Study reveals intense CO2 degassing process in magmas

The Okinawa Trough is a newly formed back-arc basin located in the outer margin of the continental shelf of the East China Sea. The submarine hydrothermal activities are widely developed in the Okinawa Trough. A typical feature of the basin is that the hydrothermal fluids are highly rich in CO₂.

An increasing number of studies suggest that CO₂ in hydrothermal fluids may come directly from magmatic degassing. However, the process of CO₂ degassing in the Okinawa Trough magmas is poorly understood, and it is unclear whether the magma can release enough CO₂ into the hydrothermal system.

Recently, Dr. Zhang Yuxiang of Prof. Zeng Zhigang’s team from the Institute of Oceanology of the Chinese Academy of Sciences (IOCAS), in collaboration with Prof. Glenn Gaetani from the Woods Hole Oceanographic Institution, selected volcanic rock samples from the areas near the hydrothermal fields of the southern Okinawa Trough, analyzed the volatile compositions (CO₂, H₂O, S, F, Cl) in mineral-hosted melt inclusions and matrix glass using ion probe, and discussed the process of magmatic degassing.

The study was published in Lithos on March 23.

The researchers found that the CO₂ contents in the matrix glass and some of the melt inclusions were very low (2 contents positively correlated with water contents, and the CO₂ contents in the matrix glass were even lower than the instrumental detection limit (2 came from leaching the basement rocks. On the other hand, it suggested the magma had experienced an intense CO₂ degassing process.

They estimated that at this level of CO₂ degassing, 1 km³ of magma could support a high CO₂ flux of hydrothermal vents for more than 500 years. Therefore, from the perspective of magmatic degassing, this study illustrates that magma is an important potential source of CO₂ for hydrothermal system.

The researchers also found that the magma in the Okinawa Trough also underwent a certain degree of S degassing, but the halogens (F and Cl) did not change significantly during the magma degassing.

“These understandings can provide research support for investigating the material correlation between the magmatic system and the hydrothermal system in the subduction zone,” said Dr. Zhang, first author of the study.

In addition, melt inclusion analysis and plagioclase hydrometer were combined to estimate magma water content and its variation from the modern arc front to the back-arc spreading centers. Together with data from the Mariana and Tonga subduction zones and the mid-ocean ridge basalts, a good positive correlation between H₂O/Ce and boron isotope (δ¹¹B) were established for volcanic rocks in subduction zones.

Boron isotope is an effective indicator of subducted serpentine, which is very rich in water and is considered an important source of fluid in subduction zone. This correlation also indicates that fluids derived from subducted serpentine have an important contribution to the water budget of arc magma.