Chapter 1: Electric Charges and Fields

Chapter 1: Electric Charges and Fields

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Electric flux is maximum when angle is:

0°

90°

180°

45°

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Electric field due to dipole decreases as:

1/r

1/r²

1/r³

Constant

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Field lines are:

Closed

Open

Circular

Spiral

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Electric dipole moment direction:

Negative to positive

Positive to negative

Random

Zero

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Electric field is zero at:

Infinity

Inside conductor

Both

None

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Unit of permittivity:

C²/Nm²

N/C

Volt

Joule

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Electric field due to infinite plane sheet is:

Constant

Variable

Zero

Infinite

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Maximum force when charges are:

Equal

Unequal

Zero

Infinite

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Assertion: Field lines intersect (Reason: Field is vector)

True

False

N/A

N/A

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Assertion: Charges repel (Reason: Same charges repel)

Both correct

Both wrong

Only assertion

Only reason

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Electric flux depends on:

Area

Field

Angle

All

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Electric field inside dielectric reduces by:

k

1/k

k²

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Dipole in uniform field experiences:

Force

Torque

Both

None

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Electric field due to negative charge is:

Away

Towards

Circular

Zero

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Force between two charges in vacuum is:

Minimum

Maximum

Zero

Constant

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SI unit of electric field intensity:

N/C

Volt

Joule

Ampere

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Work done moving charge perpendicular to field:

Zero

Maximum

Infinite

Negative

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Electric field lines density represents:

Charge

Field strength

Energy

Work

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If charge doubles, force becomes:

Same

Double

Half

Four times

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If distance doubles, force becomes:

Same

Half

One-fourth

Double

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Electric field is vector:

True

False

N/A

N/A

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Charge is additive:

True

False

N/A

N/A

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Electric field inside hollow sphere:

Zero

Infinite

Constant

Variable

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Field outside charged sphere behaves like:

Dipole

Point charge

Plane

Wire

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Field inside conductor is:

Zero

Maximum

Infinite

Negative

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Gauss law is useful for:

Symmetric charges

Random charges

Moving charges

None

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Gauss law relates:

Flux and charge

Force and charge

Energy and charge

Potential

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Unit of electric flux:

Nm²/C

N/C

Volt

Joule

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Electric flux is:

Number of lines passing

Charge

Energy

Work

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Torque on dipole =

pE sinθ

pE cosθ

p/E

E/p

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Unit of dipole moment:

Cm

Nm

Volt

Ampere

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Dipole moment is:

q × d

q/d

d/q

q²d

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Dipole consists of:

Two equal charges

Two opposite equal charges

Three charges

One charge

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Field lines originate from:

Negative charge

Positive charge

Both

None

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Electric field lines never:

Start

End

Intersect

Curve

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Direction of electric field is:

Opposite to force on positive charge

Same as force on positive charge

Random

None

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Unit of electric field:

N/C

C/N

Volt

Joule

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Electric field is defined as:

Force per charge

Charge per force

Energy per charge

Work done

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Superposition applies to:

One charge

Two charges

Many charges

None

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Net force is:

Product of forces

Sum of forces

Difference

Average

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SI unit of permittivity is:

C²/Nm²

Nm²/C²

N/C

Volt

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Force between charges varies as:

r

r²

1/r²

1/r

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Force between like charges is:

Attractive

Repulsive

Zero

Infinite

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Coulomb’s law is valid for:

Only large charges

Point charges

Only moving charges

None

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Coulomb’s law force depends on:

Distance only

Charges only

Both charges and distance

Time

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Law of conservation of charge states:

Charge is destroyed

Charge is created

Total charge remains constant

Charge disappears

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Charge on an electron is:

+1.6 × 10⁻¹⁹ C

−1.6 × 10⁻¹⁹ C

1.6 × 10⁻¹⁹ C

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Quantization of charge is given by:

q = ne

q = n/e

q = e/n

q = n²e

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Charge is:

Scalar

Vector

Tensor

None

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The SI unit of electric charge is:

Coulomb

Ampere

Volt

Ohm

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