3. Characteristics of Electromagnet

3. Characteristics of Electromagnetic Waves

Electromagnetic waves may be thought of as particles of energy (photons) that move through space with wave-like properties, i.e., they exhibit wave-particle duality. They consist of oscillating electric and magnetic fields that are perpendicular to one another, and to the direction of propagation. The sinusoidal variation in the amplitude of the electric vector of the wave can be plotted as a function of time (at a fixed position within a material) or as a function of distance (at a fixed point in time). A monochromatic (single wavelength) electromagnetic wave that propagates through a vacuum can be described completely by its frequency, wavelength and amplitude (or parameters derived from these):

The frequency (v) of a wave is the number of cycles per second (Hz = s-1).
The period (T) of a wave is the time taken to complete a cycle: T = 1/v.
The wavelength (l) is the distance between successive maxima of a wave.
The wave number () is the number of cycles per unit distance (=1/l).
The amplitude (A) of a wave is the maximum magnitude of the electric vector.
The intensity (I) of a wave is proportional to the square of the amplitude. It is the amount of energy passing through a given area per second. Increasing the intensity of an electromagnetic wave increases the number of quanta passing a given area per second, not the energy of each individual quantum.
The velocity (c) of an electromagnetic wave is the distance traveled per second: c = vl. The velocity of an electromagnetic wave travelling through a vacuum is c = 3 x 108 m s-1. The velocity of an electromagnetic wave travelling through a material is always less than that in a vacuum. The refractive index of a material is equal to cvacuum/cmaterial.
The energy (E) of the photons in an electromagnetic wave is related to the frequency of the wave:
E = hv = h/T = hc/l = hc

where, h = Planks constant (6.6262 x 10-34 J s). These expressions can be used to relate the energy of an electromagnetic wave to its frequency, period, wavelength or wave number. This relationship indicates that monochromatic radiation (i.e., radiation of a single frequency) contains photons that all have the same energy.

The electromagnetic spectrum consists of radiation that ranges in wavelength from 10-12 m (high energy) to 104 m (low energy). The physical principles and mathematical description of radiation across the whole of the electromagnetic spectrum is the same, however, it is convenient to divide it into a number of different regions depending on the origin of the waves, i.e., cosmic rays, gamma rays, x-rays, ultraviolet, visible, infrared, microwaves, and radio waves.