Polymetallic Nodules: Nature’s Riches on the Seafloor

Introduction

Lying beneath the waves sits something that possesses the power to change the trajectory of humanity’s advancement for the next century. This “something” is also known as polymetallic nodules, which are a blend of a multitude of metals and minerals that are essential for many different industries. So, as the demand for critical minerals soars, polymetallic nodules may offer a way to meet it, without cutting down forests or digging massive pits that hurt the ecosystem around us [1].

Beneath The Surface

Polymetallic nodules (PMNs) are these small, rock‑like deposits that rest on the ocean floor of the Pacific Ocean [2]. They are located in the Peru Basin, Indian Ocean, and a small amount in the South Atlantic, but they are most prevalent in the Clarion‑Clipperton Zone (CCZ). The size of these PMNs varies, from some being the size of just a golf ball to some being the size of a potato. These nodules are found on the ocean floor, specifically at depths between 4,000 and 6,000 meters, with high concentrations in the CCZ. The CCZ is a 4.5 million square kilometer patch of ocean that exists between Hawaii and Mexico. It is estimated that there are close to 21 billion tons of these nodules within that region [3].

PMNs first started to form millions of years ago, as they are composed of concentric layers of valuable metals that took eons to build up [4]. Their formation first begins with a tiny nucleus, which is often a fragment of a shell, bone, or even rock. Around this nucleus, metal‑rich layers slowly accumulated over time through processes such as chemical precipitation from seawater and sediment pore water. What makes these nodules different from the way we collect resources terrestrially is that they are not buried under layers of earth. Rather, they sit atop the seabed, and are often densely scattered across vast areas, as sometimes there are thousands of them per square kilometer [5]. As stated, they are not confined to veins or underground pockets but are openly accessible, which presents a unique and potentially transformative source of key industrial metals.

A Treasure Within

At first glance, PMNs look nothing more than just a rock sitting on the seabed, but that is not what makes them important. Rather, what is inside is what matters. These nodules hold a high‑grade cocktail of critical metals that power so much of the technology needed in our modern age. Each individual nodule contains a significant amount of nickel, cobalt, manganese, and copper. All these metals are essential to the technologies driving the current global shift toward electrification and renewable energy [6].

To go more in depth, nickel and cobalt are key ingredients in the cathodes of lithium‑ion batteries, which are heavily used in EV batteries and in power grid storage. But that is not all, they are used in the phone that you have in your hand or pocket, in the laptops that billions around the world use daily, and in the headphones that billions of people use during their daily routine [7]. These metals are in huge demand, and there are metric tons of them down there in the ocean. Another metal, as stated, is manganese, which plays a vital role in the production of steel and in battery formulations. Lastly, copper is a metal that will remain irreplaceable due to its numerous functions in our current world, most notably due to its high conductivity, which is useful in power grids, electronics, and clean energy systems [8]. Essentially, anything that uses or conducts electricity possesses copper within it.

Typically, each of these resources would require its own separate mine, and thousands upon thousands of man‑hours would be poured into it while also hurting our ecosystem. Yet these nodules change this notion. What makes them most compelling, beyond the metals, is that each of these resources occurs together in a single, naturally pre‑concentrated resource, often with higher combined metal content than many land‑based ores [9].

The Urgency Today

The value of PMNs has surged in recent years due to a plethora of factors, but mainly due to the skyrocketing demand for critical metals that are needed for the global energy transition to green energy and for the digital economy. As current governments and industries race and struggle to electrify their transportation and expand their renewable energy infrastructure, while also developing new and advanced electronic systems, the need for each metal mentioned earlier grows as well [10].

Additionally, land‑based mining is facing increased scrutiny due to environmental degradation and geopolitical risk. PMNs offer an alternative that could help diversify supply chains and reduce dependence on unstable or monopolized mineral sources [11].

A Critical Crossroads

Multiple nations and private ventures have launched a multitude of exploration programs in the CCZ, while international regulatory bodies are currently under immense pressure to finalize rules that allow for commercial deep‑sea mining. Concurrently, environmental debates about this field are ongoing and are starting to gain more traction, drawing public attention, investor scrutiny, and even calls for cautious development [12], [13], [14]. With the convergence of economic opportunity, geopolitical interest, and environmental concerns, PMNs are being turned into a focal point of the broader conversation about where we will source the metals that power the 21st century and the future.

Conclusion

The pace of progress is relentless, and with each passing year, the demand for cleaner, more connected, and technologically advanced systems only intensifies. This leaves us with a critical question, where will we source the materials that are becoming more urgent by the day?

An unlikely solution may lie at the bottom of the ocean, in the form of small pieces of metal that resemble stones. These are polymetallic nodules, formed over millions of years in the silence and abyss of the seafloor. They offer a rare convergence of abundance, accessibility, and utility, combining the metals we need most into a single, naturally concentrated resource.

While the challenge of extracting them responsibly and balancing environmental risk with global necessity remains, one thing is becoming increasingly clear: polymetallic nodules will no longer be confined to research papers and oceanography labs. They are now positioned to reshape the global resource landscape.

The decisions we make in the next few years, as individuals, as a nation, and as a world, will determine who leads this field and who falls behind. In doing so, they will show us just how profoundly the seabed can reshape our future.

The ocean breathed life into Earth billions of years ago, and once again, it may be called upon to do the same.

References

[1] International Energy Agency, The Role of Critical Minerals in Clean Energy Transitions, 2021. https://www.iea.org/reports/the-role-of-critical-minerals-in-clean-energy-transitions

[2] J. Hein et al., “Marine mineral resources of the Clarion–Clipperton Fracture Zone,” Marine Georesources & Geotechnology, vol. 31, no. 2, pp. 160–179, 2013.

[3] International Seabed Authority, DeepData Portal. https://www.isa.org.jm

[4] P. Halbach et al., “Formation of polymetallic nodules: Insights from field and lab studies,” Ore Geology Reviews, vol. 5, pp. 245–260, 1990.

[5] K. Wedding et al., “From principles to practice: A spatial approach to sustainably managing the deep seabed mining of polymetallic nodules,” Scientific Reports, vol. 5, 10529, 2015.

[6] G. Petersen et al., “Polymetallic nodules as a strategic resource,” Resources Policy, vol. 79, p. 102999, 2022.

[7] U.S. Department of Energy, Mineral Requirements for Clean Energy Technologies, 2020. https://www.energy.gov

[8] European Commission, Critical Raw Materials Resilience: Charting a Path toward Greater Security and Sustainability, 2020.

[9] D. A. Hannington et al., “The abundance of polymetallic nodules and ferromanganese crusts,” Elements, vol. 7, no. 4, pp. 301–306, 2011.

[10] McKinsey & Company, The Raw-Materials Challenge: How the Metals and Mining Sector Will Be at the Core of Enabling the Energy Transition, 2022. [Online]. Available: https://www.mckinsey.com

[11] World Bank, The Growing Role of Minerals and Metals for a Low-Carbon Future, 2017.

[12] D. Leary, “International Environmental Law Perspectives on Deep Sea Mining,” Asia-Pacific Journal of Ocean Law and Policy, vol. 3, no. 1, pp. 20–42, 2018.

[13] International Seabed Authority, Exploration Contracts, 2023. [Online]. Available: https://isa.org.jm/exploration-contracts

[14] MIT Media Lab Ocean Futures Group, “Call for a Precautionary Pause to Deep-Sea Mining,” 2021. [Online]. Available: https://www.media.mit.edu