Min Jun Park, Julio Frigerio, Bob Clapp, Biondo Biondi
{"title":"DeepNRMS:在延时地震图像中进行无监督深度学习以监测不含噪声的二氧化碳含量","authors":"Min Jun Park, Julio Frigerio, Bob Clapp, Biondo Biondi","doi":"10.1190/geo2023-0608.1","DOIUrl":null,"url":null,"abstract":"Monitoring stored <span><math display=\"inline\" overflow=\"scroll\"><mrow><msub><mi>CO</mi><mn>2</mn></msub></mrow></math></span> in carbon capture and storage projects is crucial for ensuring safety and effectiveness. We introduce DeepNRMS, a novel noise-robust method that effectively handles time-lapse noise in seismic images. The DeepNRMS leverages unsupervised deep learning to acquire knowledge of time-lapse noise characteristics from preinjection surveys. By using this learned knowledge, our approach accurately discerns <span><math display=\"inline\" overflow=\"scroll\"><mrow><msub><mi>CO</mi><mn>2</mn></msub></mrow></math></span>-induced subtle signals from the high-amplitude time-lapse noise, ensuring fidelity in monitoring while reducing costs by enabling sparse acquisition. We evaluate our method using synthetic data and field data acquired in the Aquistore project. In the synthetic experiments, we simulate time-lapse noise by incorporating random near-surface effects in the elastic properties of the subsurface model. We train our neural networks exclusively on preinjection seismic images and subsequently predict <span><math display=\"inline\" overflow=\"scroll\"><mrow><msub><mi>CO</mi><mn>2</mn></msub></mrow></math></span> locations from postinjection seismic images. In the field data analysis from Aquistore, the images from preinjection surveys are used to train the neural networks with the characteristics of time-lapse noise, followed by identifying <span><math display=\"inline\" overflow=\"scroll\"><mrow><msub><mi>CO</mi><mn>2</mn></msub></mrow></math></span> plumes within two postinjection surveys. The outcomes demonstrate the improved accuracy achieved by DeepNRMS, effectively addressing the strong time-lapse noise.","PeriodicalId":55102,"journal":{"name":"Geophysics","volume":"32 1","pages":""},"PeriodicalIF":3.0000,"publicationDate":"2024-05-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"DeepNRMS: Unsupervised deep learning for noise-robust CO2 monitoring in time-lapse seismic images\",\"authors\":\"Min Jun Park, Julio Frigerio, Bob Clapp, Biondo Biondi\",\"doi\":\"10.1190/geo2023-0608.1\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Monitoring stored <span><math display=\\\"inline\\\" overflow=\\\"scroll\\\"><mrow><msub><mi>CO</mi><mn>2</mn></msub></mrow></math></span> in carbon capture and storage projects is crucial for ensuring safety and effectiveness. We introduce DeepNRMS, a novel noise-robust method that effectively handles time-lapse noise in seismic images. The DeepNRMS leverages unsupervised deep learning to acquire knowledge of time-lapse noise characteristics from preinjection surveys. By using this learned knowledge, our approach accurately discerns <span><math display=\\\"inline\\\" overflow=\\\"scroll\\\"><mrow><msub><mi>CO</mi><mn>2</mn></msub></mrow></math></span>-induced subtle signals from the high-amplitude time-lapse noise, ensuring fidelity in monitoring while reducing costs by enabling sparse acquisition. We evaluate our method using synthetic data and field data acquired in the Aquistore project. In the synthetic experiments, we simulate time-lapse noise by incorporating random near-surface effects in the elastic properties of the subsurface model. We train our neural networks exclusively on preinjection seismic images and subsequently predict <span><math display=\\\"inline\\\" overflow=\\\"scroll\\\"><mrow><msub><mi>CO</mi><mn>2</mn></msub></mrow></math></span> locations from postinjection seismic images. In the field data analysis from Aquistore, the images from preinjection surveys are used to train the neural networks with the characteristics of time-lapse noise, followed by identifying <span><math display=\\\"inline\\\" overflow=\\\"scroll\\\"><mrow><msub><mi>CO</mi><mn>2</mn></msub></mrow></math></span> plumes within two postinjection surveys. 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DeepNRMS: Unsupervised deep learning for noise-robust CO2 monitoring in time-lapse seismic images
Monitoring stored in carbon capture and storage projects is crucial for ensuring safety and effectiveness. We introduce DeepNRMS, a novel noise-robust method that effectively handles time-lapse noise in seismic images. The DeepNRMS leverages unsupervised deep learning to acquire knowledge of time-lapse noise characteristics from preinjection surveys. By using this learned knowledge, our approach accurately discerns -induced subtle signals from the high-amplitude time-lapse noise, ensuring fidelity in monitoring while reducing costs by enabling sparse acquisition. We evaluate our method using synthetic data and field data acquired in the Aquistore project. In the synthetic experiments, we simulate time-lapse noise by incorporating random near-surface effects in the elastic properties of the subsurface model. We train our neural networks exclusively on preinjection seismic images and subsequently predict locations from postinjection seismic images. In the field data analysis from Aquistore, the images from preinjection surveys are used to train the neural networks with the characteristics of time-lapse noise, followed by identifying plumes within two postinjection surveys. The outcomes demonstrate the improved accuracy achieved by DeepNRMS, effectively addressing the strong time-lapse noise.
期刊介绍:
Geophysics, published by the Society of Exploration Geophysicists since 1936, is an archival journal encompassing all aspects of research, exploration, and education in applied geophysics.
Geophysics articles, generally more than 275 per year in six issues, cover the entire spectrum of geophysical methods, including seismology, potential fields, electromagnetics, and borehole measurements. Geophysics, a bimonthly, provides theoretical and mathematical tools needed to reproduce depicted work, encouraging further development and research.
Geophysics papers, drawn from industry and academia, undergo a rigorous peer-review process to validate the described methods and conclusions and ensure the highest editorial and production quality. Geophysics editors strongly encourage the use of real data, including actual case histories, to highlight current technology and tutorials to stimulate ideas. Some issues feature a section of solicited papers on a particular subject of current interest. Recent special sections focused on seismic anisotropy, subsalt exploration and development, and microseismic monitoring.
The PDF format of each Geophysics paper is the official version of record.
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