Wavenumber: Difference between revisions

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In spectroscopy, the wavenumber indicates the number of EM waves that would fit in a unit of length. The normal units for wavenumbers are inverse centimeters cm^-1. A different name for this unit is kayser (after Heinrich Kayser). Light with a wavelength of 500 nm (green) has a wavenumber of 20,000 cm^-1 or 20 kK. Photon energy and frequency are proportional to wavenumber: 10 kK corresponds to 1.24 eV.

Historically, wavenumbers were introduced by Janne Rydberg in the 1880's in his analyses of atomic spectra.

Wavenumbers ( $v'$ ), wavelength ( $\lambda$ ), and frequency ( $v$ ) are related:

$v'[cm^{-1}]={\frac {1}{\lambda [cm]}}={\frac {v[sec^{-1}]}{(c{\frac {m}{sec}})(100{\frac {cm}{m}})}}$

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 In spectroscopy, the '''wavenumber''' indicates the number of [[Electromagnetic spectrum|EM waves]] that would fit in a unit of length.  The normal units for wavenumbers are inverse centimeters cm<sup>-1</sup>. A different name for this unit is kayser (after [[Heinrich Kayser]]). Light with a wavelength of 500 nm (green) has a wavenumber of 20,000 cm<sup>-1</sup> or 20&nbsp;kK. Photon energy and frequency are proportional to wavenumber: 10&nbsp;kK corresponds to 1.24 eV.
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    v' [cm^{-1}] = \frac{1}{\lambda [cm]} = \frac{v [sec^{-1}]}{(c \frac{m}{sec}) (100 \frac{cm}{m})}
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Wavenumber: Difference between revisions

Revision as of 15:40, 19 December 2007

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