recorded wavelength - meaning and definition. What is recorded wavelength
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What (who) is recorded wavelength - definition

PHYSICAL QUANTITY OF IDEAL AND QUANTUM GASES
Thermal wavelength; Thermal De Broglie Wavelength

Wavelength (magazine)         
GROUPING OF SURFING MAGAZINES
Wavelength Magazine
Multiple publications exist under the name Wavelength Magazine. 'Wavelength' is a worldwide surfing magazine published by WL Media, based in Newquay, Cornwall.
Single-wavelength anomalous dispersion         
X-RAY CRYSTALLOGRAPHY TECHNIQUE
Single wavelength anomalous dispersion
Single-wavelength anomalous diffraction (SAD) is a technique used in X-ray crystallography that facilitates the determination of the structure of proteins or other biological macromolecules by allowing the solution of the phase problem. In contrast to multi-wavelength anomalous diffraction, SAD uses a single dataset at a single appropriate wavelength.
wavelength         
  • A sinusoidal wave travelling in a nonuniform medium, with loss
  • Relationship between wavelength, angular wavelength, and other wave properties.
  • envelope]].
  • Pattern of light intensity on a screen for light passing through two slits. The labels on the right refer to the difference of the path lengths from the two slits, which are idealized here as point sources.
  • Separation of colors by a prism (click for animation)
  • Various local wavelengths on a crest-to-crest basis in an ocean wave approaching shore<ref name=Pinet2/>
  • Wavelength of a periodic but non-sinusoidal waveform.
  • Near-periodic waves over shallow water
  • Refraction: upon entering a medium where its speed is lower, the wave changes direction.
  • A standing wave (black) depicted as the sum of two propagating waves traveling in opposite directions (red and blue)
  • A propagating wave packet
  • Wavelength is decreased in a medium with slower propagation.
  • A wave on a line of atoms can be interpreted according to a variety of wavelengths.
  • Sinusoidal standing waves in a box that constrains the end points to be nodes will have an integer number of half wavelengths fitting in the box.
SPATIAL PERIOD OF THE WAVE; THE DISTANCE OVER WHICH THE WAVE'S SHAPE REPEATS; THE INVERSE OF THE SPATIAL FREQUENCY
Wave length; Wavelengths; Subwavelength; Long wavelength limit; Wavelenght; Vacuum wavelength; Wave lenght; Wavelength of light; Long Wavelength Limit; Angular wavelength; Optical wavelength; Spatial period
n.
manner of thinking
(colloq.) to be on the same wavelength; to operate on different wavelengths

Wikipedia

Thermal de Broglie wavelength

In physics, the thermal de Broglie wavelength ( λ t h {\displaystyle \lambda _{\mathrm {th} }} , sometimes also denoted by Λ {\displaystyle \Lambda } ) is roughly the average de Broglie wavelength of particles in an ideal gas at the specified temperature. We can take the average interparticle spacing in the gas to be approximately (V/N)1/3 where V is the volume and N is the number of particles. When the thermal de Broglie wavelength is much smaller than the interparticle distance, the gas can be considered to be a classical or Maxwell–Boltzmann gas. On the other hand, when the thermal de Broglie wavelength is on the order of or larger than the interparticle distance, quantum effects will dominate and the gas must be treated as a Fermi gas or a Bose gas, depending on the nature of the gas particles. The critical temperature is the transition point between these two regimes, and at this critical temperature, the thermal wavelength will be approximately equal to the interparticle distance. That is, the quantum nature of the gas will be evident for

i.e., when the interparticle distance is less than the thermal de Broglie wavelength; in this case the gas will obey Bose–Einstein statistics or Fermi–Dirac statistics, whichever is appropriate. This is for example the case for electrons in a typical metal at T = 300 K, where the electron gas obeys Fermi–Dirac statistics, or in a Bose–Einstein condensate. On the other hand, for

i.e., when the interparticle distance is much larger than the thermal de Broglie wavelength, the gas will obey Maxwell–Boltzmann statistics. Such is the case for molecular or atomic gases at room temperature, and for thermal neutrons produced by a neutron source.