MIGRATION OF RADIOGENIC LEAD ISOTOPES DURING FORMATION OF MINERALS IN OPEN CAVITIES IN THE PRESENCE OF COLLOIDS: THEORETICAL ASPECTS AS APPLIED TO U-Pb DATING OF YOUNG MINERALS
S.E. Pashchenko and Yu.V. Dublyansky*
Institute of Chemical Kinetics and Combustion, Siberian Branch of the RAS, 3 ul. Institutskaya, Novosibirsk, 630090, Russia * Institute of Mineralogy and Petrography, Siberian Branch of the RAS, 3 prosp. Koptyuga, Novosibirsk, 630090, Russia
Keywords: Opal, lead, radon, colloids, coagulation, U-Pb dating
Pages: 203-217
Abstract
A semi-empirical model is presented, which describes the processes of formation, migration, and accumulation of radiogenic lead (PbRn) in opals deposited in open cavities. In contrast to lead that forms in situ through radioactive decay of uranium trapped by opal, PbRn is produced from uranium disseminated in the rock enclosing the cavities. Its incorporation into the opal is described by the following chain of processes: decay of parental uranium to yield radon - emanation and diffusion migration of radon from the rock into the cavity - decay of radon to yield lead - diffusion migration of lead in the cavity - adsorption of lead on colloidal silica particles - coagulation and settling of the colloidal particles - formation of opal. Besides the colloidal adsorption, PbRn can also be incorporated into the growing opal through direct diffusion flow onto its surface. The latter mechanism is also relevant to minerals crystallizing from ionic solutions; it is less efficient than the mechanism of colloidal adsorption. Distribution of PbRn isotopes throughout a cavity depends on the cavity geometry and the half-life of the parental Rn isotope. In cavity filled with stagnant water, the concentration profiles of PbRn show maxima at some distance from the cavity wall. The movement of water through a cavity leads to a more complex distribution of PbRn isotopes. The model describes accumulation of PbRn on silica micelles during their growth until the critical size of coagulation (5-10 nm) is reached and during the subsequent coagulation. For micelles 5-50 nm in size, the calculated concentrations of PbRn agree with those in young (Miocene and younger) natural opals. Opals formed in open cavities in acidic volcanic rocks (with U = 4-5 ppm) can trap significant amounts of PbRn. Applying standard U-Pb dating equations, which ignore PbRn, will yield an overestimated age of such opals. This is true for young opals (younger than ≈30 Ma). As the age of opal increases, the share of radiogenic Pb formed in situ also grows, and the PbRn correction becomes negligible.
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