Automated Seafloor Massive Sulfide Detection Through Integrated Image Segmentation and Geophysical Data Analysis: Revisiting the TAG Hydrothermal Field

Amir Haroon; Hendrik Paasche; Sebastian Graber; Sven Petersen; Eric Attias; Marion Jegen; Romina Gehrmann; Sebastian Hölz; Meike Klischies

doi:10.1029/2023GC011250

Geochemistry, Geophysics, Geosystems (Dec 2023)

Automated Seafloor Massive Sulfide Detection Through Integrated Image Segmentation and Geophysical Data Analysis: Revisiting the TAG Hydrothermal Field

Amir Haroon,
Hendrik Paasche,
Sebastian Graber,
Sven Petersen,
Eric Attias,
Marion Jegen,
Romina Gehrmann,
Sebastian Hölz,
Meike Klischies

Affiliations

Amir Haroon: Helmholtz Centre for Ocean Research GEOMAR Kiel Kiel Germany
Hendrik Paasche: UFZ Helmholtz Centre for Environmental Research Leipzig Germany
Sebastian Graber: Helmholtz Centre for Ocean Research GEOMAR Kiel Kiel Germany
Sven Petersen: Helmholtz Centre for Ocean Research GEOMAR Kiel Kiel Germany
Eric Attias: Institute for Geophysics Jackson School of Geosciences The University of Texas at Austin Austin TX USA
Marion Jegen: Helmholtz Centre for Ocean Research GEOMAR Kiel Kiel Germany
Romina Gehrmann: Defence Research and Development Canada Dartmouth NS Canada
Sebastian Hölz: Helmholtz Centre for Ocean Research GEOMAR Kiel Kiel Germany
Meike Klischies: Helmholtz Centre for Ocean Research GEOMAR Kiel Kiel Germany

DOI: https://doi.org/10.1029/2023GC011250
Journal volume & issue: Vol. 24, no. 12
pp. n/a – n/a

Abstract

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Abstract Accessible seafloor minerals located near mid‐ocean ridges are noticed to mitigate the projected metal demands of the net‐zero energy transition, promoting growing interest in quantifying the global distributions of seafloor massive sulfides (SMS). Mineral potentials are commonly estimated using geophysical and geological data that lastly rely on additional confirmation studies using sparsely available, locally limited, seafloor imagery, grab samples, and coring data. This raises the challenge of linking in situ confirmation data to geophysical data acquired at disparate spatial scales to obtain quantitative mineral predictions. Although multivariate data sets for marine mineral research are incessantly acquired, robust, integrative data analysis requires cumbersome workflows and experienced interpreters. We introduce an automated two‐step machine learning approach that integrates the mound detection through image segmentation with geophysical data. SMS predictors are subsequently clustered into distinct classes to infer marine mineral potentials that help guide future exploration. The automated workflow employs a U‐Net convolutional neural network to identify mound structures in bathymetry data and distinguishes different mound classes through the classification of mound architectures and magnetic signatures. Finally, controlled source electromagnetic data are utilized together with in situ sampling data to reassess predictions of potential SMS volumes. Our study focuses on the Trans‐Atlantic Geotraverse area, which is among the most explored SMS areas worldwide and includes 15 known SMS sites. The automated workflow classifies 14 of the 15 known mounds as exploration targets of either high or medium priority. This reduces the exploration area to less than 7% of the original survey area from 49 to 3.1 km2.

Published in Geochemistry, Geophysics, Geosystems

ISSN: 1525-2027 (Online)
Publisher: Wiley
Country of publisher: United States
LCC subjects: Science: Physics: Geophysics. Cosmic physics; Science: Geology
Website: https://agupubs.onlinelibrary.wiley.com/journal/15252027

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