20 · LIGHT AND SPECTROSCOPYElectronic spectra of other atoms
The emission spectrum of sodium atoms is produced by passing an electric dis-
charge through sodium vapour (sodium vapour is easily produced by heating
sodium metal). Figure 20.8(a) shows how the two main emission lines in the sodium
atom spectrum would appear when recorded on a photographic emulsion. When
the human eye is used as a detector (as in a hand-held spectroscope), both lines are
seen to be an intense yellow colour. The lines are responsible for the yellow colour
of sodium street lights and the yellow colour observed when sodium compounds
(such as salt) are sprinkled into flames. Although the lines are separated only by
0.6 nm (0.6 nanometres), they can be distinguished (resolved) even with cheap spec-
troscopes.
The absorption spectrum (Fig. 20.8(b)) of sodium atoms is produced by measur-
ing the light wavelengths absorbed when white light is passed through sodium vapour.
The absorption spectrum as recorded on a photographic emulsion contains lines at
the same frequency as those found in the emission spectrum, but they are light (not
dark) because the lines represent a reductionin the intensity of the white light source at
those wavelengths.
The absorption and emission spectra of metals such as copper, lithium, caesium,
calcium and potassium involve lines at different wavelengths to those observed in the
sodium spectrum. As with sodium, a few lines in each spectrum dominate the colours
of compounds of these metals in the gas flame. This is the basis of the flame testswhich
are used to indicate the presence of compounds of these metals (see page 195).Electronic spectra of molecules
Changes of electronic energy in simple molecules, such as H 2 O, HCl or H 2 , generally
give rise to absorption and emission spectra in the UV region. Many larger organic
molecules (including dyes) and some inorganic ions display part of their electronic
spectra in the visible region. Figure 20.9 shows the electronic spectrum of potassium
manganate(VII) (potassium permanganate, KMnO 4 ), in aqueous solution between
400 and 600 nm. Water and potassium ions do not absorb in this wavelength range –
the absorption is solely due to the MnO 4 – ion.Fluorescence
Some molecules absorb ultraviolet light and immediately emit light at a slightly
longer wavelength. This is called fluorescence. For example, quinine (which gives
tonic water its bitter taste) is colourless, but upon irradiation with UV light it emits a376
Fig. 20.8The two strongest lines in the
visible region in (a) the emission and (b)
the absorption spectra of sodium atoms.