Hundreds of people undressed for a nude photo shoot last week to bring attention to the Dead Sea, a unique body of water bordered by Israel and Jordan at the lowest point on Earth—1,380 feet below sea level.

The Dead Sea (Salt Sea in Hebrew) is the deepest hypersaline lake in the world, 27 times denser than Utah’s Great Salt Lake.

Tourists and Israelis alike love bobbing in the mineral-rich water, slathering on its healing mud and using cosmetics made from its extracts. The water and even the ambient air have proven health benefits for everything from asthma to psoriasis.

The problem is that the Dead Sea has been shrinking at an alarming pace, losing more than 40 inches of water per year for a total of 78 feet since the 1990s, according to EcoPeace Middle East. Giant sinkholes have swallowed up several beaches.

The photo shoot by the Dead Sea Revival Project was intended to spur action and celebrate the opening of a virtual Dead Sea Museum meant as a forerunner to an actual museum in nearby Arad.

ISRAEL21c asked several experts to explain the Dead Sea’s troubles and what can be done to ensure the beloved lake won’t disappear.

Some of their answers may surprise you. Spoiler alert: The Dead Sea is surely shrinking—but it is not dying.

First let’s explain the problems and proposed solutions. Then we’ll share our experts’ predictions.

People camp on the shores of the Dead Sea, March 2, 2018. Photo by Matanya Tausig/Flash90.

Why is the Dead Sea shrinking?

“The main problem is a lack of freshwater coming into the Dead Sea, in which natural evaporation is strong,” explains Isaac Gertman, a senior researcher at the National Institute of Oceanography at the Israel Oceanographic and Limnological Research in Haifa.

Dr. Isaac Gertman near the Israel Oceanographic and Limnological Research institute’s 30-year-old meteorology platform, where the Dead Sea’s temperature and water level are measured. Credit: Courtesy.

This happened because the landlocked Dead Sea primarily depends on the lower Jordan River, which in turn depends on the Sea of Galilee (Lake Kinneret), to get replenished. Much of this freshwater has been diverted to provide for drinking, farming and industry in Israel and Jordan.

The Jordan River near Kfar Blum, in the Upper Galilee, April 8, 2019. Photo by Yossi Zamir/Flash90.

About 700 million cubic meters of water would be needed to restore the sea level to where it was in 1900, says Gertman, who has studied the Dead Sea since 1994.

“Natural runoff, including precipitation and floods, was about 300 million cubic meters per year. Now it’s about 100 million cubic meters per year,” says Gertman.

A lesser factor is the mineral-extraction industries in Israel and Jordan.

A view of the Dead Sea Works on Feb. 2, 2018. The Dead Sea Works is an Israeli potash plant on the Dead Sea coast. Photo by Issac Harari/Flash90.

Potassium chloride and magnesium chloride are mined in large quantities by Dead Sea Works and the Arab Potash Company at the southern end of the Dead Sea. The evaporation ponds used in this process are responsible for about 35 percent of the depletion of the Dead Sea.

What causes sinkholes?

Gidon Baer, former coordinator for Dead Sea studies at the Geological Survey of Israel, explains that sinkholes form due to cavities developing underground because fresh groundwater from the Judean mountains is dissolving a salt layer deposited in the Dead Sea about 10,000 years ago.

Dr. Gidon Baer setting up a camera at a Dead Sea sinkhole. Credit: Courtesy.

That salt layer now sits 10 to 15 meters below the surface at the shoreline, covered by newer sediments.

“Until the 1980s, this salt layer was soaked with salty water that infiltrated from the Dead Sea. But as the Dead Sea water level drops, the interface between the salty subsurface water and the fresh groundwater dropped as well, and the salt layer encountered freshwater, which led to the dissolution,” says Baer.

Eventually the cavities collapse and form sinkholes. Flash floods in the winter drain directly into the subsurface salt layer of the sinkhole, dissolving it much more quickly than when fresh groundwater reaches the sinkhole.

Sinkholes near the Dead Sea, formed by dissolution of underground salt by incoming freshwater, as a result of a continuing sea level drop, on Nov. 5, 2020. Photo by Yonatan Sindel/Flash90.

“We expect that in the coming 20 to 30 years, the fresh groundwater level will become lower than the salt layer, so the only freshwater that will reach the salt layer will be from flash floods. We are now studying the effect this will have,” says Baer.

The Geological Survey set up a sinkhole early-warning system monitored with satellite- and airborne-based measurements.

“Sometimes we can predict the collapse five years ahead, sometimes two weeks ahead. We mark all places where we see it happening and share that information with road authorities and other planning authorities so they can mitigate the consequences.”

This system forecast the sinkhole that formed along the main road north of Ein Gedi in 2015, about three years in advance. That gave local authorities time to build a bypass road and close the main road, avoiding a disaster.

Are there solutions?

Gertman says that one idea was to connect the Dead and Mediterranean seas, sending runoff from the Med to the Dead and building power plants along the way. But this is not feasible economically or logistically.

About 10 years ago, another idea was floated: Building a channel from the Red Sea in Eilat to the Dead Sea, bringing desalinated water mainly to Jordan and sending the end desal product, brine, to the Dead Sea. The addition of brine could slow the rate of decrease in water level and thereby postpone the development of related problems.

An aerial view shows the salt formations on the Dead Sea shore, July 20, 2020. Photo by Mendy Hechtman/Flash90.

However, it’s doubtful the project will go forward due to economic and political considerations.

“It would be very expensive and difficult to build. The World Bank agreed to give some money to study this project and to build it, but it’s still at the idea stage because we need close cooperation with Jordan to make it happen,” says Gertman. “It’s easy to talk about but hard to do.”

Many Israeli scientists agree with Gertman that it may be better to build desal plants on the northern Mediterranean coast that would replenish the Kinneret with freshwater and at least partially restore the natural flow from the Kinneret to the Jordan to the Dead Sea.

Clive Lipchin, director of the Arava Institute for Environmental Studies’ Center for Transboundary Water Management, believes the Dead Sea can never again be adequately fed by the Jordan River, because the water is too badly needed by people on both sides of the border.

Dr. Clive Lipchin. Credit: Arava Institute.

“This is a water-scarce region. Even with 100 more desalination plants, freshwater will always be the most sought-after resource,” he says.

The Arava Institute strives to build cooperation in the region to solve water-related issues.

“It’s critical to understand that any potential solution has to have collaborative foundations. You need regional cooperation, and that is our best and most valuable role,” says Lipchin.

“We have strong partnerships in Jordan and the Palestinian Authority. But the reason nothing is moving forward to save the Dead Sea is a lack of such cooperation at the governmental level. Israel and Jordan signed agreements on Red-Dead 10 years ago but until the governments get their act together nothing will happen.”

The future of the Dead Sea

Contrary to popular belief, research indicates that the Dead Sea will never dry up entirely, says Gidon Baer of the Geological Survey of Israel.

“The rate at which the level is dropping will lessen and eventually it will stabilize. The Dead Sea will not disappear,” he says.

This is because the rate of evaporation declines as salinity increases. “Eventually, the rate of loss will equal the rate of inflow of water,” Baer explains.

The consequences of the shrinkage will continue causing economic and environmental impacts, not all of them bad.

“When the water level drops it exposes new land at the shoreline, more salt is deposited and sinkholes form,” he says. “These features have both negative and positive aspects.”

Aerial view of the Dead Sea beaches, on June 25, 2016. Photo by Edi Israel/Flash90.

For tourists, one negative result is that the sinkholes have destroyed several Dead Sea beaches and make it difficult to reach the waterline of surviving beaches. This could be managed by finding or building alternative routes, Baer suggests.

On the other hand, tourism could benefit from the situation.

“The features exposed have never been seen before, and the beauty of the Dead Sea is even enhanced,” says Baer.

“Before the 1980s, salt wasn’t deposited along the shoreline in such variety and quantity, and now you see it both on the shoreline and in the water. People can take advantage of that by bringing tourists to see those features.”

People walk on a sand barrier in the southern Dead Sea, on Feb. 21, 2017. Photo by Hadas Parush/Flash90.

Israel could, for example, build a safe trail around the sinkholes for tourists.

Another advantage of the newly exposed features is the opportunity for scientific study that could shed light on similar places in the world.

Living with the problems

At least for now, with no sure solution in sight for the Dead Sea’s woes, we may have to view the situation the way we are starting to view the Covid pandemic: learn to live with it.

That’s the opinion of Jiwchar Ganor, a professor of Earth and environmental sciences at Ben-Gurion University of the Negev, and former dean of the Faculty of Natural Sciences.

Ben-Gurion University professor Jiwchar Ganor. Credit: Dani Machlis/BGU.

“The decrease in sea level is of course human caused, but people need to drink and eat,” he says. “There is a huge population in Israel, Jordan, Lebanon and Syria. These areas are starving for water. They use all the available water, and the result is a drop in the Dead Sea level.”

Ganor adds that the net effect of the mineral-mining industry is more salinity. It’s not possible to stabilize both the salinity and the water level.

“We can stop the sea-level drop by adding seawater or desalination brine, but if we do that, we will make the surface water much less salty on the top and this will cause more sinkholes,” he says.

“We can stabilize the salinity, but if we do that the water level will go down. All we can do is slow the rate of decrease by adding a limited amount of water from the brine of desalination in the Gulf of Eilat.”

The reality, says Ganor, is that the problems cannot be solved completely.

“We have a huge need for freshwater. And we have an industry that is a very important source of foreign currency for Jordan, and for Israel is a major employer in the South.”

However, he agrees with Baer that the salty lake will be with us forever.

“The Dead Sea will shrink but not disappear,” he concludes.

This article was first published by Israel21c.

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