spectral line series

▪ physics

      any of the related sequences of wavelengths characterizing the light and other electromagnetic radiation emitted by energized atoms. The simplest of these series are produced by hydrogen. When resolved by a spectroscope, the individual components of the radiation form images of the source (a slit through which the beam of radiation enters the device). These images, in the form of lines, appear to have a regularity in spacing, coming closer together toward the shortest wavelength, called the series limit. Hydrogen displays five of these series in various parts of the spectrum, the best-known being the Balmer series in the visible region. Johann Balmer, a Swiss mathematician, discovered (1885) that the wavelengths of the visible hydrogen lines can be expressed by a simple formula: the reciprocal wavelength (1/λ) is equal to a constant (R) times the difference between two terms, 1/4 (written as 1/2²) and the reciprocal of the square of a variable integer (1/n²), which takes on successive values 3, 4, 5, etc.; i.e., 1/λ = R(1/2² - 1/n²). The constant R is known as the Rydberg constant, after Johannes Robert Rydberg, a Swedish physicist, and, in the case of hydrogen, has a value of 109,677.58 reciprocal centimetres. When n = 3, Balmer's formula gives λ = 656.21 nanometres (1 nanometre = 10^-9 metre), the wavelength of the line designated Hα, the first member of the series (in the red region of the spectrum), and when n = ∞, λ = 4/R, the series limit (in the ultraviolet).

      The four other spectral line series, in addition to the Balmer series, are named after their discoverers, Theodore Lyman, A.H. Pfund, and F.S. Brackett of the United States and Friedrich Paschen of Germany. The Lyman series lies in the ultraviolet, whereas the Paschen, Brackett, and Pfund series lie in the infrared. Their formulas are similar to Balmer's except that the constant term is the reciprocal of the square of 1, 3, 4, or 5, instead of 2, and the running number n begins at 2, 4, 5, or 6, respectively, instead of 3.

      Atoms of other elements that have lost all their electrons, save one, and therefore are hydrogen-like (e.g., singly-ionized helium and doubly-ionized lithium), also emit radiation that can be analyzed into spectral line series that can be expressed by formulas similar to Balmer's.

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