Chapter 8 Electromagnetic Waves
SANDEEP SONI’S PHYSICS COMPETITION CLASSES
(10+1, 10+2, IIT-JEE (Main & Advance), NEET, B.Sc. Agriculture, NDA)
OPP: JHUNTHARA DHARAMSHALA NEAR SURKHAB CHOWK, HISSAR ROAD SIRSA
Unit-5 Electromagnetic Waves PH- 94676-12340, 8708535733
Unit-5 Electromagnetic Waves
1 Electromagnetic Waves m.imp:
A wave originated by changing electric field and magnetic field is called electromagnetic waves. These waves are transverse in nature and propagate in a direction perpendicular to both electric and magnetic field. Electric and magnetic field are also perpendicular to each other.
These waves do not require any material medium for their propagation.
2 Hertz Demonstration of Electromagnetic Waves:
In 1887, a German Scientist Hertz demonstrated an experiment for production of electromagnetic waves using an oscillatory circuit.
He used two large metallic plates and connected input to an induction coil.
The two metallic spheres separated by a small air gap are connected to the metallic plates, which acts as a capacitor of capacitance C.
When input is supplied then spark produces between metallic plates which produce electromagnetic waves of frequency
This frequency can be observed by receiver
The frequency produced by Hertz experiment was small, later J.C. Bose and Marconi obtained large frequency electromagnetic waves.
3 Characteristics/Properties of Electromagnetic Wave m. imp:
These waves do not require any material medium for their propagation.
These waves are transverse in Nature.
The electric field and magnetic field which produces electromagnetic waves are ⊥ to each other and are also ⊥ to direction of propagation of light.
The electromagnetic waves travel with velocity of light in space.
The energy densities of electromagnetic waves of electric field and magnetic field are equal.
the velocity of electromagnetic waves in medium is
An electric dipole is a basic source of electromagnetic waves.
Electromagnetic waves transport energy. The rate of energy transported of electromagnetic waves per unit area is represented by a quantity called pointing vector. i.e Unit:
The electric field vector is responsible for the optical effect of light. There electric field vector are called light vector.
Electromagnetic waves do not deflect by electric and magnetic field.
Electromagnetic waves obey principle of superposition. They show the properties of reflection, refraction, interference, diffraction on and polarization.
When electromagnetic travel from one medium to another medium then its wavelength changes but frequency (inherent property) remains constant.
The magnitude of propagation vector of electromagnetic waves can be given as
4 Maxwell’s concept of Electromagnetism or Displacement Currentm.imp:
According to Maxwell, a changing magnetic field induces an electric field (faradays laws of electromagnetic induction) and hence a changing electric field must induced magnetic field.
As the electric field between two parallel plates capacitors can be given by
Now differentiating both sides we get
Or
Or
Or
Where is the electric flux and I is the current due to change in electric flux between two plates of a capacitor, this current is called displacement current
Now as we know conduction current due to flow of charges in a conductor and are denoted by
So total current
So from Ampere circuital law
We get
Or
The above expression is called modified form of Ampere circuital law and known as Ampere Maxwell circuital law.
5 Maxwell’s Equations:
The Maxwell equations give the basic laws of electromagnetic. These equations are given below
- This eq. is known as Ampere Maxwell Circuital Law.
- this eq. is known as Gauss’s theorem in electrostatics
- This eq. known as Gauss’s law in magnetism.
- This eq. is known as faradays laws in electromagnetic induction.
6 Continuity of currentm.imp:
The sum of conduction current and displacement current is continuous along any closed path, although the individual conduction current and displacement current may not be continuous.
As
7 Electromagnetic Spectrumm.imp:
The whole orderly range of frequencies and wavelengths of the electromagnetic waves is known as the electromagnetic spectrum.The electromagnetic spectrum consists of the following waves.
Sr. No. |
Names |
Frequency |
Wavelength |
Production |
Detection |
Uses |
1 |
Radio Waves |
toHz (Lowest Frequency) |
>0.1m or 600m to 0.1m (Highest λ) |
By Oscillating in LC oscillator |
Receiver aerials |
In Radio and T.V. |
2 |
Micro Waves |
to Hz |
0.1m to 1 mm |
Klystron Valve, Magnetron Valve. |
Point Contact Diode |
|
3 |
Infrared Waves |
to Hz |
1mm to 700 nm |
Vibrating of atoms and molecules. |
Bolometer Infrared photographic plate |
|
4 |
Visible Light |
to Hz |
700 nm to 400 nm |
Electron emits visible light when jumps from excited state to ground level. |
Human eye, Photocells, Photographic film |
|
5 |
Ultra Violet Rays |
to Hz |
400nm to 1nm |
Due to moving in inner shells from one level to another level. |
Photocells, Photographic film. |
|
6 |
X-Ray |
to Hz |
1nm to nm |
From inner shell electrons. |
Photographic Film, Geiger tube, ionization chamber |
|
7 |
-Ray |
to Hz (Highest Frequency) |
<nm (Lowest Wavelength) |
Radioactive decay of the nucleus. |
Photographic film, Geiger tube, Ionization Chamber |
|
1: In a plane electromagnetic wave, the electric field oscillates sinusoidal at a frequency 2 1010 Hz And
Amplitude 48 V/m. The amplitude of oscillating magnetic field will be:
- Wb/m2 (B) 16 10–8 Wb/m2 (C)12 10–7 Wb/m2 (D) Wb/m2
S0l: (B) Oscillating magnetic field B = = 16 10–8 Wb/m2
2: In the above problem, the wavelength of the wave will be-
Sol. Wavelength of electromagnetic wave = = = 1.5 × 10–2 = 1.5 cm
3: What should be the height of transmitting antenna if the T.V. telecast is to cover a radius of 128 km?
Sol. Height of transmitting antenna h = = = 1280 m
4: The area to be covered for T.V. telecast is doubled, and then the height of transmitting antenna (T.V tower) will have to be-
Sol. The area of transmission of surrounding the T.V. tower A = d2 = (2h) A h
5: In an electromagnetic wave, the amplitude of electric field is 1 V/m. The frequency of wave is 5 × 1014 Hz. The wave is propagating along z-axis. The average energy density of electric field, in Joule/m3, will be-
Sol. Average energy density is given by uE = 0E2 = 0 = 0
= × 8.85 × 10–12 × (1)2 = 2.2 × 10–12 J/m2
6: A T.V. tower has a height of 100 m. How much population is covered by T.V. broadcast, if the average population density around the tower is 1000/km2?
Sol. Radius of the area covered by T.V. telecast d =
Total population covered = d2 × population density = 2hRe × population density
= 2 × 3.14 × 100 × 6.4 × 106 × = 39.503 × 105
7: An electromagnetic radiation has energy 14.4 KeV. To which region of electromagnetic spectrum does it belong?
Sol. = = = 0.8 × 10–10m = 0.8 Å. This wavelength belongs to X-ray region.
1. If E and B are the electric and magnetic field vectors of electromagnetic waves then the direction of propagation of electromagnetic wave is along the direction of:
(A) (B) (C) (D) None of these
2. The electromagnetic waves do not transport:
(A) Energy (B) charge (C) momentum (D) information
3. A capacitor is connected in an electric circuit. When key is pressed, the current in the circuit is:
(A) Zero (B) Maximum (C) any transient value (D) depends on capacitor used
4. Displacement current is continuous:
(A) When electric field is changing in the circuit (B) when magnetic field is changing in the circuit
(C) In both types of fields (D) through wires and resistance only
5. The magnetic field between the plates of a capacitor when r > R is given by:
(A) (B) (C) (D) ‘kwU;
Sol. (C) According to Ampere’s law, when r > R B =
6. The conduction current is the same as displacement current when the source is:
(A) A.C. only (B) D.C. only
(C) Both A.C. and D.C. (D) Neither for A.C. nor for D.C.
7. The wave function (in S.I. units) for an electromagnetic wave is given as:
(x, t) = 103 sin (3 106x – 9 1014t) the speed of the wave as:
(A) 9 1014 m/s (B) 3 108 m/s (C) 3 1016 m/s (D) 3 107 m/s
Sol. (B) c = = 3 108 m/s
8. In an electromagnetic wave the average energy density is associated with:
(A) electric field only (B) magnetic field only
(C) Equally with electric and magnetic fields (D) average energy density is zero
9. In an electromagnetic wave the average energy density associated with magnetic field will be:
(A) (B) (C) (D)
10. in the above problem, the energy density associated with the electric field will be:
(A) (B) (C) (D)
11. If there were no atmosphere, the average temperature on earth surface would be:
(A) Lower (B) Higher (C) same (D) 0oC
Sol. (A) The green house effect would not have been possible without atmosphere. Hence temperature would be lower.
12. In which part of earth’s atmosphere is the ozone layer present?
(A) Troposphere (B) Stratosphere (C) Ionosphere (D) Mesosphere
13. Kenneley’s Heaviside layer lies between:
(A) 50Km to 80 Km (B ) 80Km to 400 Km (C) beyond 110 Km (D) beyond 250 Km
14. The ozone layer in earth’s atmosphere is crucial for human survival because it:
(A) Has ions (B) reflects radio signals (C) reflects ultraviolet ray (D) reflects infra red rays
15. The frequency from 3 109 Hz to 3 1010 Hz:
(A) High frequency band (B) Super high frequency band
(C) Ultra high frequency band (D) High frequency band
16. The frequency from 3 to MHz is known as:
(A) Audio band (B) Medium frequency band
(C) Very high frequency band (D) High frequency band
17. The AM range of radio waves has frequency:
(A) Less than 30 MHz (B) More than 30 MHz
(C) Less than 20000 Hz (D) More than 20000 Hz
18. The displacement current flows in the dielectric of a capacitor
(A) Becomes zero (B) has assumed a constant value
(C) Is increasing with time (D) is decreasing with time
19. Select wrong statement from the following Electromagnetic waves:
(A) Are transverse (B) travel with same speed in all media
(C) travel with the speed of light (D) are produced by acceleration charge
20. The waves related to tele-communication are:
(A) Infra red (B) visible light (C) Microwaves (D) ultraviolet rays
21. Electromagnetic waves do not transport:
(A) Energy (B) charge (C) Momentum (D) information
22. The nature of electromagnetic wave is:
(A) Longitudinal (B) longitudinal stationary (C) Transverse (D) transverse stationary
23. Greenhouse effect keeps the earth surface:
(A) Cold at night (B) dusty and cold (C) warm at night (D) moist
24. A plane electromagnetic wave of frequency 40 MHz travels in free space in the X-direction. At some point and at some instant, the electric field has its maximum value of 750 N/C in Y-direction. The wavelength of the wave is:
(A) 3.5 m (B) 5.5 m (C) 7.5 m (D) 9.5 m
Sol. (C)
25. in the above problem, the period of the wave will be:
(A) 2.5 s (B) 0.25 s (C) 0.025 s (D) None of these
Sol. (C) T = = = 0.025s
26. in Q. 40, the magnitude and direction of magnetic field will be:
(A) 2.5 T in X-direction (B) 2.5 T in Y-direction (C) 2.5 T Z-direction (D) none of these
Sol. (C) Bm = = 2.5T Z-direction = 1.34 V/m
27. in Q. 5, the energy density at a distance 3.5m from the source wills be_ (in joule/m3)
(A) 1.73 10–5 (B) 1.73 10–6 (C) 1.73 10–7 (D) 1.73 10–8
Sol. (D) Energy density at 3.5m is given by
= = 1.73 10–8 hence the correct answer will be (D)
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