μ F

2

18 μ F

3

8 μ F

4

44 μ F

Explanation:

The capacitance of a parallel plate air capacitor is given by
$C_{0} = \frac{ε_{0} A}{d} (1)$
Where, $ε_{0} =$ vacum permitivity $\approx$ permitivity of air
A = area of plates and d = distance between the plates
When the distance between plates is reduced and a dielectric slab is introduced, then the capacitance becomes $C = \frac{K ε_{0} A}{d_{1}} (2)$
Where, $K =$ dielectric constant of medium
$Here, K = 2, d_{1} = \frac{d}{4} and C_{0} = 4 μ F$
From eq.(2), we get
$C = (\frac{K ε_{0} A}{d / 4}) = 4 K (\frac{ε_{0} A}{d})$
$= 4 K C_{0} (3)$
[ from eq.(1)]
Substituting the given values in eq.(3), we get
$C = 4 \times 2 \times 4 = 32 μ F$

MHTCET - 2019

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359188 A parallel plate capacitor of area $A$ , plate separation $d$ and capacitance $C$ is filled with three different dielectric material having dielectric constants $K_{1}, K_{2}$ and $K_{3}$ as shown. If a single dielectric material is to be used to have the same capacitance $C$ in this capacitor, then its dielectric constant $k$ is given by
supporting img

1

K = K_{1} + K_{2} + 2 K_{3}

2

K = \frac{K_{1} K_{2}}{K_{1} + K_{2}} + 2 K_{3}

3

K = \frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}

4

\frac{1}{K} = \frac{1}{K_{1}} + \frac{1}{K_{2}} + \frac{1}{2 K_{3}}

Explanation:

The given system should be assumed as a combination of four capacitors.
supporting img
$C_{1} = \frac{K_{1} ε_{o} \frac{A}{2}}{\frac{d}{2}}, C_{2} = \frac{K_{2} ε_{o} \frac{A}{2}}{\frac{d}{2}} & C_{3} = \frac{K_{3} ε_{o} \frac{A}{2}}{\frac{d}{2}}$
$C_{e q} = \frac{C_{1} C_{3}}{C_{1} + C_{3}} + \frac{C_{2} C_{3}}{C_{2} + C_{3}}$
$= (\frac{K_{1} K_{3}}{K_{1} + K_{3}}) \frac{ε_{o} A}{d} + (\frac{K_{2} K_{3}}{K_{2} + K_{3}}) \frac{ε_{o} A}{d}$
$C_{e q} = \frac{ε_{o} A}{d} [\frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}] = \frac{K ε_{o} A}{d}$
$\Rightarrow K = \frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}$

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359189 If a capacitor $C_{0}$ has plate area $A$ and distance between plates is $‘ d^{'}$ . Now a dielectric of dielectric constant $‘ k^{'}$ is placed between capacitor as shown in figure. Find new capacitance :
supporting img

1

\frac{4 k C_{0}}{(k + 3)}

2

\frac{3 k C_{0}}{(k + 4)}

3

\frac{(k + 3) C_{0}}{4 k}

4

\frac{3 k C_{0}}{(k + 4)}

Explanation:

$C_{0} = \frac{\in_{0} A}{d}$
$C_{e q} = \frac{C_{1} C_{2}}{C_{1} + C_{2}} = \frac{\frac{k \in_{0} A}{3 \frac{d}{4}} \times \frac{\in_{0} A}{\frac{d}{4}}}{\frac{k \in_{0} A}{3 \frac{d}{4}} + \frac{\in_{0} A}{\frac{d}{4}}} = \frac{\frac{k \in_{0} A \times 16}{3 d}}{(\frac{k}{3} + 1) \times 4}$
$= \frac{4 k \in_{0} A}{d (k + 3)} = \frac{4 k C_{0}}{(k + 3)}$

JEE - 2021

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359186 A combination of parallel plate capacitors is maintained at a certain potential difference. When a 3 $m m$ thick slab is introduced between all the plates, in order to maintain the same potential difference, the distance between plates in increased by 2.4 $m m$ . Find the dielectric constant of the slab.
supporting img

1 6

2 4

3 3

4 5

Explanation:

$C_{1} = \frac{ε_{0} A}{3}$ before
After inserting the slab the capacitances are
$\frac{K ε_{0} A}{3} & \frac{ε_{0} A}{2.4}$
As capacitance remains same
$\frac{ε_{0} A}{3} = \frac{\frac{k ε_{0} A}{3} . \frac{ε_{0} A}{2.4}}{\frac{k ε_{0} A}{3} + \frac{ε_{0} A}{2.4}} \Rightarrow k = \frac{3}{0.6} = 5$

JEE - 2017

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359187 In a parallel plate air capacitor the distance between plates is reduced to one fourth and the space between them is filled with a dielectric medium of constant 2. If the initial capacity of the capacitor is $4 μ F$ , then its new capacity is

1

32 μ F

2

18 μ F

3

8 μ F

4

44 μ F

Explanation:

The capacitance of a parallel plate air capacitor is given by
$C_{0} = \frac{ε_{0} A}{d} (1)$
Where, $ε_{0} =$ vacum permitivity $\approx$ permitivity of air
A = area of plates and d = distance between the plates
When the distance between plates is reduced and a dielectric slab is introduced, then the capacitance becomes $C = \frac{K ε_{0} A}{d_{1}} (2)$
Where, $K =$ dielectric constant of medium
$Here, K = 2, d_{1} = \frac{d}{4} and C_{0} = 4 μ F$
From eq.(2), we get
$C = (\frac{K ε_{0} A}{d / 4}) = 4 K (\frac{ε_{0} A}{d})$
$= 4 K C_{0} (3)$
[ from eq.(1)]
Substituting the given values in eq.(3), we get
$C = 4 \times 2 \times 4 = 32 μ F$

MHTCET - 2019

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359188 A parallel plate capacitor of area $A$ , plate separation $d$ and capacitance $C$ is filled with three different dielectric material having dielectric constants $K_{1}, K_{2}$ and $K_{3}$ as shown. If a single dielectric material is to be used to have the same capacitance $C$ in this capacitor, then its dielectric constant $k$ is given by
supporting img

1

K = K_{1} + K_{2} + 2 K_{3}

2

K = \frac{K_{1} K_{2}}{K_{1} + K_{2}} + 2 K_{3}

3

K = \frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}

4

\frac{1}{K} = \frac{1}{K_{1}} + \frac{1}{K_{2}} + \frac{1}{2 K_{3}}

Explanation:

The given system should be assumed as a combination of four capacitors.
supporting img
$C_{1} = \frac{K_{1} ε_{o} \frac{A}{2}}{\frac{d}{2}}, C_{2} = \frac{K_{2} ε_{o} \frac{A}{2}}{\frac{d}{2}} & C_{3} = \frac{K_{3} ε_{o} \frac{A}{2}}{\frac{d}{2}}$
$C_{e q} = \frac{C_{1} C_{3}}{C_{1} + C_{3}} + \frac{C_{2} C_{3}}{C_{2} + C_{3}}$
$= (\frac{K_{1} K_{3}}{K_{1} + K_{3}}) \frac{ε_{o} A}{d} + (\frac{K_{2} K_{3}}{K_{2} + K_{3}}) \frac{ε_{o} A}{d}$
$C_{e q} = \frac{ε_{o} A}{d} [\frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}] = \frac{K ε_{o} A}{d}$
$\Rightarrow K = \frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}$

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359189 If a capacitor $C_{0}$ has plate area $A$ and distance between plates is $‘ d^{'}$ . Now a dielectric of dielectric constant $‘ k^{'}$ is placed between capacitor as shown in figure. Find new capacitance :
supporting img

1

\frac{4 k C_{0}}{(k + 3)}

2

\frac{3 k C_{0}}{(k + 4)}

3

\frac{(k + 3) C_{0}}{4 k}

4

\frac{3 k C_{0}}{(k + 4)}

Explanation:

$C_{0} = \frac{\in_{0} A}{d}$
$C_{e q} = \frac{C_{1} C_{2}}{C_{1} + C_{2}} = \frac{\frac{k \in_{0} A}{3 \frac{d}{4}} \times \frac{\in_{0} A}{\frac{d}{4}}}{\frac{k \in_{0} A}{3 \frac{d}{4}} + \frac{\in_{0} A}{\frac{d}{4}}} = \frac{\frac{k \in_{0} A \times 16}{3 d}}{(\frac{k}{3} + 1) \times 4}$
$= \frac{4 k \in_{0} A}{d (k + 3)} = \frac{4 k C_{0}}{(k + 3)}$

JEE - 2021

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359186 A combination of parallel plate capacitors is maintained at a certain potential difference. When a 3 $m m$ thick slab is introduced between all the plates, in order to maintain the same potential difference, the distance between plates in increased by 2.4 $m m$ . Find the dielectric constant of the slab.
supporting img

1 6

2 4

3 3

4 5

Explanation:

$C_{1} = \frac{ε_{0} A}{3}$ before
After inserting the slab the capacitances are
$\frac{K ε_{0} A}{3} & \frac{ε_{0} A}{2.4}$
As capacitance remains same
$\frac{ε_{0} A}{3} = \frac{\frac{k ε_{0} A}{3} . \frac{ε_{0} A}{2.4}}{\frac{k ε_{0} A}{3} + \frac{ε_{0} A}{2.4}} \Rightarrow k = \frac{3}{0.6} = 5$

JEE - 2017

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359187 In a parallel plate air capacitor the distance between plates is reduced to one fourth and the space between them is filled with a dielectric medium of constant 2. If the initial capacity of the capacitor is $4 μ F$ , then its new capacity is

1

32 μ F

2

18 μ F

3

8 μ F

4

44 μ F

Explanation:

The capacitance of a parallel plate air capacitor is given by
$C_{0} = \frac{ε_{0} A}{d} (1)$
Where, $ε_{0} =$ vacum permitivity $\approx$ permitivity of air
A = area of plates and d = distance between the plates
When the distance between plates is reduced and a dielectric slab is introduced, then the capacitance becomes $C = \frac{K ε_{0} A}{d_{1}} (2)$
Where, $K =$ dielectric constant of medium
$Here, K = 2, d_{1} = \frac{d}{4} and C_{0} = 4 μ F$
From eq.(2), we get
$C = (\frac{K ε_{0} A}{d / 4}) = 4 K (\frac{ε_{0} A}{d})$
$= 4 K C_{0} (3)$
[ from eq.(1)]
Substituting the given values in eq.(3), we get
$C = 4 \times 2 \times 4 = 32 μ F$

MHTCET - 2019

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359188 A parallel plate capacitor of area $A$ , plate separation $d$ and capacitance $C$ is filled with three different dielectric material having dielectric constants $K_{1}, K_{2}$ and $K_{3}$ as shown. If a single dielectric material is to be used to have the same capacitance $C$ in this capacitor, then its dielectric constant $k$ is given by
supporting img

1

K = K_{1} + K_{2} + 2 K_{3}

2

K = \frac{K_{1} K_{2}}{K_{1} + K_{2}} + 2 K_{3}

3

K = \frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}

4

\frac{1}{K} = \frac{1}{K_{1}} + \frac{1}{K_{2}} + \frac{1}{2 K_{3}}

Explanation:

The given system should be assumed as a combination of four capacitors.
supporting img
$C_{1} = \frac{K_{1} ε_{o} \frac{A}{2}}{\frac{d}{2}}, C_{2} = \frac{K_{2} ε_{o} \frac{A}{2}}{\frac{d}{2}} & C_{3} = \frac{K_{3} ε_{o} \frac{A}{2}}{\frac{d}{2}}$
$C_{e q} = \frac{C_{1} C_{3}}{C_{1} + C_{3}} + \frac{C_{2} C_{3}}{C_{2} + C_{3}}$
$= (\frac{K_{1} K_{3}}{K_{1} + K_{3}}) \frac{ε_{o} A}{d} + (\frac{K_{2} K_{3}}{K_{2} + K_{3}}) \frac{ε_{o} A}{d}$
$C_{e q} = \frac{ε_{o} A}{d} [\frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}] = \frac{K ε_{o} A}{d}$
$\Rightarrow K = \frac{K_{1} K_{3}}{K_{1} + K_{3}} + \frac{K_{2} K_{3}}{K_{2} + K_{3}}$

PHXII02:ELECTROSTATIC POTENTIAL AND CAPACITANCE

359189 If a capacitor $C_{0}$ has plate area $A$ and distance between plates is $‘ d^{'}$ . Now a dielectric of dielectric constant $‘ k^{'}$ is placed between capacitor as shown in figure. Find new capacitance :
supporting img

1

\frac{4 k C_{0}}{(k + 3)}

2

\frac{3 k C_{0}}{(k + 4)}

3

\frac{(k + 3) C_{0}}{4 k}

4

\frac{3 k C_{0}}{(k + 4)}

Explanation:

$C_{0} = \frac{\in_{0} A}{d}$
$C_{e q} = \frac{C_{1} C_{2}}{C_{1} + C_{2}} = \frac{\frac{k \in_{0} A}{3 \frac{d}{4}} \times \frac{\in_{0} A}{\frac{d}{4}}}{\frac{k \in_{0} A}{3 \frac{d}{4}} + \frac{\in_{0} A}{\frac{d}{4}}} = \frac{\frac{k \in_{0} A \times 16}{3 d}}{(\frac{k}{3} + 1) \times 4}$
$= \frac{4 k \in_{0} A}{d (k + 3)} = \frac{4 k C_{0}}{(k + 3)}$

JEE - 2021