24.4 Heinrich Rudolf Hertz
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Transcript of 24.4 Heinrich Rudolf Hertz
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24.4 Heinrich Rudolf Hertz 1857 – 1894 The first person
generated and received the EM waves 1887
His experiment shows that the EM waves follow the wave phenomena
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Hertz’s Experiment An induction coil is connected to a
transmitter The transmitter consists of two
spherical electrodes separated by a narrow gap to form a capacitor
The oscillations of the charges on the transmitter produce the EM waves.
A second circuit with a receiver, which also consists of two electrodes, is a single loop in several meters away from the transmitter.
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Hertz’s Experiment, cont The coil provides short voltage surges to the
electrodes As the air in the gap is ionized, it becomes a
better conductor The discharge between the electrodes
exhibits an oscillatory behavior at a very high frequency
From a circuit viewpoint, this is equivalent to an LC circuit
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Hertz’s Experiment, final Hertz found that when the frequency of the
receiver was adjusted to match that of the transmitter, the energy was being sent from the transmitter to the receiver
Hertz’s experiment is analogous to the resonance phenomenon between a tuning fork and another one.
Hertz also showed that the radiation generated by this equipment exhibited wave properties Interference, diffraction, reflection, refraction and
polarization He also measured the speed of the radiation
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LC circuit
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24.5 Energy Density in EM Waves The energy density, u, is the energy per
unit volume For the electric field, uE= ½ oE2
For the magnetic field, uB = B2 / 2o
Since B = E/c and oo1c 2
212 2B E o
o
Bu u E
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Energy Density, cont The instantaneous energy density
associated with the magnetic field of an EM wave equals the instantaneous energy density associated with the electric field In a given volume, the energy is shared
equally by the two fields
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Energy Density, final The total instantaneous energy density
in an EM wave is the sum of the energy densities associated with each field u =uE + uB = oE2 = B2 / o
When this is averaged over one or more cycles, the total average becomes uav = o (Eavg)2 = ½ oE2
max = B2max / 2o
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Energy carried by EM Waves Electromagnetic waves carry energy As they propagate through space, they
can transfer energy to objects in their path
The rate of flow of energy in an EM wave is described by a vector called the Poynting vector
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Poynting Vector The Poynting Vector is
defined as
Its direction is the direction of propagation
This is time dependent Its magnitude varies in time Its magnitude reaches a
maximum at the same instant as the fields
1
o S E B
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Poynting Vector, final The magnitude of the vector represents
the rate at which energy flows through a unit surface area perpendicular to the direction of the wave propagation This is the power per unit area
The SI units of the Poynting vector are J/s.m2 = W/m2
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Intensity The wave intensity, I, is the time average of S
(the Poynting vector) over one or more cycles When the average is taken, the time average
of cos2(kx-t) equals half
I = Savg = c uavg
The intensity of an EM wave equals the average energy density multiplied by the speed of light
2 2max max max max
2 2 2avgo o o
E B E c BI Sc
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24.6 Momentum and Radiation Pressure of EM Waves
EM waves transport momentum as well as energy
As this momentum is absorbed by some surface, pressure is exerted on the surface
Assuming the EM wave transports a total energy U to the surface in a time interval t, the total momentum is p = U / c for complete absorption
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Measuring Radiation Pressure
This is an apparatus for measuring radiation pressure
In practice, the system is contained in a high vacuum
The pressure is determined by the angle through which the horizontal connecting rod rotates
For complete absorption An absorbing surface for which all
the incident energy is absorbed is called a black body
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Pressure and Momentum Pressure, P, is defined as the force per
unit area
But the magnitude of the Poynting vector is (dU/dt)/A and so P = S / c
1 1F dp dU dtPA A dt c A
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Pressure and Momentum, cont
For a perfectly reflecting surface, p = 2 U / c and P = 2 S / c
For a surface with a reflectivity somewhere between a perfect reflector and a perfect absorber, the momentum delivered to the surface will be somewhere in between U/c and 2U/c
For direct sunlight, the radiation pressure is about 5 x 10-6 N/m2
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