Localization of spatiotemporally heterogeneous subsurface flows using autoencoder-based deep learning framework for time-lapse self-potential tomography

Huichao Yin; Scott Ikard; Dale F. Rucker; Scott C. Brooks; Zhenxue Dai; Mohamad Reza Soltanian; Kenneth C. Carroll

doi:10.1029/2025JH001208

Localization of spatiotemporally heterogeneous subsurface flows using autoencoder-based deep learning framework for time-lapse self-potential tomography

JGR Machine Learning and Computation

By: Huichao Yin, Scott Ikard, Dale F. Rucker, Scott C. Brooks, Zhenxue Dai, Mohamad Reza Soltanian, and Kenneth C. Carroll

https://doi.org/10.1029/2025JH001208

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Abstract

Self-potential (SP) monitoring has emerged as a valuable method for characterizing subsurface hydrogeological features and processes due to its sensitivity to fluid-induced electrokinetic effects. Despite advancements in SP inversion, challenges remain in imaging groundwater dynamics from SP activities due to complex hydrological settings and transient noise. In this study, a deep learning autoencoder (AE)-based framework is proposed for the spatiotemporal localization of subsurface fluid movement from time-lapse SP tomography. Temporal segments of time-lapse numerical inversions were first derived from long-term SP monitoring conducted from a floodplain site in Oak Ridge, Tennessee, known for active hyporheic exchange. Subsequently, AE models based on vision transformer (ViT), convolutional long short-term memory (ConvLSTM), convolutional neural network, and temporal convolutional network were individually trained and compared on the SP tomography segments for reconstruction performance. Finally, the reconstruction error over time serves as an anomaly score to identify moments of active SP variation, whereas spatial distributions of errors within these moments are analyzed to image and localize regions associated with anomalous subsurface fluid movement. The results demonstrate that ConvLSTM- and ViT-AE are most capable for the localization task with contrasting error distributions and consistent delineation of anomalies. Applying the method to both SP arrays parallel and perpendicular to the stream produced consistent anomaly zones near a fault or karst feature, validating the robustness and generalization of the approach. These results demonstrate the potential of the proposed framework as a scalable and interpretable tool for spatiotemporal analysis of subsurface flow dynamics in complex hydrogeological systems.

Suggested Citation

Yin, H., Ikard, S., Rucker, D.F., Brooks, S.C., Dai, Z., Soltanian, M.R., and Carroll, K.C., 2026, Localization of spatiotemporally heterogeneous subsurface flows using autoencoder-based deep learning framework for time-lapse self-potential tomography: JGR Machine Learning and Computation, v. 3, no. 3, e2025JH001208, 18 p., https://doi.org/10.1029/2025JH001208.

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Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Localization of spatiotemporally heterogeneous subsurface flows using autoencoder-based deep learning framework for time-lapse self-potential tomography
Series title	JGR Machine Learning and Computation
DOI	10.1029/2025JH001208
Volume	3
Issue	3
Publication Date	May 29, 2026
Year Published	2026
Language	English
Publisher	American Geophysical Union
Contributing office(s)	Oklahoma-Texas Water Science Center
Description	e2025JH001208, 18 p.
Country	United States
State	Tennessee
City	Oak Ridge
Other Geospatial	East Fork Poplar Creek