Difference between revisions of "high energy photon communication"

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m (Created page with 'Category:Science CW transmitter using 19.34 exahertz (1.93*10<sup>19</sup> Hz) electromagnetic radiation. The detector is a pancake Geiger–Müller tube (Mica window 44.5 …')
 
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CW transmitter using 19.34 exahertz (1.93*10<sup>19</sup> Hz) electromagnetic radiation.
 
CW transmitter using 19.34 exahertz (1.93*10<sup>19</sup> Hz) electromagnetic radiation.
  
The detector is a pancake Geiger–Müller tube (Mica window 44.5 mm diameter, 1.75 mg/cm). This is a bit of a joke since the detector cannot discriminate between different wavelengths (or indeed even different types of energy -- alpha and beta particiles versus photons). It is basically a very wide-band detector that is unable to "tune" in the '''carrier wave'''. To compensate for signal loss and noise a very slow data rate and FEC is necessary.
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The detector is a pancake Geiger–Müller tube (Mica window 44.5 mm diameter, 1.75 mg/cm). This is a bit of a joke since the detector cannot discriminate between different wavelengths (or indeed even different types of energy -- alpha and beta particles versus photons). It is basically a very wide-band detector that is unable to "tune" in the '''carrier wave'''. To compensate for signal loss and noise a very slow data rate and FEC is necessary.
  
 
= energy, frequency, electron volts =
 
= energy, frequency, electron volts =

Latest revision as of 12:56, 22 February 2012


CW transmitter using 19.34 exahertz (1.93*1019 Hz) electromagnetic radiation.

The detector is a pancake Geiger–Müller tube (Mica window 44.5 mm diameter, 1.75 mg/cm). This is a bit of a joke since the detector cannot discriminate between different wavelengths (or indeed even different types of energy -- alpha and beta particles versus photons). It is basically a very wide-band detector that is unable to "tune" in the carrier wave. To compensate for signal loss and noise a very slow data rate and FEC is necessary.

energy, frequency, electron volts

The amount of energy a photon carries is determined by its frequency (v) or wavelength (λ).

E = h * v
  or
E = h * c / λ
  or
E eV = 1240 eV nm / λ nm

Where Planck's Constant, h = 4.135667516(91)*10−15 eV·s, and the Speed of Light, c = 299792458 m/s.

So an 80 keV x-ray beam emits photons with a peak energy of 80 keV, this the wavelength:

  80 keV = 1240 eV nm / λ
  λ = 1240 eV nm / 80 keV = 1240 eV nm / 80000 eV
  λ = 1.55 * 10<sup>-11</sup> m
  λ = 0.0155 nm

1.55*10-11 m 1.934*1019 Hz