Managing the next ‘gold rush’ as miners eye the vast seafloor

By Sharon Burke

Sun, Aug 25, 2019 - Page 7

The International Seabed Authority (ISA) sits perched above the concrete boardwalk of Jamaica’s Kingston Harbor, across the bay from the spot where “Calico Jack” Rackham was once gibbeted as a warning to other 18th-century pirates. Today, this small UN agency rules the high seas — or, more precisely, the seafloor about 4.8km below — and yet it is largely unknown to the general public.

However, if China decides to retaliate against US import tariffs by restricting its exports of rare earth elements, that could change fast. Seventy-one percent of the Earth’s surface is underwater and the seafloor (or seabed) is rich in rare earth elements and other sought-after minerals — especially in deep international waters. The ISA manages the mineral rights of more than 50 percent of the world’s deep ocean floor and its 168 member states have the right to vie for access to the resources there.

However, given the risk of catastrophic environmental consequences, all countries could lose out if this contest proceeds without due care.

Undersea minerals tend to be clustered in potato-shaped chunks of rock nestled on abyssal plains, vented in boiling-hot water from fissures in the seafloor, and crusted along the flanks of extinct underwater volcanoes called seamounts. Generally, the concentrations of minerals in these formations are much higher than in ores on dry land.

Yet even with all that wealth, the only active seafloor mining project in the world right now is off the coast of Papua New Guinea and it is stalled because of financial problems. That reflects how difficult and expensive it still is to operate in the dark, freezing and high-pressure deep-sea environment, more than 80 percent of which remains unmapped and unexplored.

Nonetheless, commercial organizations and ocean scientists think that new technologies will make deep-ocean mining all but inevitable within the next decade. A range of innovations, such as better satellite imaging of the ocean floor and robot submersibles, is improving seabed access. Moreover, digital-age technologies and the global clean-energy transition are driving a sharp increase in demand for materials that are abundant in the deep ocean. In addition to rare earth elements, these include cobalt, manganese and tellurium, which are used in a growing number of applications, including batteries, magnetic resonance equipment, solar panels and guidance systems for munitions.

Competition for these increasingly useful materials was heating up even before the recent escalation of US-China trade tensions. China has a comparative advantage in critical minerals, owing to its significant domestic resources and extensive processing facilities. It also has longstanding investments in other major producing countries such as the Democratic Republic of the Congo (DRC), which accounts for about 65 percent of global cobalt production and half of total reserves.

The US, by contrast, must import many high-tech minerals. Accordingly, the US government recently deemed 35 minerals critical to the country’s economic and national security, and announced a new strategy calling for increased domestic mining, among other measures.

In terms of seabed resources, there is no contest between these two geopolitical rivals. China is expected to fare well next year when the ISA issues a new mining code and begins its first-ever permit process for mineral exploitation in international waters.

However, the US will not even be at the table, because it is not a party to the UN Convention on the Law of the Sea and thus is not officially represented at the ISA. A small clique of US senators has long blocked accession to the treaty for obscure ideological reasons, an idiosyncrasy that America might soon decide it can ill afford.

With or without US companies in the mix, economic progress is not a free ride. Recovering and refining the raw materials needed for digital technologies and clean energy inevitably has environmental consequences. All mining — including the noxious process of extracting minerals from rocks — is destructive and it is too soon to tell if deep-ocean mining is more or less destructive than mining on land.

What looks at first like a barren and forbidding wasteland is actually the largest biome on the planet, populated by fantastical creatures such as the anglerfish, vampire squid, and ancient corals that have been around since the Bronze Age. A recent University of Hawaii-led exploration of the Clarion-Clipperton Zone, a vast international underwater territory stretching from Hawaii to Mexico, documented a plethora of deep-seabed flora and fauna, more than half of which were entirely new to science.

Researchers have also recently discovered that microbial organisms in the deep ocean might play an important part in regulating the Earth’s climate. Some of these formations and organisms have taken millions of years to accrue; disturbing them, or even covering them in the sediment that mining would kick up, could permanently destroy them. Little is known about the role these species and deep-ocean microbes play in fisheries, the global climate and other ecosystem processes that support marine and terrestrial life.

The international community should aim to secure the best, least destructive supply of the minerals it needs, whether from the DRC or the deep ocean — or likely both. We should at least identify and understand the tradeoffs before crucial decisions are made, so as to weigh the possible consequences before they become irrevocable.

Clearly, China and the US — if it can be persuaded to step off the sidelines — must play a leading role in this effort.

When the industrial revolution began, no one could have known that climate change would be one of its end results, but in the digital age, the world must be much more environmentally aware when tapping the deep-ocean mineral riches.

Sharon Burke, former US assistant secretary of defense for operational energy, directs the New America’s Resource Security Program.

Copyright: Project Syndicate