ABSORPTION SPECTRA AND COLOURpurple glow. The emission stops as soon as the light is turned off. Other common
fluorescent molecules include caffeine, benzene and ‘fluorescein’. Fluorescent mate-
rials are used to label valuables (‘security tagging’) – the written information can
only be seen in UV light.
Chemiluminescence
When fuels are burned in a flame, both heat andlight are produced. There are some
chemical reactions which produce light but no heat. These reactions are said to be
chemiluminescent, and the light is emitted by electronically excited molecules or
atoms produced during the reaction mechanism. Examples of chemiluminescence
in nature are to be found in the fire-fly, glow-worms and in some types of fish found
in the (otherwise dark) ocean depths. The familiar glow of air when subjected to
high voltage discharges (including lightning) is also due to chemiluminescence.
Chemiluminescent ‘fun sticks’ contain reactants in separate tubes. On bending the
stick, the tubes are broken and the reactants mix, producing the chemiluminescent
emission. The observed colour of the emission depends upon the type of dye in the reac-
tion mixture. The same principle is used in ‘light sticks’ designed to be used in emergen-
cies by cavers and walkers, some of which continue to emit light for several hours.
Absorption spectra and colour
Colour of compounds
The colour of a solution is controlled by the light that is transmittedthrough the solution.
Think of the manganate(VII) ion. Its solution, viewed under white light, is violet.
From its spectrum, Fig. 20.9, we see that the most intense absorptions in the visible
wavelengths lie between 520 and 550 nm. This is yellow-green light. The remaining
colours of white light pass through the solution, and it happens that the human eye
interprets this combination of transmitted wavelengths (and their relative intensities)
as violet in colour (Fig. 20.10).
Similarly, a coloured solid absorbs only some wavelengths of light. The observed
colour of the solid is due to the wavelengths of light that are unabsorbed, and which
arereflectedinto the eyes of the observer.
It follows that the colour of a compound can be predictedfrom its absorption spec-
trum in the visible region.
20.6
377Fig. 20.9Electronic spectrum of the
manganate(VII) ion between 400 and
600 nm (perspex 1.0 cm cell).Chemiluminescence
The rate of
chemiluminescent emission
is controlled by the speed
at which the excited
electronic states are
produced by the chemical
reaction. With this in mind,
what would you expect to
happen to the intensity of
emission from a funstick if
the stick was placed in (i)
iced water, (ii)warm water?Exercise 20G