Submarine Mountains and Long-Distance Waves Stir Deep Ocean Circulation: Groundbreaking UWA Study

When gazing at the ocean's surface, it's tempting to envision the depths below as a serene, motionless void. Yet, groundbreaking research from the University of Western Australia (UWA) shatters this illusion, revealing how submarine mountains and long-distance waves generated by surface tides actively stir the deepest ocean layers, influencing global circulation patterns. 59 90

This new UWA study, published in the prestigious journal Ocean Science, delves into the abyssal Pacific Ocean—regions exceeding 3,000 meters in depth—where a dynamic 'bottom mixed layer' (BML) plays a pivotal role in heat, nutrient, and sediment transport. Led by Dr. Jessica Kolbusz from UWA's School of Biological Sciences, the findings highlight the interconnectedness of surface phenomena and abyssal processes, with profound implications for climate modeling and marine ecosystems.

🌊 Decoding the Abyssal Ocean and the Bottom Mixed Layer

The abyssal ocean, comprising vast expanses over 4,000 meters deep, covers much of the Pacific seafloor, featuring flat abyssal plains punctuated by fracture zones and seamounts—underwater mountains rising thousands of meters. These features are not passive; they interact with ocean dynamics in critical ways.

At the heart of the study is the Bottom Mixed Layer (BML), a zone tens to hundreds of meters thick immediately above the seafloor. Here, temperature, salinity, and density homogenize due to friction and turbulence from seabed contact. This layer marks the interface where deep waters begin their sluggish ascent in the global meridional overturning circulation (MOC), a conveyor belt redistributing heat and carbon worldwide. Without adequate mixing, cold Antarctic Bottom Water (AABW) and North Pacific Deep Water (NPDW) would stagnate, disrupting climate regulation. 90

Historically, abyssal observations have been sparse—costly deep-sea deployments yield data decades apart. UWA's work bridges this gap, combining cutting-edge expeditions with archival datasets to map BML variability comprehensively.

The UWA Expedition: Methodology and Data Revolution

The research drew from the Trans-Pacific Transit (TPT) Expedition (2023–2024), deploying autonomous landers equipped with high-resolution temperature and pressure sensors (RBRduet|deep) that reached within 40 meters of the seafloor. Seventy-three profiles across the central and eastern Pacific were analyzed, supplemented by GO-SHIP hydrographic sections (P16 and P02) spanning two decades. 90

Four methods identified BML thickness: threshold (temperature deviation <0.003°C), threshold-gradient (density gradient <1×10^{-3} kg/m³), relative variance, and Douglas-Peucker algorithm. The threshold method proved most reliable, validated by a quality index.

Machine learning—a Random Forest Regressor with 1,000 trees—processed predictors like bottom depth, slope, terrain roughness index (TRI), and internal tide dissipation rates from global datasets (GEBCO 2024, de Lavergne et al.). This novel application pinpointed dominant drivers, marking a methodological leap for oceanography.

• Surface-to-seafloor profiles: 69 valid from TPT.
• GO-SHIP integration: Salinity via Gaussian Mixture Modeling.
• Environmental factors: Extracted at 50 km scales for precision.

Key Findings: Dramatic Variability in BML Thickness

The study revealed BML thickness averaging 226 ± 172 meters (median 200m), varying wildly from <100m near continental slopes to over 700m—peaking at 799m across the Clarion Fracture Zone. Thicker layers prevailed over abyssal plains, thinner near Hawaii's rugged ridges. 90

Random Forest analysis ranked predictors: bottom depth (importance ~0.4), total internal tide energy dissipation, slope, and TRI. Low-mode internal tides—long-distance waves from surface tides breaking over submarine features—emerged as crucial, dissipating energy via wave-wave interactions, scattering, and shoaling.

This confirms submarine mountains (seamounts, fracture zones) amplify mixing by modulating wave energy, stirring even 'flat' plains remotely.

Submarine Mountains and Internal Tides: The Stirring Mechanism

Surface tides generate internal waves that propagate thousands of kilometers as low-mode waves, losing energy over rough topography. In the abyssal Pacific, these interact with seamounts and fracture zones, enhancing turbulence.

For instance, high dissipation between Hawaii and the equator correlates with thicker BMLs. Subcritical slopes allow persistent mixing, while roughness (TRI) captures local drag. Cold AABW flows northward along ridges like Tonga-Kermadec, fueling this dynamic. 59

These processes connect surface forcings to the abyss, challenging stagnant deep-ocean models.

Implications for Global Ocean Circulation

The BML facilitates water-mass transformation, enabling upwelling in the MOC. Variability affects deep limb strength, crucial for poleward heat transport. Inaccurate parameterization in models underestimates abyssal mixing, skewing circulation projections. 70

UWA's insights refine these, aiding predictions of circulation slowdowns amid warming.

Climate Change, Heat Storage, and Carbon Sequestration

Oceans absorb 90% of excess heat; abyssal mixing redistributes it vertically. Enhanced BML stirring boosts heat uptake but risks destabilizing circulation if tides weaken. Similarly, nutrient resuspension supports productivity, while carbon burial on stirred sediments influences long-term storage. 72

As climate models evolve, UWA data underscores the need for topographic realism to avoid projection errors.

Ecological and Human Impacts: Deep-Sea Mining Concerns

BML transports sediments and larvae, sustaining biodiversity. Mining nodules in Clarion-Clipperton Zone could resuspend plumes, spreading via currents. UWA's Minderoo-UWA Deep-Sea Research Centre advocates informed management under the UN High Seas Treaty. 60 Read the full study in Ocean Science. 90

Stakeholders, from policymakers to industry, must weigh these dynamics.

UWA's Leadership in Deep-Sea Research

UWA's Oceans Institute and Deep-Sea Research Centre pioneer expeditions, blending biology, geology, and engineering. Collaborators like Dr. Todd Bond and Prof. Alan Jamieson drive innovation. Explore UWA's contributions at their Oceans Institute site. 60

For aspiring researchers, research jobs and career advice for research assistants in Australia abound.

Career Pathways in Oceanography and Higher Education

This study exemplifies opportunities in Australian universities. Oceanography demands interdisciplinary skills—machine learning, fieldwork, modeling. Pursue jobs in Australia, research assistant roles, or professor positions via AcademicJobs.com. Craft a winning academic CV to join leaders like UWA.

Future Directions and Call to Action

Temporal BML changes remain unresolved; sustained seafloor observatories are next. As abyssal pathways gateway global climate, UWA calls for targeted monitoring. Engage with ocean science: rate professors at Rate My Professor, seek higher ed jobs, or explore career advice. The deep ocean's stirrings demand our attention—for science, sustainability, and careers.

For more, visit The Conversation article. 89