The solubility relationships upon w

The solubility relationships upon which the two based are not sufficiently well known to permit a final conclusion at this time. The possibility that Cuz* and Fe” are combined in 3 double oxide such as cupric ferrite is of great significance in soils and merits further investigation.
Copper forms several sulfate and oxysulfate minerals shown by Reactions 8 through 12 of Table 14.1. The minerals CuSO4(chalcocyanite) and CuSO4 - 5 H 20(0) are too soluble to form in soils because they would require > l M Cu. The oxysulfate minerals are less soluble and are plotted in Fig. 14.2. These minerals decrease in solubility in the order CuO ~ CuSO4(c) >
Cu 4(()}-1) 6SQ 4. 1_3 H2O(o) > Cu4(OH)6SO4(bronehantite) > soil-Cu.
The Oxysulfate minerals are also too soluble to remain in soils and will dissolve to form soil-Cu.
The copper orthophosphates shown by Reactions 13 and 14 of table 14.1and are plotted in Fig. 14.3. Since copper in in soil is generally less abundant than Phosphorus,this plot was developed to show how Phosphorus may effect the solubility of Cu. The minerals Cu3po4 is always more stable than Cu3 po4 s as it lowers Cu by 0.63 log unit.
Details of only the dihydrate mineral are show in Fig.14.3. In this plot phosphate is fix by strengite and soil-Fe at low pH, by hydroxypatite, or DCPD with soil-Ca at intermediate pH, and by Calcite and CO2 at high pH.