Match List I (Wavelength range of electromagnetic spectrum) with List II (Method of production of these waves) and select the correct option from the options given below the lists. List I List II (a) 700 nm to 1 mm (i) Vibration of atoms and molecules. (b) 1 nm to 400 nm (ii) Inner shell electrons in atoms moving from one energy level to a lower level. (c) < 10 - 3 nm (iii) Radioactive decay of the nucleus. (d) 1 mm to 0 . 1 m (iv) Magnetron valve.

(a) - (i), (b) - (ii), (c) - (iii), (d) - (iv)

(a) - (iii), (b) - (iv), (c) - (i), (d) - (ii)

(a) - (iv), (b) - (iii), (c) - (ii), (d) - (i)

(a) - (ii), (b) - (iii), (c) - (iv), (d) - (i)

The electric field of a plane polarized electromagnetic wave in free space at time t = 0 is given by the expression E → x , y = 10 j ^ c o s 6 x + 8 z . The magnetic field B → x , z , t is given by ( c is the velocity of light.)

1 c 6 k ^ - 8 i ^ c o s 6 x + 8 z - 10 c t

1 c 6 k ^ - 8 i ^ cos 6 x + 8 z + 10 c t

1 c 6 k ^ + 8 i ^ cos 6 x + 8 z - 10 c t

1 c 6 k ^ + 8 i ^ cos 6 x - 8 z + 10 c t

The magnetic field of an electromagnetic wave is given by: B → = 1.6 × 10 - 6 cos ⁡ 2 × 10 7 z + 6 × 10 15 t 2 i ^ + j ^ W b m 2 The associated electric field will be:

E → = 4.8 × 10 2 c o s 2 × 10 7 z + 6 × 10 15 t - i ^ + 2 j ^ V m

E → = 4.8 × 10 2 c o s 2 × 10 7 z - 6 × 10 15 t - 2 j ^ + i ^ V m

E → = 4.8 × 10 2 c o s 2 × 10 7 z + 6 × 10 15 t i ^ - 2 j ^ V m

E → = 4.8 × 10 2 c o s 2 × 10 7 z - 6 × 10 15 t 2 i ^ + j ^ V m

The electric field of a plane electromagnetic wave is given by E → = E 0 i ^ c o s k z c o s ( ω t ) The corresponding magnetic field B → is then given by:

B → = E 0 c j ^ sin ⁡ k z s i n ( ω t )

B → = E 0 c j ^ cos ⁡ k z s i n ( ω t )

B → = E 0 c k ^ sin ⁡ k z c o s ( ω t )

B → = E 0 c j ^ sin ⁡ k z c o s ( ω t )

Magnetic field in a plane electromagnetic wave is given by, B → = B 0 sin k x + ω t j ^ T . Expression for corresponding electric field will be: (Where c is speed of light)

E → = B 0 c sin k x + ω t k ^ V m - 1

E → = - B 0 c sin k x + ω t k ^ V m - 1

E → = B 0 c sin k x - ω t k ^ V m - 1

E → = B 0 c sin k x + ω t k ^ V m - 1

An electromagnetic wave is travelling in x -direction with electric field vector given by, E → y = E 0 sin k x - ω t j ^ . The correct expression for magnetic field vector is

B → z = E 0 c sin ( k x - ω t ) k ^

B → y = E 0 c sin k x - ω t j ^

B → z = E 0 c sin k x - ω t k ^

If the magnetic field in a plane electromagnetic wave is given by B → = 3 × 10 - 8 sin 1.6 × 10 3 x + 48 × 10 10 t j ^ T , then what will be expression for electric field ?

E → = 9 sin ⁡ 1.6 × 10 3 x + 48 × 10 10 t k ^ V m

E → = 60 sin ⁡ 1.6 × 10 3 x + 48 × 10 10 t k ^ V m

E → = 3 × 10 - 8 sin 1.6 × 10 3 x + 48 × 10 10 t j ^ V m

E → = 3 × 10 - 8 sin 1.6 × 10 3 x + 48 × 10 10 t i ^ V m

EASY

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Which of the following is not an electromagnetic wave?

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Important Questions on Electromagnetic Waves

EASY

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

Out of the following options which one can be used to produce a propagating electromagnetic wave?

HARD

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

Match List I (Wavelength range of electromagnetic spectrum) with List II (Method of production of these waves) and select the correct option from the options given below the lists.

	List I		List II
(a)	$700 nm$ to $1 mm$	(i)	Vibration of atoms and molecules.
(b)	$1 nm$ to $400 nm$	(ii)	Inner shell electrons in atoms moving from one energy level to a lower level.
(c)	$< 10^{- 3} nm$	(iii)	Radioactive decay of the nucleus.
(d)	$1 mm$ to $0.1 m$	(iv)	Magnetron valve.

EASY

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

Consider an electromagnetic wave propagating in vacuum. Choose the correct statement:

EASY

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

The magnetic field in a travelling electromagnetic wave has a peak value of

20 nT

. The peak value of electric field strength is :

HARD

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

The electric field of a plane polarized electromagnetic wave in free space at time

t = 0

is given by the expression

\vec{E} (x, y) = 10 \hat{j} c o s (6 x + 8 z)

. The magnetic field

\vec{B} (x, z, t)

is given by (

c

is the velocity of light.)

MEDIUM

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

The magnetic field of an electromagnetic wave is given by:

\vec{B} = 1.6 \times 10^{- 6} \cos (2 \times 10^{7} z + 6 \times 10^{15} t) (2 \hat{i} + \hat{j}) \frac{W b}{m^{2}}

The associated electric field will be:

MEDIUM

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

An EM wave from air enters a medium. The electric fields are

{\vec{E}}_{1} = E_{01} \hat{x} \cos [2 π v (\frac{z}{c} - t)]

in air and

{\vec{E}}_{2} = E_{02} \hat{x} \cos [k (2 z - c t)]

in medium, where the wave number k and frequency

v

refer to their values in the air. The medium is non-magnetic. If

ϵ_{r_{1}}

and

ϵ_{r_{2}}

refer to relative permittivities of air and medium respectively, which of the following options, is correct?

EASY

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

The electric field of a plane electromagnetic wave is given by

\vec{E} = E_{0} \hat{i} c o s (k z) c o s (ω t)

The corresponding magnetic field

\vec{B}

is then given by:

MEDIUM

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

Magnetic field in a plane electromagnetic wave is given by,

\vec{B} = B_{0} \sin (k x + ω t) \hat{j} T

. Expression for corresponding electric field will be:

(Where

c

is speed of light)

HARD

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

The electric field component of a monochromatic radiation is given by

\vec{E} = 2 E_{0} \cos k z \cos ω t \hat{i}

, Its magnetic field

\vec{B}

is then given by:

MEDIUM

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

A plane electromagnetic wave travels in free space along the x-direction. The electric field component of the wave at a particular point of space and time is

E = 6 V m^{- 1}

along y-direction. Its corresponding magnetic field component,

B

would be:

MEDIUM

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

A red $L E D$ emits light at $0.1 watt$ uniformly around it. The amplitude of the electric field of the light at a distance of $1 m$ from the diode is:

EASY

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

An electromagnetic wave is represented by the electric filed

\vec{E} = E_{0} \hat{n} \sin [ω t + (6 y - 8 z)] .

Taking unit vectors in

x, y

and

z

directions to be

\hat{i}, \hat{j}, \hat{k},

the directions of propagations

\hat{s},

is:

EASY

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

Microwave oven acts on the principle of:

HARD

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

The magnetic field of a plane electromagnetic wave is given by

\vec{B} = B_{0} \hat{i} [c o s (k z - ω t)] + B_{1} \hat{j} c o s (k z + ω t)

, where

B_{0} = 3 \times 10^{- 5} T

and

B_{1} = 2 \times 10^{- 6} T

. The

RMS

value of the force experienced by a stationary charge

Q = 10^{- 4} C

z = 0

is closest to

EASY

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

An electromagnetic wave is travelling in

x

-direction with electric field vector given by,

{\vec{E}}_{y} = E_{0} \sin (k x - ω t) \hat{j}

. The correct expression for magnetic field vector is

MEDIUM

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

If the magnetic field in a plane electromagnetic wave is given by

\vec{B} = 3 \times 10^{- 8} \sin (1.6 \times 10^{3} x + 48 \times 10^{10} t) \hat{j} T,

then what will be expression for electric field ?

EASY

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

In an electromagnetic wave in free space the root mean square value of the electric field is

E_{r m s} = 6 V m^{- 1}

. The peak value of the magnetic field is

MEDIUM

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

An electromagnetic wave travelling in the

x -

direction has frequency of

2 \times 10^{14} H z

and electric field amplitude of

27 V m^{- 1}

oscillates in

Y -

direction. From the options given below, which one describes the magnetic field for this wave?

EASY

Physics>Electricity and Magnetism>Electromagnetic Waves>Electromagnetic Waves and Their Characteristics

If the magnetic field of a plane electromagnetic wave is given by (The speed of light

= 3 \times 10^{8} m s^{- 1}

)

B = 100 \times 10^{- 6} \sin [2 π \times 2 \times 10^{15} (t - \frac{x}{c})]

then the maximum electric field associated with it is:

Which of the following is not an electromagnetic wave?

Important Questions on Electromagnetic Waves

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