[84] If sodium iodate be mixed with a solution of sodium hydroxide, heated, and chlorine passed through the solution, a sparingly soluble salt separates out, which corresponds with periodic acid, and has the composition Na₄I₂O₉,3H₂O.

6NaHO + 2NaIO₃ + 4Cl = 4NaCl + Na₄I₂O₉ + 3H₂O.

This compound is sparingly soluble in water, but dissolves easily in a very dilute solution of nitric acid. If silver nitrate be added to this solution a precipitate is formed which contains the corresponding compound of silver, Ag₄I₂O₉,3H₂O. If this sparingly soluble silver compound be dissolved in hot nitric acid, orange crystals of a salt having the composition AgIO₄ separate on evaporation. This salt is formed from the preceding by the nitric acid taking up silver oxide—Ag₄I₂O_9 + 2HNO₃ = 2AgNO₃ + 2AgIO₄ + H₂O. The silver salt is decomposed by water, with the re-formation of the preceding salt, whilst iodic acid remains in solution—

4AgIO₄ + H₂O = Ag₄I₂O₉ + 2HIO₄.

The structure of the first of these salts, Na₄I₂O₉,3H₂O, presents itself in a simpler form if the water of crystallisation is regarded as an integral portion of the salt; the formula is then divided in two, and takes the form of IO(OH)₃(ONa)₂—that is, it answers to the type IOX₅, or IX₇, like AgIO₄ which is IO₃(OAg). The composition of all the salts of periodic acids are expressed by this type IX₇. Kimmins (1889) refers all the salts of periodic acid to four types—the meta-salts of HIO₄ (salts of Ag, Cu, Pb), the meso-salts of H₃IO₅ (PbH, Ag₂H, CdH), the para-salts of H₅IO₆ (Na₂H₃, Na₃H₂), and the di-salts of H₄I₂O₉ (K₄, Ag₄, Ni₂). The three first are direct compounds of the type IX₇, namely, IO₃(OH), IO₂(OH)₃, and IO(OH)₅, and the last are types of diperiodic salts, which correspond with the type of the meso-salts, as pyrophosphoric salts correspond with orthophosphoric salts—i.e. 2H₃IO₅-H₂O = H₄I₂O₉.

[85] Periodic acid, discovered by Magnus and Ammermüller, and whose salts were afterwards studied by Langlois, Rammelsberg, and many others, presents an example of hydrates in which it is evident that there is not that distinction between the water of hydration and of crystallisation which was at first considered to be so clear. In HClO,2H₂O the water, 2H₂O, is not displaced by bases, and must be regarded as water of crystallisation, whilst in HIO₄,2H₂O it must be regarded as water of hydration. We shall afterwards see that the system of the elements obliges us to consider the halogens as substances giving a highest saline type, GX₇, where G signifies a halogen, and X oxygen (O = X₂), OH, and other like elements. The hydrate IO(OH)₅ corresponding with many of the salts of periodic acid (for example, the salts of barium, strontium, mercury) does not exhaust all the possible forms. It is evident that various other pyro-, meta-, &c., forms are possible by the loss of water, as will be more fully explained in speaking of phosphoric acid, and as was pointed out in the preceding note.

[86] With respect to hydrogen, oxygen, chlorine, and other elements, bromine occupies an intermediate position between chlorine and iodine, and therefore there is no particular need for considering at length the compounds of bromine. This is the great advantage of a natural grouping of the elements.

[87] They were both obtained by Gay-Lussac and many others. Recent data respecting iodine monochloride, ICl, entirely confirm the numerous observations of Trapp (1854), and even confirm his statement as to the existence of two isomeric (liquid and crystalline) forms (Stortenbeker). With a small excess of iodine, iodine monochloride remains liquid, but in the presence of traces of iodine trichloride it easily crystallises. Tanatar (1893) showed that of the two modifications of ICl, one is stable, and melts at 27°; while the other, which easily passes into the first, and is formed in the absence of ICl₃, melts at 14°. Schützenberger amplified the data concerning the action of water on the chlorides (Note [88]), and Christomanos gave the fullest data regarding the trichloride.

After being kept for some time, the liquid monochloride of iodine yields red deliquescent octahedra, having the composition ICl₄, which are therefore formed from the monochloride with the liberation of free iodine, which dissolves in the remaining quantity of the monochloride. This substance, however, judging by certain observations, is impure iodine trichloride. If 1 part of iodine be stirred up in 20 parts of water, and chlorine be passed through the liquid, then all the iodine is dissolved, and a colourless liquid is ultimately obtained which contains a certain proportion of chlorine, because this compound gives a metallic chloride and iodate with alkalis without evolving any free iodine: ICl₅ + 6KHO = 5KCl + KIO₃ + 3H₂O. The existence of a pentachloride ICl₅ is, however, denied, because this substance has not been obtained in a free state.

Stortenbeker (1888) investigated the equilibrium of the system containing the molecules I₂, ICl, ICl₃, and Cl₂, in the same way that Roozeboom (Chapter X. Note [38]) examined the equilibrium of the molecules HCl, HCl,2H₂O, and H₂O. He found that iodine monochloride appears in two states, one (the ordinary) is stable and melts at 27°·2, whilst the other is obtained by rapid cooling, and melts at 13°·9, and easily passes into the first form. Iodine trichloride melts at 101° only in a closed tube under a pressure of 16 atmospheres.