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Passive Acoustic Monitoring of Leaks in Underwater Wells and Pipelines

Wegner Chukwuemeka Dulo
June 19, 2026
Published Date

Research Abstract & Technology Focus

Subsea wells and pipelines are critical components of offshore energy systems, water management networks, and industrial fluid transport infrastructure. Undetected leaks carry severe consequences, including environmental contamination, significant financial loss, and safety hazards for personnel and communities. Traditional inspection approaches, including diver-based surveys and active sonar scanning, are expensive, intermittent, and often impractical in deepwater environments. Passive Acoustic Monitoring (PAM) offers a compelling non-intrusive alternative: rather than emitting signals and analysing echoes, PAM simply listens, capturing the acoustic fingerprints naturally produced by escaping fluid, bubble formation, turbulence, and structural vibration (Zimmer, 2011; Van Parijs et al., 2009). Modern PAM systems deploy hydrophones and distributed acoustic sensing (DAS) networks to capture signals across wide frequency ranges (Ferguson et al., 2010; He and Liu, 2021). These raw signals are processed through signal processing pipelines, pattern recognition algorithms, and machine learning tools to separate meaningful leak signatures from background noise whether from ship traffic, marine life, or ocean currents (Siddique et al., 2023; Gemeinhardt and Sharma, 2023). Time-frequency analysis, spectral density estimation, and automated feature extraction have all improved how reliably these systems identify and classify leak events (Ghazali et al., 2012; Ahadi and Bakhtiar, 2010). When PAM is integrated with autonomous underwater vehicles or fixed seabed sensor arrays, it becomes capable of covering large, complex pipeline networks in real time (Premus et al., 2022; Eleftherakis and Vicen-Bueno, 2020). Challenges remain: false positives are still a persistent problem, sensor placement requires careful planning, and consistent performance in noisy or variable environments is not always straightforward (Van Walree, 2013; Stojanovic and Preisig, 2009). Active research continues on multi-modal sensing, adaptive signal processing, and AI-driven localization to push detection sensitivity and spatial accuracy further. Taken together, PAM holds genuine promise for transforming subsea asset monitoring, enabling early leak identification, reducing environmental damage, and improving operational efficiency across both mature offshore markets and rapidly expanding developing economies.
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What is the core focus of the research titled 'Passive Acoustic Monitoring of Leaks in Underwater Wells and Pipelines'?

This literature focuses on: Subsea wells and pipelines are critical components of offshore energy systems, water management networks, and industrial fluid transport infrastructure. Undetected leaks carry severe consequences, including environmental contamination, significant...

What other academic literature is closely related to 'Passive Acoustic Monitoring of Leaks in Underwater Wells and Pipelines'?

Yes, highly correlated activity was mapped. An entry titled 'Exploiting Phase Memory in Multicarrier Waveforms for Robust Underwater Acoustic Communication' discusses this: Reliable underwater acoustic (UWA) communication is fundamental to marine sensing applications, including environmental monitoring, underwater sens...

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