Initial conditions The initial aqueous solution contains hydrogen peroxide, an iodate, divalent
manganese (Mn2+) as
catalyst, a strong chemically unreactive acid (
sulfuric acid (H2SO4) or
perchloric acid (HClO4) are good), and an organic compound with an active ("
enolic") hydrogen atom attached to carbon which will slowly
reduce free iodine (I2) to
iodide (I−). (
Malonic acid (CH2(COOH)2) is excellent for that purpose.) Starch is optionally added as an indicator to show the abrupt increase in iodide ion concentration as a sudden change from amber (free iodine) to dark blue (the "
iodine-starch complex", which requires both iodine
and iodide.) Recently it has been shown, however, that the starch is not only an indicator for iodine in the reaction. In the presence of starch the number of oscillations is higher and the period times are longer compared to the starch-free mixtures. It was also found that the iodine consumption segment within one period of oscillation is also significantly longer in the starch-containing mixtures. This suggests that the starch probably acts as a reservoir for the iodine and iodide because of the starch-triiodide equilibrium, thereby modifying the kinetics of the steps in which iodine and iodide are involved. The reaction is "poisoned" by chloride (Cl−) ion, which must therefore be avoided, and will oscillate under a fairly wide range of initial concentrations. For recipes suitable for demonstration purposes, see Shakhashiri or
preparations in the external links.
Terminal conditions The residual mixture contains iodinated malonic acid, inorganic acid, manganous catalysts, unreacted iodate and hydrogen peroxide. After the oscillations cease, the iodomalonic acid decomposes and iodine is produced. The rate of decomposition depends on the conditions. All of the components present in the residual mixture are of environmental concern: Iodate, iodine and hydrogen peroxide are strong oxidants, the acid is corrosive and manganese has been suggested to cause
neurological disorders. A simple method has been developed employing
thiosulfate and carbonate – two inexpensive salts – to remove all oxidants, neutralize the acidity and recover the manganous ion in the form of
manganese dioxide.
Behaviour in time The reaction shows recurring periodic changes, both gradual and sudden, which are visible: slow changes in the intensity of colour, interrupted by abrupt changes in hue. This demonstrates that a complex combination of slow and fast reactions are taking place simultaneously. For example, following the iodide ion concentration with a silver/silver iodide electrode (see ) shows sudden dramatic swings of several orders of magnitude separated by slower variations. This is shown by the oscillogram above. Oscillations persist over a wide range of temperatures. Higher temperatures make everything happen faster, with some qualitative change observable (see ). Stirring the solution throughout the reaction is helpful for sharp colour changes; otherwise spatial variations may develop (see ). Bubbles of free oxygen are evolved throughout, and in most cases, the final state is rich in free iodine. ==Variants==