THE AQUEOUS GEOCHEMISTRY OF THE RARE-EARTH ELEMENTS AND YTTRIUM .4. MONAZITE SOLUBILITY AND REE MOBILITY IN EXHALATIVE MASSIVE SULFIDE-DEPOSITING ENVIRONMENTS
Sa. Wood et Ae. Williamsjones, THE AQUEOUS GEOCHEMISTRY OF THE RARE-EARTH ELEMENTS AND YTTRIUM .4. MONAZITE SOLUBILITY AND REE MOBILITY IN EXHALATIVE MASSIVE SULFIDE-DEPOSITING ENVIRONMENTS, Chemical geology, 115(1-2), 1994, pp. 47-60
Although there is considerable evidence that rare-earth elements (REE)
, and particularly the light REE (LREE), have been mobile in the alter
ation zones below many massive sulfide deposits, there is some disagre
ement over the cause of this mobility. Most researchers have argued or
implied that the REE were mobilized by analogues of modern seafloor h
ydrothermal vent fluids. However, the few measurements that have been
made of the REE concentrations of these modern fluids suggest that the
ir ability to mobilize REE is negligible. In order to shed further lig
ht on this problem we have carried out calculations of monazite solubi
lity (monazite is thought to be the principal host for the LREE) in a
model vent fluid at temperatures from 200-degrees to 300-degrees-C. Th
ese calculations show that at 300-degrees-C the model fluid will conta
in 0.08 ppb Ce, 0.07 ppb La and 0.03 ppb Nd. At 200-degrees-C the conc
entrations increase to 0.54 ppb, 0.37 ppb and 0.15 ppb, respectively.
A decrease in pH of one unit at 300-degrees-C also increases REE solub
ility significantly (7.4 ppb Ce, 5.7 ppb La and 1.1 ppb Nd). These sol
ubilities are similar to the concentrations of REE measured in seafloo
r hydrothermal vent fluids. However, they are considerably lower than
required to account for the scale of REE mobility in alteration zones
associated with massive sulfide deposits. If the mass ratio of typical
hydrothermal vent fluid to rock reached 1000, concentrations of REE i
n the altered rock are predicted to be in the range < 1 ppm to several
ppm, whereas REE depletions up to several tens of ppm and enrichments
in excess of 1000 ppm have been reported. Our calculations thus sugge
st that ancient analogues of modern seafloor hydrothermal vent fluids
could not have transported REE in the quantities required to explain t
he extent of REE mobility documented for alteration zones associated w
ith massive sulfide deposits. This finding requires that either ancien
t massive sulfide-forming hydrothermal systems were different in some
critical respect from modem seafloor hydrothermal systems or that REE
enrichment/depletion occurred during later metamorphism or alteration
of massive sulfide deposits.