# Titanite-bearing calc-silicate rocks constrain timing, duration and   magnitude of metamorphic CO2 degassing in the Himalayan belt

**Authors:** Giulia Rapa, Chiara Groppo, Franco Rolfo, Maurizio Petrelli, Pietro, Mosca, Diego Perugini

arXiv: 1812.10489 · 2018-12-31

## TL;DR

This study constrains the timing, conditions, and amount of CO2 released during Himalayan metamorphism by analyzing titanite growth and associated reactions, revealing significant metamorphic CO2 fluxes relevant to global carbon budgets.

## Contribution

It provides the first detailed characterization of metamorphic reactions producing CO2 and links titanite growth to specific PTt conditions and timing during Himalayan metamorphism.

## Key findings

- Titanite growth occurred during two main episodes at 30-26 Ma and 25-20 Ma.
- Metamorphic CO2 production ranged from 1.4 to 1.8 wt percent.
- Estimated metamorphic CO2 fluxes are comparable to modern spring water degassing rates.

## Abstract

The pressure, temperature, and timing (PTt) conditions at which CO2 was produced during the Himalayan prograde metamorphism have been constrained, focusing on the most abundant calcsilicate rock type in the Himalaya. A detailed petrological modeling of a clinopyroxene, scapolite, Kfeldspar, plagioclase, quartz, calcite calcsilicate rock allowed the identification and full characterization, for the first time, of different metamorphic reactions leading to the simultaneous growth of titanite and CO2 production. The results of thermometric determinations (Zr in Ttn thermometry) and UPb geochronological analyses suggest that, in the studied lithology, most titanite grains grew during two nearly consecutive episodes of titanite formation: a nearpeak event at 730 740 {\deg}C, 10 kbar, 30 26 Ma, and a peak event at 740 765 {\deg}C, 10.5 kbar, 25 20 Ma. Both episodes of titanite growth are correlated with specific CO2producing reactions and constrain the timing, duration and PT conditions of the main CO2producing events, as well as the amounts of CO2 produced (1.4 1.8 wt percent of CO2). A firstorder extrapolation of such CO2 amounts to the orogen scale provides metamorphic CO2 fluxes ranging between 1.4 and 19.4 Mt yr; these values are of the same order of magnitude as the presentday CO2 fluxes degassed from spring waters located along the Main Central Thrust. We suggest that these metamorphic CO2 fluxes should be considered in any future attempts of estimating the global budget of non volcanic carbon fluxes from the lithosphere.

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Source: https://tomesphere.com/paper/1812.10489