Abstract
Since water is only composed of oxygen and hydrogen, δ18O and δ2H values are thus utilized to trace the origin of water(s) and quantify the water-rock interactions. While Triassic high pressure (HP) and ultrahigh pressure (UHP) metamorphic rocks across the Dabie-Sulu orogen in central-eastern China have been well documented, postcollisional magmatism driven hydrothermal systems are little known. Here we show that two sources of externally derived water interactions were revealed by oxygen isotopes for the gneissic country rocks intruded by the early Cretaceous postcollisional granitoids. Inverse modellings indicate that the degree of disequilibrium (doD) of meteoric water interactions was more evident than that of magmatic one (−65 ± 1o vs. −20 ± 2°); the partial reequilibration between quartz and alkali feldspar oxygen isotopes with magmatic water was achieved at 340 °C with a water/rock (W/R) ratio of about 1.2 for an open-hydrothermal system; two-stage meteoric water interactions were unraveled with reequilibration temperatures less than 300 °C and W/R ratios around 0.4. The lifetime of fossil magmatic hydrothermal system overprinted on the low zircon δ18O orthogneissic country rocks was estimated to maintain up to 50 thousand years (Kyr) through oxygen exchange modellings. Four-stage isotopic evolutions were proposed for the magmatic water interacted gneiss.
Highlights
Zircon δ18O values with quartz and alkali feldspar data from the same set of samples were analyzed via laser fluorination online techniques (Methods and Table S1)
Some of the alkali feldspar δ18O values of granitoids steeply shift toward low values and depart from equilibrium isotherms, indicating low δ18O water interactions
It is of particular interests that the remarkable disequilibria and even reversals are evident between zircon and alkali feldspar and between zircon and quartz δ18O values for these gneissic country rocks
Summary
Two gneisses from the Sidaohe without intruding granitoids in the Hong’an Block were studied. Fresh medium-grained granitoids and gneisses were collected from quarries and/or along road cuttings. Quartz, feldspar, biotite, and sometimes amphibole are major rock-forming minerals, and accessory minerals include zircon and magnetite. Zircon δ18O values with quartz and alkali feldspar data from the same set of samples were analyzed via laser fluorination online techniques (Methods and Table S1)
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call