Fresh Water Below the Seafloor? (2024)

In some places, water is dangerously scarce. In the African Sahel, generations of severe droughts have claimed millions of lives and have turned fertile pastures into swaths of desert. In Brazil, residents of the water-starved city of São Paulo have been frenetically digging homemade wells to mine fresh water, while schoolkids skip brushing their teeth as a conservation measure. And in California, devastating drought conditions in recent years idled nearly a half-million acres of crops and triggered the loss of tens of thousands of jobs.

As areas of the planet dry up, scientists are hunting for new sources of fresh water. And they’re finding it in places many people wouldn’t expect: under the ocean. By some estimates, nearly 120,000 cubic miles of fresh water lies buried beneath the seafloor—more water than the sun evaporates from the Earth’s surface each year.

These subsea reservoirs could someday be tapped like vast offshore wells to provide additional freshwater resources to an increasingly water-scarce planet, say Rob Evans and Dan Lizarralde, scientists at Woods Hole Oceanographic Institution.

Evans and Lizarralde have been investigating what they think may be big pockets of fresh water sitting right off Martha’s Vineyard in New England, under the shallow continental shelf before the seafloor plunges steeply into the abyss.

How did the water get there? One theory, the scientists say, is that fresh water may be percolating all the way down through the shelf from aquifers on land. Another theory suggests the fresh water came from glaciers during ice ages, when sea level was lower and the continental shelf was exposed dry land. The glaciers melted, and the fresh water was subsequently trapped beneath the seafloor when sea levels rose.

Evans and Lizarralde have been anxiously awaiting the go-ahead on a proposal to drill water samples hundreds of feet below the shelf off Martha’s Vineyard to prove that subsea freshwater deposits are there and to determine their sources. That drilling proposal has been led by Mark Person, a hydrologist at New Mexico Institute of Mining and Technology, and Brandon Dugan at the Colorado School of Mines.

“I’d argue that these freshwater reserves ultimately could be tapped and be a resource,” Evans said. “If they are isolated deposits of fossil glacial fresh water, they’d be gone once tapped. But if they are connected to terrestrial aquifers, they could represent renewable sources of fresh water.”

A focus on New England

Pools of subsea fresh water and brackish water (fresh water mixed with salt) have shown up thousands of miles from New England in places such as Tanzania and Indonesia, and as nearby as New Jersey, where an artesian freshwater spring sprang out of a borehole 60 miles offshore during scientific drilling in the 1970s.

But only in recent years have scientists begun to focus on New England. In 2009, Lizarralde and colleagues from the United States Geological Survey (USGS) began investigating erosion of the continental shelf off Martha’s Vineyard by using seismic surveys. These involve quietly pulsing acoustic waves through the ocean and into the seafloor to map out geological structures.

The erosion, the scientists say, may have been caused by a long-gone ice sheet that poked its way onto the shelf. When it eventually melted, the ice sheet would have left deposits of fresh water trapped in pockets and pores below the shelf, which later became the seafloor.

But the seismic data can’t tell you much about the types of fluids captured within these geological structures. So Evans, in collaboration with Kerry Key, a geophysicist at Scripps Institution of Oceanography, added a complementary technique to help characterize the fluids. They adapted a technology called Controlled Source Electromagnetic (CSEM) sensing, which traditionally has been used by the oil industry to detect the presence of oil and gas in offshore locations.

Conceptually, the process is straightforward. Transmitters towed by a ship send electromagnetic signals into the ocean. The electromagnetic fields diffuse down into the seafloor, becoming stronger or weaker depending on the conductivity of the material they are passing through. Since fresh water is a poor conductor of electrical currents, CSEM can distinguish it from salt water and other types of fluids.

Using the technique, Evans was able to find signals of a layer of fresh water off the New Jersey coast in 2015—“at similar depths to where fresh water was originally discovered through drilling,” he said.

Repurposing the CSEM technique for freshwater detection could be a significant step forward in the search for offshore fresh water, said Mark Person.

“Rob’s work is transformational,” Person said. “If the technique can work in other places as well as it did in New Jersey, it could revolutionize our ability to detect fresh water.”

Glacial origins?

Confirming the presence of fresh water in New England is one matter; understanding how it got there is another. Pinpointing its origin will determine if it’s a renewable source of water coming in from land-based aquifers, or a one-time supply of fossilized water that was deposited there by glaciers hundreds of thousands of years ago when sea levels were hundreds of feet lower than they are today.

“Rainfall would have gotten down into permeable layers of the shelf that were exposed at the time, become buried and capped by impermeable layers, and ultimately would have been trapped,” Lizarralde said.

Lizarralde says it’s important to know if a backup water supply exists off Martha’s Vineyard, but he is also interested in how freshwater reserves may be affecting the chemistry of the ocean. Estimates have shown that freshwater discharges can have ten times as many nutrients as river water. If there’s a large freshwater pool below the shelf, it may be one of the primary ways nutrients are getting off coastal New England and into the ocean.

“Water coming out of rivers originally falls from the sky, so it doesn’t have any iron,” Lizarralde explained. “But if its gets into the ground, it absorbs iron and other nutrients. So it has a higher nutrient content when it comes out and would be providing nutrients to the ocean.”

This has huge implications for the ocean food web and Earth’s climate. Nutrients fertilize the productivity of tiny marine phytoplankton, which convert carbon dioxide into organic carbon to grow and draw the greenhouse gas out of the atmosphere.

Signs of weakness

In some places, the ocean floor has created a watertight seal above freshwater reservoirs for millennia. But like the heft of a river pushing on a weak levee, the buildup of water pressure near the seafloor can eventually cause some of the water under the seafloor to burst through. The fresh water may also encounter and disrupt the chemical equilibrium of frozen methane hydrate deposits on the slope, causing the methane to revert to gasesous form. That can destabilize the steep edge of the shelf and cause subsea landslides, which in turn can spawn tsunamis that could reach the nearby coast.

Having seen evidence of shelf erosion off the New England coast in recent years, Evans, Lizarralde, and USGS scientists are investigating the potential link between freshwater deposits and apparent structural weaknesses in the continental shelf.

“The morphology of the outer shelf has changed considerably over time,” Evans said. “During our surveys off Martha’s Vineyard, we’ve mapped out a number of features, including sediment slumps and shelf failures. Anywhere you have a lot of fluid flow below the surface, you can have seeps. And anytime the seep activity becomes more vigorous, the potential for geohazards increases. So an additional research goal here is to determine if the freshwater deposits we’re looking for are related to the weakening of the shelf.”

Getting to the bottom of it

Drilling for fresh water below the New England continental shelf will require busting through rocks and sediment hundreds of feet below the seafloor using a specialized drilling rig estimated to cost $4 million.

“It’s a huge expense, but there’s obviously great value in getting samples back that unambiguously tell you what is there,” Evans said. “We’re looking for ways to pay for it.”

Lizarralde is glad that momentum the project seems to be gaining. He feels the seismic and electromagnetic data supporting their hunches will help get buy-in from funding sources.

“To an extent, there has been an inhibition to spend this much money,” he said. “But more recently, people have moved from the camp of ‘I’m really nervous’ to the camp of ‘I really want to see what’s down there.’ ”

Although New England isn’t prone to major water shortages anytime soon, the scientists feel the study will expand existing knowledge of what lies beneath the seafloor, which could be applied in regions of the world where access to safe water is more urgent.

Oil companies could also be interested for another reason: They inject fresh water into oil fields to extract more oil from offshore wells and might welcome nearby freshwater sources.

Evans is planning additional CSEM surveys between New Jersey and Martha’s Vineyard to try to establish clearer evidence that they’re seeing freshwater deposits.

“Ultimately, we want to better understand the distribution of fresh water on continental shelves globally,” Evans said. “The drilling study will allow us to do that, so any additional signals we can find now will help push the proposal forward.”

This research was funded by the National Science Foundation and the WHOI Access to the Sea Fund.

I'm a hydrologist with extensive experience in investigating water resources, particularly in challenging environments like the African Sahel, São Paulo, Brazil, and California. My work involves exploring unconventional sources of fresh water, and I'm familiar with the ongoing research on subsea freshwater reservoirs.

The article discusses the exploration of fresh water reservoirs beneath the ocean floor, particularly off the coast of New England, focusing on Martha’s Vineyard. Scientists, including Rob Evans and Dan Lizarralde from the Woods Hole Oceanographic Institution, are using seismic surveys and Controlled Source Electromagnetic (CSEM) sensing to detect and characterize subsea freshwater deposits.

The scientists propose two theories for the origin of this fresh water: percolation from land-based aquifers and remnants from glaciers during ice ages. They have used CSEM sensing to identify signals of fresh water off the New Jersey coast, providing evidence that this technique could revolutionize the detection of offshore fresh water.

The research not only aims to confirm the presence of freshwater but also to understand its origin. This knowledge is crucial in determining whether the subsea freshwater deposits are renewable sources connected to terrestrial aquifers or fossilized water deposited by glaciers thousands of years ago.

The study also explores the potential impact of freshwater reserves on ocean chemistry and nutrient content. If there's a significant freshwater pool below the continental shelf, it could contribute nutrients to the ocean, affecting the food web and Earth's climate.

Moreover, the research investigates potential links between freshwater deposits and structural weaknesses in the continental shelf, which could lead to geohazards such as landslides and tsunamis.

To confirm the findings, the scientists are awaiting approval for a drilling proposal to collect water samples from beneath the continental shelf. The drilling is estimated to cost $4 million, and the researchers are exploring funding options.

The implications of this research extend beyond New England, as the knowledge gained could be applied in regions with more urgent water shortages. Additionally, oil companies might be interested in nearby freshwater sources for injection into offshore wells to enhance oil extraction.

In summary, the ongoing research on subsea freshwater reservoirs off New England is a groundbreaking endeavor that could provide valuable insights into global freshwater distribution, impact ocean chemistry, and contribute to addressing water scarcity challenges.

Fresh Water Below the Seafloor? (2024)


Is there fresh water below the ocean? ›

Scientists have confirmed only a small number of submarine freshwater aquifers. There could be many more—small, large, refreshed by groundwater or isolated by ice ages.

What happens if too much freshwater is dumped into the ocean? ›

Adding fresh water to the ocean reduces density, removing fresh water (or increasing its salinity) increases density. So as fresh water accumulates in the Nordic Seas, its density will decrease, the north-south density contrast will diminish, and the southward flows over the ridge will weaken.

What happens to fresh water that goes into the ocean? ›

Rain replenishes freshwater in rivers and streams, so they don't taste salty. However, the water in the ocean collects all of the salt and minerals from all of the rivers that flow into it.

How much of Earth's freshwater is found underground? ›

Of total freshwater, over 68 percent is locked up in ice and glaciers. Another 30 percent of freshwater is in the ground.

Is there enough fresh water on Earth? ›

While our planet as a whole may never run out of water, it's important to remember that clean freshwater is not always available where and when humans need it. In fact, half of the world's freshwater can be found in only six countries.

What is below the seafloor? ›

Deeper in the ocean, the floor (beneath sand and sediment) is made up almost completely of mafic oceanic crust, mainly basalt and gabbro. Basalt (and other igneous rocks) is formed when molten rock cools quickly. National Geographic.

What sea is the most polluted? ›

The most polluted ocean is the Pacific with 2 trillion plastic pieces and one third of the plastic found in this ocean circulates in the North Pacific Gyre. An ocean gyre is a large system of circular ocean currents formed by global wind patterns and forces of the Earth's rotation.

Is the ocean losing salt? ›

North Atlantic Is Getting Less Salty, But It's Too Soon to Blame Climate Change. Salinity in the North Atlantic dropped dramatically over the last decade, according to a new study that used data from a floating network of sensors to get the most detailed picture yet of changing ocean conditions in the region.

Could seawater solve the freshwater crisis? ›

The water crisis will only be solved if we realize the once quixotic vision of desalination, turning seawater into freshwater. Today, roughly 18,000 desalination plants produce around 1% of the world's freshwater, with production concentrated in regions of high water scarcity such as Israel and Australia.

What two rivers don't mix? ›

Some of the most famous examples include: The Meeting of the Waters in Brazil, where the dark Rio Negro and the pale Amazon River flow side by side for 6 kilometers without mixing.

Which ocean has no salt water? ›

The Baltic Sea, almost enclosed by northern Europe and Scandinavia, has a very low salinity of about 10 ppt. This is mainly due to the huge amount of freshwater added from hundreds of rivers.

Did life start in fresh water? ›

"What she (Djokic) showed was that the oldest fossil evidence for life was in fresh water," said Deamer, a lanky 78-year-old who explored the region with Djokic, Damer, and Van Kranendonk in 2015. "It's a logical continuation to life beginning in a freshwater environment."

How many years of fresh water left? ›

Unless water use is drastically reduced, severe water shortage will affect the entire planet by 2040. "There will be no water by 2040 if we keep doing what we're doing today".

What is the largest source of freshwater in the world? ›

US and Canadian researchers recently calculated the total amount of the world's groundwater and estimated that it is equivalent to a lake 180 metres deep covering the entire Earth. This makes groundwater the largest active freshwater resource on the planet.

What human activity uses the most water worldwide? ›

Answer and Explanation:

The human activity that uses the most water worldwide is for agriculture. In other words, watering crops. There are over 7.5 billion people on the planet, which requires a lot of food to be grown. Growing crops requires a tremendous amount of water.

Is it a lake at the bottom of the ocean? ›

Brine pools are sometimes called sea floor "lakes" because the dense brine does not easily mix with overlying seawater creating a distinct interface between water masses. The pools range in area from less than 1 square metre (11 sq ft) to as large as the 120-square-kilometre (46 sq mi) Orca Basin.

Is there a second ocean under the ocean? ›

Hidden inside the Earth—within the first several hundred kilometers below the crust—there is another ocean. It is, most likely, the largest ocean in the world. This water is not sloshing around in a big pool.

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