Journal of Petrology
Stephen M. Wickham , Amy D. Alberts , Ada N. Zanvilevich , Boris A. Litvinovsky,
Ilya N. Bindeman, and Edwin A. Schauble
ABSTRACT
A stable isotope study of 168 plutonic igneous rock and 5 water samples from
Transbaikalia, East Asia has been made, including 318 whole rock and mineral
18O/16O analyses and 14 D/H analyses. This represents the first detailed isotopic
study of the enormous Phanerozoic K-rich (mostly anorogenic) granitoid belts
of this region which are thousands of kilometers in length and span an age range
of >250 Ma. Of the five main intrusive suites, emplacement of the youngest (Permo-Triassic)
was accompanied by intense meteoric-hydrothermal activity, locally causing extreme
18O-depletion (d18Ofeldspar < -12). This reflects the very low d18O of the water
involved in these systems, which probably had d18O < -20 and dD < -150, consistent
with the high paleolatitude of Transbaikalia in the early Mesozoic (~80°ree;N).
Despite local post-emplacement, hydrothermal 18O-depletion effects near Permo-Triassic
and younger plutons, the variation of magmatic isotopic composition in the five
intrusive suites, in space and time, can be clearly discerned using the 18O/16O
variation in phases such as quartz and sphene that are resistant to sub-solidus
exchange. A procedure for analyzing 18O/16O in sphene using a laser fluorination
technique is described: analysis of samples as small as 0.4 mg (including single
crystals of sphene from granitoids) is possible and provides an effective way
to estimate the magmatic d18O value of plutonic igneous rocks. Most sphene and
quartz d18O values vary by 1.0 to 2.0%o within each of the five main intrusive
suites in Transbaikalia (ranging in age from mid-Paleozoic to Mesozoic) and
are uniform both within individual plutons and among plutons of the same suite
separated by tens or hundreds of kilometers. However, each suite has a unique
range in 18O/16O, indicating that on a regional scale, the magmatic d18O values
of these granitoids decreased progressively in ~1 per mil decrements from ~+10
in the earliest group to ~+6 in the youngest. This progression was accompanied
by increases in the concentration of elements such as K and Zr, and decreases
in the concentration of elements such as Sr and B. These systematics require
large-scale deep crustal melting and mixing processes in order to generate the
compositional uniformity of individual plutons and groups over such wide areas,
and also a progressive hybridization of the crust with alkalic, mantle-derived
magmas in order to generate syenites and granites with progressively lower d18O
values. This process may be a hallmark of anorogenic granitoid petrogenesis
and the intracontinental cratonization process in general, and also represents
an important (though largely cryptic) crustal growth mechanism.
Key words
anorogenic granitoids;crustal growth;hybridization;hydrothermal systems;stable
isotopes
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