(8) the magnetic field intensity vector H (x,y,z,t), and (9) the time-average intensity (power per unit area) of the wave. 1 Hint: the vacuum permittivity is -x109 F/m and the vacuum 367 permeability is 4 = 47×107 H/m.
Electromagnetic Power Density
The power density of an electromagnetic (EM) wave is proportional to the square of the frequency of electric field (or magnetic field). The moving charge produces both electric field and magnetic field. Electric and magnetic fields are inseparable and exist in combination in EM waves.
Wave Reflection and Transmission
Reflection is defined as a sudden change in the path of the wave that strikes the boundary between two types of media. The least part of the disturbances coming from the wavelength remains the same within the same area. The reflection of the wave takes place by following everyday thinking, simple rules, at the ends of the plane. The coefficient of reflection is the ratio of the amplitude of the reflected wave to the value of the incident wave.
Skin Depth
The wire-type conductors are used in the transmission of electrical energy or signals using an alternating current. The electrons are driven apart due to the electric field created nearby the copper conductor surface. The magnetic field changes with the change in the current density. This change in the magnetic field produces an electric field that opposes the current density change. This electric field is known as back electromotive force (EMF). This force is stronger inside the copper conductor and is weaker at the surface. An alternating current can be induced due to the magnetic field according to the law of induction. Such a current is produced due to the electromagnetic wave impinging on the copper conductor.
Plane wave propagation
Any of the ways how waves travel is known as wave propagation. One can find the difference between longitudinal wave and transverse wave with respect to the direction of oscillation, which is related to the propagation direction. Propagation may occur in vacuum for electromagnetic waves as well as in material medium. Other types of waves need a transmission medium to exist and cannot propagate through the vacuum. The amplitude of a wave is the maximum distance from the displacement of the particle from its resting position on the medium. The waves that propagate are of two types, Pressure waves or Shear waves.
8 and 9 0nly
![Problem 3
The electric field intensity of a time-harmonic plane electromagnetic wave is given by
Ē(x, y, z, t) = a 126× sin[10°t - 6y + 8z - 0.2] Volt/m, where all the variables are
in MKSA units. This wave propagates in a simple, nonmagnetic, lossless medium.
Find numerically, including units if applicable, for
(1) the unit vector pointing to the wavefront propagation direction,
(Indicate the direction of the vector by plotting it in the y-z plane)
(2) the wavelength along the wavefront normal direction,
(3) the wavefront velocity or the phase velocity of the electromagnetic wave in
the wavefront propagation direction,
(4) the phase velocity in the z direction,
(5) the wavelength in the y direction,
(6) the refractive index of the medium,
(7) the intrinsic wave impedance,
(8) the magnetic field intensity vector H(x,y,z,t), and
(9) the time-average intensity (power per unit area) of the wave.
1
36л
Hint: the vacuum permittivity is &
=
permeability is = 4×107 H/m.
109 F/m and the vacuum](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F463d379b-4d7c-4041-b0ec-7b676d1223ee%2Fe73f5ec7-d549-41e9-982d-893877769315%2F9hodmjd_processed.jpeg&w=3840&q=75)
Step by step
Solved in 3 steps
