Storage of carbon by the Himalaya: the importance of organic carbon unveiled
An international team, led by IPGP researchers, has looked into organic carbon stored as graphite in the Nepal Himalaya, whose importance as compared with well-known carbonates for the global carbon budget of the chain remains poorly understood. Studying this stored graphite is essential to better estimate the carbon sink/source duality of large orogens and its associated effects on Earth’s climate.
While carbonates represent the major storage of inorganic carbon in large mountain belts, organic carbon stored as graphite may have a substantial contribution. Although fundamental to define the global carbon budget of orogens such as the Himalaya which also exhibits metamorphic carbon release as carbon dioxide (CO2), the importance of the storage of graphite remains insufficiently constrained.
An international team, led by IPGP researchers and composed of researchers from ENS (PSL Research University/CNRS), CRPG (Lorraine University/CNRS), the University of Turin (UniTO /CNR-IGG) in Italy, the Central Department of Geology of the Tribhuvan University and the Department of Mines and Geology (DMG) in Nepal, has analyzed extensively graphite occurrences within the so-called black schists in the Nepal Himalaya using numerous well-established and novel techniques, and estimated the contribution of organic carbon to the global carbon budget.
The results show the significant coherence of metamorphic conditions for the graphitic black schists in the vicinity of the Main Central Thrust zone from the metric scale to the scale of an 800-km-long lateral portion of the Himalaya. The total organic carbon (TOC) content and the temperature attained by metamorphism (peak-T) are consistent, suggesting a similar thermal history of these graphitic rocks.
First-order extrapolations reveal that organic carbon may represent up to 20 % of the total amount of carbon stored by the Nepal Himalaya. Graphite is more stable than carbonates during prograde metamorphism and remains passively stable, not involving CO2 producing and consuming reactions. Higher TOC content and peak-T are reported in Central Nepal, where the current metamorphic CO2 emission is also the highest. The graphitic black schists emerge as remarkable signs of the carbon sink/source duality of the Himalayan orogeny and its associated effects on Earth’s climate.
References:
Thapa, S., Girault, F., Deldicque, D., Losno, R., France-Lanord, C., Groppo, C., Rolfo, F., Tamang, S., Rigaudier, T., Debret, B., Paudyal, K.R., Adhikari, L.B., Perrier, F., 2023. Metric, kilometric and large-scale coherence of metamorphic conditions from graphitic phyllite in the Upper Lesser Himalaya of Nepal: Contribution to the estimation of carbon stored during Himalayan orogeny. Chem. Geol., 121378,
https://doi.org/10.1016/j.chemgeo.2023.121378