Abstract
The Mid-Atlantic Ridge belongs to slow-spreading ridges. Hannington predicted that there were a large number of mineral resources on slow-spreading ridges; however, seafloor massive sulfide deposits usually develop thousands of meters below the seafloor, which make them extremely difficult to explore. Therefore, it is necessary to use mineral prospectivity mapping to narrow the exploration scope and improve exploration efficiency. Recently, Fang and Shao conducted mineral prospectivity mapping of seafloor massive sulfide on the northern Mid-Atlantic Ridge, but the mineral prospectivity mapping of magmatic-related seafloor massive sulfide on the whole Mid-Atlantic Ridge scale has not yet been carried out. In this study, 11 types of data on magmatic-related seafloor massive sulfide mineralization were collected on the Mid-Atlantic Ridge, namely water depth, slope, oceanic crust thickness, large faults, small faults, ridge, bedrock age, spreading rate, Bouguer gravity, and magnetic and seismic point density. Then, the favorable information was extracted from these data to establish 11 predictive maps and to create a mineral potential model. Finally, the weights-of-evidence method was applied to conduct mineral prospectivity mapping. Weight values indicate that oceanic crust thickness, large faults, and spreading rate are the most important prospecting criteria in the study area, which correspond with important ore-controlling factors of magmatic-related seafloor massive sulfide on slow-spreading ridges. This illustrates that the Mid-Atlantic Ridge is a typical slow-spreading ridge, and the mineral potential model presented in this study can also be used on other typical slow-spreading ridges. Seven zones with high posterior probabilities but without known hydrothermal fields were delineated as prospecting targets. The results are helpful for narrowing the exploration scope on the Mid-Atlantic Ridge and can guide the investigation of seafloor massive sulfide resources efficiently.
Highlights
Due to increasing demand, mineral resources on land are depleting
Compared with mineral resources on land, due to the limitations of physical conditions and techniques, very little exploration has been done on seafloor massive sulfides; data related to their mineralization are limited
The above results can provide a basis for reducing the exploration scope; the mineral prospectivity mapping of magmatic-related seafloor massive sulfides has not been conducted for the entire Mid-Atlantic Ridge
Summary
Mineral resources on land are depleting. the progress of deep-sea exploration techniques has made exploration of seafloor mineral resources a popular research subject [1]. In the 21st century, the development of big data has provided a new way to quantitatively predict the locations of seafloor massive sulfides. Compared with mineral resources on land, due to the limitations of physical conditions and techniques, very little exploration has been done on seafloor massive sulfides; data related to their mineralization are limited. The above results can provide a basis for reducing the exploration scope; the mineral prospectivity mapping of magmatic-related seafloor massive sulfides has not been conducted for the entire Mid-Atlantic Ridge. By comparing prediction maps with high weight values in the study area to important ore-forming factors on slowspreading ridges, we determined that the Mid-Atlantic Ridge is a typical slow-spreading ridge. 7 prospecting targets with high posterior probabilities were delineated, which provide a basis for the exploration of magmatic-related seafloor massive sulfides on the Mid-Atlantic Ridge
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