A SIMPLE 3-DIMENSIONAL MODEL OF DIFFUSION-WITH-PRECIPITATION APPLIED TO LOCALIZED PYRITE FORMATION IN FRAMBOIDS, FOSSILS AND DETRITAL IRON MINERALS

A three-dimensional diffusion-with-precipitation model is constructed to estimate radial variations in the amounts of pyrite which precipita te where a spherical mass of organic matter, producing H2S by sulphate reduction, is enveloped in a dissolved-iron bearing porewater. The mo del indicates that higher rates of sulphate reduction (more readily me tabolisable organic matter), and larger organic masses, require increa singly high dissolved iron concentrations in order to confine pyrite ( or iron sulphide) precipitation to the decay site. The maximum size sp here of exceedingly metabolisable organic matter (equivalent to fresh planktonic material) which can be pyritised is about 50 mum radius, wh ere decay occurs in porewaters with typical dissolved iron levels. Thi s radius is close to the maximum radius of framboidal pyrite, the form ation of which could involve model-type processes. Fossil carcases, al though mainly composed of less readily metabolisable organic matter, m ay be orders of magnitude larger and the model demonstrates that their pyritisation requires unusually high porewater dissolved iron concent rations. These inferred chemical conditions are consistent with sedime ntological observations of pyritisation in Beecher's Trilobite Bed (Ne w York State). At greater depths within the sediment, pyritisation is controlled by the kinetics of iron mineral reactivity towards H2S. Sed iments vary widely in their exposure times to H2S which can range at l east from 50 to > 10(6) years. At low exposure times only iron oxides are pyritised, whereas at high exposure times even the most refractory iron silicates can become pyritised.