Your search keyword '"bepress|Physical Sciences and Mathematics|Earth Sciences|Geology"' showing total 2 results

1. Stratigraphic modeling of the Western Taiwan foreland basin: Sediment flux from a growing mountain range and tectonic implications

Author

Didier Granjeon, Stefan Nagel, Sean D. Willett, Andrew Lin, Sébastien Castelltort, Geological Institute [ETH Zürich], Department of Earth Sciences [Swiss Federal Institute of Technology - ETH Zürich] (D-ERDW), Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich)- Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), IFP Energies nouvelles (IFPEN), National Central University [Taiwan] (NCU), and University of Geneva [Switzerland]

Subjects

bepress|Physical Sciences and Mathematics, Arc-continent collision, bepress|Physical Sciences and Mathematics|Earth Sciences|Sedimentology, 010504 meteorology & atmospheric sciences, Stratigraphy, Taiwan, bepress|Physical Sciences and Mathematics|Earth Sciences, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Stratigraphy, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences, Structural basin, Foreland basin, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Stratigraphic modeling, Paleontology, ddc:550, Physical Sciences and Mathematics, 14. Life underwater, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Sedimentology, Sea level, 0105 earth and related environmental sciences, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Geology, bepress|Physical Sciences and Mathematics|Earth Sciences|Geology, Sediment, Geology, Sedimentology, Sedimentation, bepress|Physical Sciences and Mathematics|Earth Sciences|Stratigraphy, EarthArXiv|Physical Sciences and Mathematics, Tectonics, Geophysics, Erosion, 13. Climate action, Earth Sciences, Economic Geology, Tectonic sedimentology, Sediment transport

Abstract

International audience; Sediment flux signals from source to sink in foreland basins preserve a record of tectonics, sea level and climate through erosion and sedimentation. However, longitudinal sediment transport often occurs in foreland basins, thus removing part of the orogenic material flux from foreland basin records. Here we use mass balance calculation and stratigraphic simulations of sediment fluxes for the Taiwan orogen to provide an order of magnitude estimate of how much orogenic material may bypass a foreland basin. Our results indicate a significant, potentially more than 50%, mismatch between sediment volume currently preserved in the basin and the amount of material presumably eroded from the orogen since the onset of collision in Taiwan. This suggests either a significant overestimation of average erosion rates over the period concerned with orogenic development of Taiwan, or it supports previous paleogeographic work suggesting that longitudinal sediment transport in the paleo-Taiwan Strait served as a major bypass conduit of importance for the establishment of a steady state orogen. We identify candidate submarine topography in the South China Sea that may preserve Taiwan's missing erosional mass.

Published

2018

2. Fully automated carbonate petrography using deep convolutional neural networks

Author

Daniel J. Lehrmann, Khalid Al-Ramadan, Michele Morsilli, Ardiansyah Koeshidayatullah, and Jonathan L. Payne

Subjects

bepress|Physical Sciences and Mathematics|Earth Sciences|Paleontology, bepress|Physical Sciences and Mathematics, bepress|Physical Sciences and Mathematics|Earth Sciences|Sedimentology, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Paleobiology, 010504 meteorology & atmospheric sciences, Stratigraphy, bepress|Physical Sciences and Mathematics|Earth Sciences, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Convolutional neural network, NO, petrography, Petrography, carbonate, chemistry.chemical_compound, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Sedimentology, 0105 earth and related environmental sciences, bepress|Physical Sciences and Mathematics|Computer Sciences|Artificial Intelligence and Robotics, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Geology, Contextual image classification, business.industry, bepress|Physical Sciences and Mathematics|Earth Sciences|Geology, Deep learning, EarthArXiv|Physical Sciences and Mathematics|Computer Sciences|Artificial Intelligence and Robotics, bepress|Physical Sciences and Mathematics|Computer Sciences, EarthArXiv|Physical Sciences and Mathematics|Computer Sciences, deep learning, object detection, Geology, Pattern recognition, Automated analysis, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Paleontology, Object detection, EarthArXiv|Physical Sciences and Mathematics, bepress|Physical Sciences and Mathematics|Earth Sciences|Paleobiology, machine learning, Geophysics, chemistry, Carbonate, Carbonate rock, Economic Geology, Artificial intelligence, F1 score, business, Automated analysis, carbonate, deep learning, machine learning, object detection, petrography

Abstract

Carbonate rocks are important archives of past ocean conditions as well as hosts of economic resources such as hydrocarbons, water, and minerals. Geologists typically perform compositional analysis of grain, matrix, cement and pore types in order to interpret depositional environments, diagenetic modification, and reservoir quality of carbonate strata. Such information can be obtained primarily from petrographic analysis, a task that is costly, labor-intensive, and requires in-depth knowledge of carbonate petrology and micropaleontology. Recent studies have leveraged machine learning-based image analysis, including Deep Convolutional Neural Networks (DCNN), to automate description, classification and interpretation of thin sections, subsurface core images and seismic facies, which would accelerate data acquisition and reproducibility for these tasks. In carbonate rocks, this approach has been applied primarily to recognize carbonate lithofacies, and no attempt has been made to individually identify and quantify various types of carbonate grains, matrix, and cement. In this study, the applicability and performance of DCNN-based object detection and image classification approaches are assessed with respect to carbonate compositional analysis. The training data comprised of more than 13,000 individually labelled objects from nearly 4000 carbonate petrographic images. The dataset is grouped into six and nine different classes for the image classification and object detection tasks, respectively. Even with a small and relatively imbalanced training set, the DCNN was able to achieve an F1 score of 92% for image classification and 84% mean precision for object detection by combining one-cycle policy, class weight, and label mixup-smoothing methods. This study highlights the inefficiency of image classification as an approach to replicating human description and classification of carbonate petrography. By contrast, DCNN-based object detection appears capable of approaching human speed and accuracy in the area of carbonate petrography because it is able to individually locate and identify different carbonate components with greater cost-efficiency, speed, and reproducibility than conventional (human) petrographic analysis.

Published

2020