Machine-Learning-Assisted Segmentation of Focused Ion Beam-Scanning Electron Microscopy Images with Artifacts for Improved Void-Space Characterization of Tight Reservoir Rocks

Kazak, Andrey; Куликов, В. А.

doi:10.2118/205347-pa

Cited by 17 publications

(6 citation statements)

References 82 publications

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“…According to BP’s Energy Outlook 2030 report, North America has approximately 10 billion tons of tight oil resources, making it the region with the richest proven tight oil resources in the world . Tight oil resources are mainly distributed along the Rocky Mountains and Appalachian Mountains. − The United States is currently the most successful country in extracting tight oil . Since the comprehensive application of horizontal well staged fracturing technology in 2006, the development of tight reservoirs has promoted the recovery of the North American oil supply. − At present, the main tight oil producing areas in the United States include the Bakun Formation, Naiebral, Barnett, and Eagle Beach tight oil areas.…”

Section: Global Tight Oil Resources and Distributionmentioning

confidence: 99%

Review of the Development Status and Technology of Tight Oil: Advances and Outlook

Liu

2023

Energy Fuels

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Tight sandstone and shale oil reservoirs are one of the most promising and realistic important oil exploration fields in the 21st century. The research on the development technology of tight sandstone and shale oil reservoirs has important theoretical and practical significance for the exploration and development of tight sandstone and shale oil reservoirs in China. First, this article introduces the distribution of tight oil in the world and calculates the recoverable reserves of tight oil technology worldwide. The review also introduces the current status of tight oil exploration and development in major countries such as the United States, Canada, and China, including the distribution of tight oil resources, the main parameters of tight oil basins, and tight oil production. Second, it analyzes the current development status of tight oil in the United States, summarizes the four main factors that led to the success of tight oil exploration and development in the United States, and points out the impact of the successful development of tight oil in the United States on the global oil supply and demand relationship. Third, in the review of the main development technologies for tight oil, the current status, application, and progress of the main development technologies for tight oil are summarized and analyzed, including horizontal well drilling, fracturing and transformation technology, microscale seismic diagnosis, gas injection, and other technologies. Finally, the development examples of tight oil such as the Bakun shale in the United States are analyzed, and the application effects and experiences of horizontal well volume fracturing in regions such as the United States are summarized.

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Section: Global Tight Oil Resources and Distributionmentioning

confidence: 99%

Review of the Development Status and Technology of Tight Oil: Advances and Outlook

Liu

2023

Energy Fuels

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“…The evaluation of model performance is related to its ability to predict on hold-out test data (Hastie et al, 2017). A confusion matrix is simply a combination of the actual status and model predictions used to measure model performance (Kazak et al, 2021). It is a special table structure that enables for the evaluation of an algorithm's performance.…”

Section: Model Evaluationmentioning

confidence: 99%

A novel machine learning model for autonomous analysis and diagnosis of well integrity failures in artificial-lift production systems

Salem

Yakoot

Mahmoud

2022

Adv. Geo-Energy Res.

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“…The most common way to segment the images produced during FIB–SEM analyses is to use grayscale thresholding, which filters pixels based on their intensity: dark pixels are assumed to represent pores, while bright pixels represent solid phases. ,,, However, the inherent complexity of the coal microstructure, coupled with image noise and artifacts means that grayscale segmentation can produce poor results. ,− Three particular effects are responsible for most of the errors during segmentation: (1) the pore-back effect, which occurs when a material inside a porenot within the current plane of interestappears in the image; the effect results in the pore region having the same grayscale value as the solid phase; , (2) charging effects, which arise as a result of charge accumulation on the specimen surface; the effect is common when imaging non-conductive materials, , and can cause a significantly higher grayscale value in the pore area, giving it a similar appearance to that of a “mineral” phase; (3) curtaining effects, which occur due to ion-beam milling; , the effect generates visible stripes with grayscale values comparable to those of the pore phase, leading to incorrect segmentation as pores, particularly when a higher grayscale thresholding level is used.…”

Section: Introductionmentioning

confidence: 99%

Interactive Machine Learning Improves Accuracy of Coal Porosity Segmentation in Focused Ion Beam–Scanning Electron Microscopy Images

Yao

Emmanuel

2023

Energy Fuels

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Accurate characterization of the pore structure of coal is critical for predicting its behavior in applications, such as CO 2 storage and coal bed methane production. Focused ion beam scanning electron microscopy (FIB−SEM) is an ultra-high resolution imaging technique that is widely used to visualize the internal 3D structure of coal samples at the microscale and nanoscale. To reconstruct the pore structure, image segmentation algorithms are used to identify pores in the FIB−SEM images. However, traditional grayscale threshold segmentation can lead to significant errors due to image artifacts, including the pore-back effect, curtaining, and charging. In this study, we present a novel workflow for improving the accuracy of pore segmentation in coal that applies interactive machine learning software to FIB−SEM images. We analyzed a FIB−SEM data set for an anthracite coal sample with a vitrinite reflectance of 2.7%. We trained machine learning software (Ilastik) by manually labeling the pores in 1.25% of the 1200 images. We selected three features (intensity, edge, and texture) on different scales to train the classifier. Once trained, we then applied the classifier to the remaining images. Our results showed that the machine learning method segments the images far more accurately than grayscale segmentation: the comprehensive segmentation quality (F 1 score) of the machine learning approach (0.89−0.94) is approximately twice that of the grayscale threshold method (0.32−0.55). Crucially, relative to the machine learning method, grayscale threshold segmentation leads to estimates for porosity that are lower by up to 73%. Our results highlight the potential of using machine learning techniques to more reliably characterize the pore structure of coal and other geological materials.

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Machine-Learning-Assisted Segmentation of Focused Ion Beam-Scanning Electron Microscopy Images with Artifacts for Improved Void-Space Characterization of Tight Reservoir Rocks

Cited by 17 publications

References 82 publications

Review of the Development Status and Technology of Tight Oil: Advances and Outlook

Review of the Development Status and Technology of Tight Oil: Advances and Outlook

A novel machine learning model for autonomous analysis and diagnosis of well integrity failures in artificial-lift production systems

Interactive Machine Learning Improves Accuracy of Coal Porosity Segmentation in Focused Ion Beam–Scanning Electron Microscopy Images

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