Page:EB1911 - Volume 21.djvu/497

with phosphoric acid, thus M′H₂PO₄ H₃PO₄. The three principal groups differ remarkably in their behaviour towards indicators. The mono metallic salts are strongly acid, the bimetallic are neutral or faintly alkaline, whilst the soluble trimetallic salts are strongly alkaline. The mono metallic salts of the alkalis and alkaline earths may be obtained in crystal form, but those of the heavy metals are only stable when in solution. The soluble trimetallic salts are decomposed by carbonic acid into a dimetallic salt and an acid carbonate. All soluble orthophosphates give with silver nitrate a characteristic yellow precipitate of silver phosphate, Ag₃PO₄, soluble in ammonia and in nitric acid Since the reaction with the acid salts is attended by liberation of nitric acid: NaH₂PO₄+3AgNO₃=Ag₃PO₄+NaNO₃ +2HNO₃, Na₂HPO₄+3AgNO₃=Ag₃PO₄+2N₃NO₃+HNO₃, it is necessary to neutralize the nitric acid if the complete precipitation of the phosphoric acid be desired. The three series also differ when heated: the trimetallic salts, containing fixed bases are unaltered, whilst the mono- and bimetallic salts yield meta- and pyrophosphates respectively If the heating be with charcoal, the trimetallic salts of the alkalis and alkaline earths are unaltered, whilst the mono- and di-salts give free phosphorus and a trimetallic salt. Other precipitants of phosphoric acid or its salts in solution are: ammonium molybdate in nitric acid, which gives on heating a canary-yellow precipitate of ammonium phosphomolybdate, 12[MoO₃] (NH₄)₃PO₄, insoluble in acids but readily soluble in ammonia; magnesium chloride, ammonium chloride and ammonia, which give on standing in a warm place a white crystalline precipitate of magnesium ammonium phosphate, Mg(NH₄)PO₄·6H₂O, which is soluble in acids but highly insoluble in ammonia solutions, and on heating to redness gives magnesium pyrophosphate, Mg₂P₂O₇; uranic nitrate and ferric chloride, which give a yellowish-white precipitate, soluble in hydrochloric acid and ammonia, but insoluble in acetic acid, mercurous nitrate which gives a white precipitate, soluble in nitric acid, and bismuth nitrate which gives a white precipitate, insoluble in nitric acid.

Pyrophosphoric acid, H₄P₂O₇, is a tetra basic acid which may be regarded as derived by eliminating a molecule of water between two molecules of ordinary phosphoric acid, its constitution may therefore be written (HO)₂OP O·PO(OH)₂. It may be obtained as a glassy mass, indistinguishable from meta phosphoric acid, by heating phosphoric acid to 215°. When boiled with water it forms the ortho-acid, and when heated to redness the metaacid. After neutralization, it gives a white precipitate with silver nitrate. Being a tetrabasic acid it can form four classes of salts; for example, the four solium salts Na₄P₂O₇, Na₃HP₂O₇, Na₂H₂P, O₇, NaH₃P₂O₇ are known. The most important is the normal salt, Na₄P₂O₇, which is readily obtained by heating disodium orthophosphate, Na₂HPO₄. It forms monoclinic prisms (with 10H₂O) which are permanent in air. All soluble pyrophosphates when boiled with water for a long time are converted into orthophosphates.

Metaphosphoric acid, HPO₃, is a mono basic acid which may be regarded as derived from orthophosphoric acid by the abstraction of one molecule of water, thus H₃PO₄—H₂O=HPO₃, its constitution is therefore (HO)PO₂. The acid is formed by dissolving phosphorus pent oxide in cold water, or by strongly heating orthophosphoric acid It forms a colourless vitreous mass, hence its name “glacial phosphoric acid.” It is readily soluble in water, the solution being gradually transformed into the ortho-acid, a reaction which proceeds much more rapidly on boiling Although the acid is mono basic, salts of polymeric forms exist of the types (MPO₃)_n, where n may be 1, 2, 3, 4, 6. They may be obtained by heating a mono metallic orthophosphate of a fixed base, or a bimetallic orthophosphate of one fixed and one volatile base, e.g. microcosmic salt: MH₂PO₄=MPO₃+H₂O, (NH₄) NaHPO₄= NaPO₃+NH3+H₂O; they may also be obtained by acting with phosphorus pentoxide on trimetallic orthophosphates: Na₃PO₄+P₂O₅=3NaPO₃. The salts are usually non-crystalline and fusible. On boiling their solutions they yield orthophosphates, whilst those of the heavy metals on boiling with water give a trimetallic orthophosphate and orthophosphoric acid: 3AgPO₃+3H₂O=Ag₃PO₄+2H₃PO₄. On heating with an oxide or carbonate they yield a trimetallic orthophosphate, carbon dioxide being evolved in the latter case. Metaphosphoric acid can be distinguished from the other two acids by its power of coagulating albumen, and by not being precipitated by magnesium and ammonium chlorides in the presence of ammonia.)  (C. E.*) 

Mineral Phosphates.—Those varieties of native calcium phosphate which are not distinctly crystallized, like apatite (q.v.), but occur in fibrous, compact or earthy masses, often nodular, and more or less impure, are included under the general term phosphorite. The name seems to have been given originally to the Spanish phosphorite, probably because it phosphoresced when heated. This mineral, known as Estremadura phosphate, occurs at Logrossan and Caceres, where it forms an important deposit in clay-slate. It may contain from 55 to 62% of calcium phosphate, with about 7% of magnesium phosphate. A somewhat similar mineral, forming a fibrous incrustation, with a mammillary surface, and containing about 9% of calcium carbonate, is known as staffelite, a name given by A. Stein in 1866 from the locality Staffel, in the valley of the Lower Lahn, where (as also in the valley of its tributary the Dill) large deposits of phosphorite occur. Dahllite is a Norwegian phosphorite, containing calcium carbonate, named in 1888 by W. C. Brogger and H. Bäckström after the Norwegian geologists T. and T. Dahll. Osteolite is a white earthy phosphorite occurring in the clefts of basaltic rocks, named in 1851 by J. C. Bromeis from the Greek ὀστέον, bone.

Phosphorite, when occurring in large deposits, is a mineral of much economic value for conversion into the super phosphate largely used as a fertilizing agent. Many of the impure substances thus utilized are not strictly phosphorite, but pass under such names as “rock-phosphate,” or, when nodular, as “coprolite” (q.v.), even if not of true coprolitic origin. The ultimate source of these mineral phosphates may be referred in most cases to the apatite widely distributed in crystalline rocks. Being soluble in water containing carbonic acid or organic acids it may be readily removed in solution, and may thus furnish plants and animals with the phosphates required in their structures. On the decay of these structures the phosphates are returned to the inorganic world, thus completing the cycle.

There are three sources of phosphates which are of importance geologically. They occur (a) in crystalline igneous and metamorphic rocks as an original constituent, (b) in veins associated with igneous rocks, and (c) in sedimentary rocks either as organic fragments or in secondary concretionary forms.