Electromagnetic Waves — Page 9 | NEET Physics

Q81

A plane electromagnetic wave of frequency 50 MHz travels in free space along the positive x-direction. At a particular point in space and time,

\overrightarrow E = 6.3\widehat j\,V/m.

The corresponding magnetic field

\overrightarrow {B,}

at that point will be :

A 18.9

\times

10

-

8

\widehat k

T

B 2.1

\times

10

-

8

\widehat k

T

C 6.3

\times

10

-

8

\widehat k

T

D 18.9

\times

108

\widehat k

T

Correct Answer

Option B

Solution

Given,

\overrightarrow E = 6.3\widehat j

$\therefore$

\left| {\overrightarrow E } \right| = \sqrt {{{\left( {6.3} \right)}^2}} = 6.3

$\therefore$

\left| {\overrightarrow B } \right| = {{\left| {\overrightarrow E } \right|} \over C}

= {{6.3} \over {3 \times {{10}^8}}}

= 2.1 \times {10^{ - 8}}\,

T Now we have to find the direction of

\overrightarrow B

. We know,

\widehat E \times \widehat B = \widehat C

and given

\overrightarrow E

is in y-direction and wave moving in positive x-direction. $\therefore$

\widehat J \times \widehat B = \widehat i

$\Rightarrow$

\widehat B = \widehat K

$\therefore$

\overrightarrow B = \left| {\overrightarrow B } \right|\widehat B

= 2.1 \times {10^{ - 8}}\,\widehat K\,T

Q82

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

\overrightarrow B

= 3

\times

10-8 sin(1.6

\times

103x + 48

\times

1010t)

\widehat j

T, then what will be expression for electric field ?

A

\overrightarrow E

= (9sin(1.6

\times

103x + 48

\times

1010t)

\widehat k

V/m)

B

\overrightarrow E

= (60sin(1.6

\times

103x + 48

\times

1010t)

\widehat k

V/m)

C

\overrightarrow E

= (3

\times

10-8 sin(1.6

\times

103x + 48

\times

1010t)

\widehat i

V/m)

D

\overrightarrow E

= (3

\times

10-8 sin(1.6

\times

103x + 48

\times

1010t)

\widehat j

V/m)

Correct Answer

Option A

Solution

Given

\overrightarrow B

= 3 $\times$ 10-8 sin(1.6 $\times$ 103x + 48 $\times$ 1010t)

\widehat j

T We know,

{{{E_0}} \over {{B_0}}} = c

$\Rightarrow$ E0 = (3 $\times$ 10-8) $\times$ (3 $\times$ 10-8) = 9 V/m $\therefore$

\overrightarrow E

= (9sin(1.6 $\times$ 103x + 48 $\times$ 1010t)

\widehat k

V/m)

Q83

The electric field in an electromagnetic wave is given as

\overrightarrow{\mathrm{E}}=20 \sin \omega\left(\mathrm{t}-\dfrac{x}{\mathrm{c}}\right) \overrightarrow{\mathrm{j}} \mathrm{NC}^{-1}

where

\omega

and

c

are angular frequency and velocity of electromagnetic wave respectively. The energy contained in a volume of

5 \times 10^{-4} \mathrm{~m}^{3}

will be (Given

\varepsilon_{0}=8.85 \times 10^{-12} \mathrm{C}^{2} / \mathrm{Nm}^{2}

)

A

17 \cdot 7 \times 10^{-13} \mathrm{~J}

B

28 \cdot 5 \times 10^{-13} \mathrm{~J}

C

8 \cdot 85 \times 10^{-13} \mathrm{~J}

D

88 \cdot 5 \times 10^{-13} \mathrm{~J}

Correct Answer

Option C

Solution

To find the energy contained in a volume of an electromagnetic wave, we need to calculate the energy density and then multiply it by the volume.

For an electromagnetic wave, the energy density

u

is given by:

u = \frac{1}{2} \varepsilon_0 E^2

where

\varepsilon_0

is the vacuum permittivity and

E

is the electric field amplitude. First, let's find the amplitude of the electric field. In the given equation:

\overrightarrow{\mathrm{E}}=20 \sin \omega\left(\mathrm{t}-\frac{x}{\mathrm{c}}\right) \overrightarrow{\mathrm{j}} \mathrm{NC}^{-1}

The amplitude

E

is

20 \mathrm{~N/C}

. Now, we can find the energy density:

u = \frac{1}{2} \cdot 8.85 \times 10^{-12} \mathrm{C}^{2} / \mathrm{Nm}^{2} \cdot (20 \mathrm{~N/C})^2

u = \frac{1}{2} \cdot 8.85 \times 10^{-12} \cdot 400

u = 1.77 \times 10^{-9} \mathrm{J/m^3}

The energy contained in a volume of

5 \times 10^{-4} \mathrm{m^3}

will be:

E_\text{total} = u \cdot V

E_\text{total} = 1.77 \times 10^{-9} \mathrm{J/m^3} \cdot 5 \times 10^{-4} \mathrm{m^3}

E_\text{total} = 8.85 \times 10^{-13} \mathrm{J}

Q84

A plane electromagnetic wave travels in a medium of relative permeability 1.61 and relative permittivity 6.44. If magnitude of magnetic intensity is 4.5

\times

10

-

2 Am

-

1 at a point, what will be the approximate magnitude of electric field intensity at that point? (Given : Permeability of free space

\mu

0 = 4

\pi

\times

10

-

7 NA

-

2, speed of light in vacuum c = 3

\times

108 ms

-

1)

A 16.96 Vm

-

1

B 2.25

\times

10

-

2 Vm

-

1

C 8.48 Vm

-

1

D 6.75

\times

106 Vm

-

1

Correct Answer

Option C

Solution

H = 4.5 $\times$ 10 $-$ 2 So B = $\mu$ 0 $\mu$ H Thus

E = {c \over n}B

(where n $\Rightarrow$ refractive index) So

E = {{3 \times {{10}^8} \times 4\pi \times {{10}^{ - 7}} \times 1.61 \times 4.5 \times {{10}^{ - 2}}} \over {\sqrt {1.61 \times 6.44} }}

E = 8.48

Q85

Match with : .tg .tg

List - I		List - II
(a)	Ultraviolet rays	(i)	Study crystal structure
(b)	Microwaves	(ii)	Greenhouse effect
(c)	Infrared rays	(iii)	Sterilizing surgical instrument
(d)	X-rays	(iv)	Radar system

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

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

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

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

Correct Answer

Option A

Solution

UV rays are used to sterilize surgical material.

Microwaves are used in radar system.

Infrared are used for green house effect and X-rays are used to study crystal structure.

Q86

Which of the following Maxwell's equation is valid for time varying conditions but not valid for static conditions :

A

\oint \overrightarrow{\mathrm{E}} \cdot \overrightarrow{d l}=0

B

\oint \vec{B} \cdot \overrightarrow{d l}=\mu_{0} I

C

\oint \vec{E} \cdot \overrightarrow{d l}=-\dfrac{\partial \phi_{B}}{\partial t}

D

\oint \vec{D} \cdot \overrightarrow{d A}=Q

Correct Answer

Option C

Solution

Maxwell's equations describe the behavior of electric and magnetic fields.

There are four equations, and each has a specific role.

In the given options, Option C refers to Faraday's Law of Electromagnetic Induction, which is the only equation among the options that is not valid for static conditions.

Option C: Faraday's Law of Electromagnetic Induction:

\oint \vec{E} \cdot \overrightarrow{d l}=-\frac{\partial \phi_{B}}{\partial t}

This equation states that a time-varying magnetic field (changing magnetic flux, $\phi_B$ ) induces an electromotive force (EMF) in a closed conducting loop, creating an electric field.

In static conditions, the magnetic field doesn't change over time, and there is no induced EMF.

Therefore, Faraday's Law is valid for time-varying conditions but not for static conditions.

Q87

An electromagnetic wave in vacuum has the electric and magnetic field

\mathop E\limits^ \to

and

\mathop B\limits^ \to

, which are always perpendicular to each other. The direction of polarization is given by

\mathop X\limits^ \to

and that of wave propagation by

\mathop k\limits^ \to

. Then

A

\mathop X\limits^ \to ||\mathop B\limits^ \to

and

\mathop X\limits^ \to ||\mathop B\limits^ \to \times \mathop E\limits^ \to

B

\mathop X\limits^ \to ||\mathop E\limits^ \to

and

\mathop k\limits^ \to ||\mathop E\limits^ \to \times \mathop B\limits^ \to

C

\mathop X\limits^ \to ||\mathop B\limits^ \to

and

\mathop k\limits^ \to ||\mathop E\limits^ \to \times \mathop B\limits^ \to

D

\mathop X\limits^ \to ||\mathop E\limits^ \to

and

\mathop k\limits^ \to ||\mathop B\limits^ \to \times \mathop E\limits^ \to

Correct Answer

Option B

Solution

as The

E.M.

wave are transverse in nature i.e.,

= {{\overrightarrow k \times \overrightarrow E } \over {\mu \omega }} = \overrightarrow H \,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,...\left( i \right)

where

\overrightarrow H = {{\overrightarrow B } \over \mu }

and

{{\overrightarrow k \times \overrightarrow H } \over {\omega \varepsilon }} = - \overrightarrow E \,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,...\left( {ii} \right)

\overrightarrow k

is

\bot \,\,\overrightarrow H

and

\overrightarrow k

is also $\bot$ to

\overrightarrow E

or In other words

\overrightarrow X ||\overrightarrow E

and

\overrightarrow k ||\overrightarrow E \times \overrightarrow B

Q88

The

rms

value of the electric field of the light coming from the Sun is

720

N/C.

The average total energy density of the electromagnetic wave is

A

4.58 \times {10^{ - 6}}\,J/{m^3}

B

6.37 \times {10^{ - 9}}\,J/{m^3}

C

81.35 \times {10^{ - 12}}\,J/{m^3}

D

3.3 \times {10^{ - 3}}\,J/{m^3}

Correct Answer

Option A

Solution

{E_{rms}} = 720

The average total energy density

= {1 \over 2}{ \in _0}\,E_0^2 = {1 \over 2}{ \in _0}{\left[ {\sqrt 2 {E_{rms}}} \right]^2} = { \in _0}\,E_{rms}^2

= 8.85 \times {10^{ - 12}} \times {\left( {720} \right)^2}

= 4.58 \times {10^{ - 6}}\,J/{m^3}

Q89

A plane electromagnetic wave of frequency 500 MHz is travelling in vacuum along y-direction. At a particular point in space and time,

\overrightarrow B

= 8.0

\times

10

-

8

\widehat z

T. The value of electric field at this point is : (speed of light = 3

\times

108 ms

-

1)

\widehat x

,

\widehat y

,

\widehat z

are unit vectors along x, y and z directions.

A 2.6

\widehat x

V/m

B

-

24

\widehat x

V/m

C 24

\widehat x

V/m

D

-

2.6

\widehat y

V/m

Correct Answer

Option B

Solution

{E_0} = B.C

{E_0} = (8 \times {10^{ - 8}}) \times (3 \times {10^8})

\Rightarrow {E_0} = 24

Direction of wave travelling is in

\overrightarrow E \times \overrightarrow B

So,

( - \widehat x) \times \widehat z = + \widehat y

$\therefore$

\widehat E = -24\widehat x

V/m

Q90

The relative permittivity of distilled water is 81. The velocity of light in it will be : (Given

\mu

r = 1)

A 4.33

\times

107 m/s

B 2.33

\times

107 m/s

C 3.33

\times

107 m/s

D 5.33

\times

107 m/s

Correct Answer

Option C

Solution

The speed of light in a medium is given by the equation:

v = \frac{c}{\sqrt{\varepsilon_r \mu_r}}

where: $c$ is the speed of light in vacuum (approximately $3 \times 10^8$ m/s), $\varepsilon_r$ is the relative permittivity of the medium (in this case, distilled water, and is given as 81), $\mu_r$ is the relative permeability of the medium (given as 1 for distilled water).

Substituting the given values into the equation, we get:

v = \frac{3 \times 10^8 \, \text{m/s}}{\sqrt{81 \times 1}}

v = \frac{3 \times 10^8 \, \text{m/s}}{9}

v = 3.33 \times 10^7 \, \text{m/s}

So, the speed of light in distilled water is $3.33 \times 10^7$ m/s.