Monday, July 10, 2023

The long-neglected ultraslow spreading Southwest Indian Ocean Ridge not only develops diverse types of hydrothermal systems but also has the potential to form large polymetallic deposits


Peer-Reviewed Publication

SCIENCE CHINA PRESS

Schematic diagram of eHeat-dFault sulfide metallogenic model for SWIR 

IMAGE: THE DIAGRAM ILLUSTRATES THE TWO MAIN TYPES (INTENSE MAGMA SUPPLY TYPE AND TECTONIC CONTROL TYPE) OF METALLOGENIC MODELS ALONG THE SPREADING AXIS OF A MID-OCEAN RIDGE, WITH THE TECTONIC CONTROL TYPE FURTHER DIVIDED INTO ONE-WAY DETACHMENT CONTROL AND FLIP-FLOP DETACHMENT CONTROL. view more 

CREDIT: ©SCIENCE CHINA PRESS


The research findings of Dr. Tao Chunhui, a senior researcher from the Second Institute of Oceanography, Ministry of Natural Resources, were published in Science China: Earth Sciences. Over a decade, Dr. Tao's research team conducted investigations into the distribution patterns and formation mechanisms of hydrothermal activities and associated polymetallic sulfides in the Southwest Indian Ridge (SWIR). They discovered a diverse range of hydrothermal activities with higher frequency and the potential for forming large-scale sulfide mineral deposits than what expected by previous theoretical model. The team also established a sulfide metallogenic model controlled by local enhanced heat supply and deep faults (eHeat-dFault model).

Submarine polymetallic sulfides have significant economic value and are primarily formed through hydrothermal circulation. The two key elements of hydrothermal circulation are the driving heat source and fluid circulation pathways. Through analysis of submarine seismic data, it was found that the driving heat source of the hydrothermal system in the SWIR exhibits local enhanced characteristics, and the depth of the heat source and circulation conduit structures are deeper compared to similar hydrothermal systems in other ridges. These characteristics are mainly manifested in deep magma chambers in the strong magmatic segment, deep detachment faults in the weak magmatic segment, and flip-flop detachment faults in the amagmatic segment. It is commonly believed that the spreading rate controls heat source, magma supply, and tectonic processes. However, this study suggests that the type of hydrothermal circulation system, circulation depth, frequency of hydrothermal activity along the axis, and the scale of sulfide mineralization may be the result of a balance between magma supply and tectonic activity.

For the ultraslow spreading SWIR, local enhanced heat supply and deep fault structures are more direct controlling factors for hydrothermal circulation and sulfide mineralization. The eHeat-dFault sulfide metallogenic model is expected to provide guidance for the exploration and mineralization research of polymetallic sulfides on the ultraslow spreading SWIR.

See the article:

Tao C, Guo Z, Liang J, Ding T, Yang W, Liao S, Chen M, Zhou F, Chen J, Wang N, Liu X, Zhou J. 2023. Sulfide metallogenic model on the ultraslowspreading Southwest Indian Ridge. Science China Earth Sciences, 66(6): 1212–1230, https://doi.org/10.1007/s11430-023-1108-7

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