There's A Massive Freshwater Reservoir Hidden Beneath The Great Salt Lake

Utah’s Great Salt Lake is one of the most important bodies of water in the western U.S. For one, the 1,000-square-mile lake is a critical layover for the Pacific Flyway, with some 12 million birds from more than 300 species spending time in its waters every year.

Also, the lake adds moisture to passing storms, which eventually dump their contents onto the mountains that lie to the east, where ski slopes reign supreme. According to the Utah Division of Water Resources, the state receives nearly 95 percent of its freshwater from snowpack.

Unfortunately, it’s no secret that the Great Salt Lake is struggling. While its 1,000-square-mile expanse might sound impressive on paper, it’s less than half the size that the lake was in 1986, and the salt water’s absence has exposed nearby Salt Lake City to increased levels of toxic dust.

However, the lake’s struggles have also revealed something else that scientists didn’t expect. In recent years, circular mounds covered in 15-foot-tall thickets of reeds have appeared along the dried-out bed of an area known as Farmington Bay, suggesting that at least some level of groundwater lies beneath the lake.

To understand what exactly has fueled these reed-filled mounds, a team of geophysicists from the University of Utah conducted airborne electromagnetic (AEM) surveys in order to X-ray structures beneath Farmington Bay. They found that freshwater permeates the sediments beneath the hypersaline lakebed up to four kilometers (or roughly 13,000 feet) deep into the ground. The results of the study were published in the journal Scientific Reports.

"We were able to answer the question of how deep this potential reservoir is, and what its spatial extent is beneath the eastern lake margin," Michael Zhdanov, the lead author of the study from the University of Utah, said in a press statement. "If you know how deep, you know how wide, you know the porous space, you can calculate the potential freshwater volume."

To accurately capture this volume, Zhdanov and his team hired a geophysical crew to conduct 10 east-west surveys, covering 154 miles in total. Using a helicopter outfitted with electromagnetic equipment, these surveys accurately captured the conductivity of the overlying brine, as well as the resistive fresh water that lies beneath.

Stitching together this data into a comprehensive map showing the saline-freshwater boundary, the researchers noticed that the phragmite (reed) mounds appeared directly where freshwater pushed through the briney layer of the lake.

By combining this data with additional magnetic measurements, Zhdanov and his team successfully peered deeper beneath Farmington Bay, confirming that the freshwater may extend as far as four kilometers down.

"There are beneficial effects of this groundwater that we need to understand before we go extracting more of it," Bill Johnson, a co-author of the study from the University of Utah, said in a press statement. "A first-order objective is to understand whether we could use this freshwater to wet dust hotspots and douse them in a meaningful way without perturbing the freshwater system too much."

For now, scientists can’t say for certain if this newly discovered freshwater reservoir is the exception or the rule for the rest of the Great Salt Lake. Future aerial surveys will need to expand beyond this tiny sliver in order to capture the full extent of the lake’s freshwater treasure.

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Japan's Effective Way In Dealing With The Diaper Problem

Our planet has a big diaper problem. Families in the United States toss out over 1 trillion of the soiled garments every year, making it the third most common consumer product piling up in landfills. They also aren’t going anywhere anytime soon. Thanks to their plastic polymer components, most diapers take upwards of 500 years to fully decompose.

As far as a solution to our big number two problem, there are two main lines of thinking. On one hand, it’s important to promote the development and use of reusable alternatives made with eco-friendly materials. At the same time, it’s vital to find ways to recycle existing disposable diapers.

While there have been promising strides in both areas over the last few years, engineers in Japan say they now have an even more efficient method for getting the most out of dirty diapers. According to AFP, it’s even got the support of Unicharm, one of Japan’s leading hygiene product manufacturers.

The new technique is piggybacking on a strategy that’s already proven successful in the southern Japanese municipalities of Shibushi and Osaki.

About 25 years ago, the region’s roughly 40,000 residents realized that their local landfill was quickly running out of space. After dramatically expanding their recycling, Shibushi and Osaki now only toss about 20 percent of their household waste into the trash. At four times the average Japanese home’s recycling rate, experts now say the municipalities’ nearby landfill can remain open for another 40 years.

In 2024, Shibushi and Osaki included dirty diapers in their recycling program. Once collected, the materials are cleaned, shredded, and separated into its principal components of plastic, fabric pulp, and super-absorbent polymer (SAP). Unicharm could already turn these materials into other hygienic products like toilet paper, but a new ozone treatment designed to bleach, sterilize, and deodorize the pulp is widening the possibilities even further.

Meanwhile, the company is finalizing a method to incorporate the SAP and plastic waste into new diapers that it aims to roll out by 2028.

Although its recycled products are only available in a handful of test markets and cost about 10 percent more than standard options, they may be able to cut down on production’s water requirements. Unicharm also hopes to integrate their diaper program with 20 municipalities within the next decade.

While it’s true that soiled diapers are an issue around the world, they are particularly problematic in Japan. The nation is home to the world’s oldest average population, with an estimated 10 percent of residents over the age of 80.

"Demand for baby diapers is falling. But a growing number of elderly people wear diapers, and more recently, even pets do too," Unicharm president Takahisa Takahara explained in a recent interview. "If we can transform the sense of guilt ordinary consumers may feel about using disposable products into something positive, and make using recycled products the norm in society, it will become economically viable."

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Artemis II Only Need 3 Minutes To Reach Space

Artemis II is currently ready for its historic lunar mission. The massive rocket and Orion spacecraft are now sitting at the Launch Complex 39B after an hours-long, four-mile journey from the assembly building, where they underwent final checks.

This was not NASA's first rollout for the Artemis II mission, but NASA hopes it will be the last. Mission planners are initially targeting an 1 April 2026 launch window. Once ignition starts, it'll take about three minutes to reach NASA's defined edge of space, and eight minutes to reach orbit.

The launch requires 8.8 million pounds of thrust, which is about the same output as 326 F-16 fighter jet engines. Around one minute into ascent, the rocket throttles down for about 25 seconds at Max Q, the point of maximum aerodynamic pressure, as it pushes through the dense lower atmosphere.

Once clear, Orion will continue to accelerate, reaching nearly 3,200 miles per hour. At about 2:09 into the flight, the solid rocket boosters detach before Orion reaches the edge of space.

The next phase is where the power of the shuttle era kicks in. Four RS-25 engines, refurbished from the shuttle program, will push the spacecraft up to 17,500 mph, the minimum speed needed to maintain a stable orbit around Earth. This phase spans from the edge of space into orbit, nearly 100 miles above Earth. Most of the thrust is pushing it forward, not up.

As the crew enters microgravity just eight minutes into their 10-day journey, the RS-25 engines will shut down, and the crew will become weightless. The spacecraft will coast in orbit for about 24 hours, waiting for the precise moment when Orion's Orbital Maneuvering System Engine (OMS-E) fires the translunar injection (TLI) burn that sends Orion toward the moon.

The crew will travel more than 230,000 miles to the moon, taking about three to four days to reach its orbit. The Artemis II mission doesn't call for landing. Instead, the crew will stay about 4,000 to 6,000 miles above the surface because NASA wants to test whether Orion can safely support a crew in deep space while also giving them an opportunity to practice navigation and control systems. Once it rounds the moon, Orion will head home, splashing down in the Pacific Ocean near San Diego about ten days after liftoff.

NASA has had to delay the mission several times to make sure the spacecraft remains intact and operational during its early phases. The most recent Artemis II delay was caused by a helium pressurization issue. There's a lot on the line because Orion will carry four astronauts around the moon for the first time since 1972.

Aboard Orion are Christina Koch, Victor Glover, and Jeremy Hansen, who will be the first woman, first person of color, and first Canadian, respectively, to reach the vicinity of the moon. NASA veteran Reid Wiseman will lead.

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Ship Graveyard Discovered Off The Coast Of Ancient City

Maritime archaeologists have recently discovered a massive 328-foot ship graveyard off the coast of the 2,000-year-old ancient Greek port city of Ptolemais, Libya.

Over the centuries, earthquakes caused the Mediterranean Sea to rise, submerging the ancient port of Ptolemais. Finally, after a 13-year hiatus due to the Libyan civil war, archaeologists from the University of Warsaw returned in 2023 to explore the remains of one of the largest ancient Greek cities in the Cyrenaica region.

In the last couple of years, researchers uncovered a wealth of finds, including ancient port infrastructure, ancient columns, traces of submerged roads, numerous dropped anchors, and probes used to explore the seabed in antiquity, according to Science in Poland.

The shining star of the dig thus far was the 328.084-foot-long ship graveyard they discovered in a shallow rock formation. The site contains remains from multiple vessels, suggesting a history of merchant ships that likely foundered in the same treacherous area while approaching the shore.

The discovered cargo fragments, amphorae, and artifacts speak of the cargo that once passed through these waters, continuing to reveal a long-under-researched world of the Greek empire. "Practically the entire city remains to be discovered," the archaeologists stated.

The extensive shipwreck stretching hundreds of feet along the seafloor marks multiple failed attempts to reach the port city; alas, these ships never docked. However, in a twist of fate, what was once a disaster zone for ships arriving from the east has become "a good starting point for long-term underwater research at Ptolemais," as per Science in Poland.

What these ships carried included amphorae, one of which held crystallized wine. Researchers also recovered a bronze aequipodium, a weight for a Roman balance scale shaped like a woman’s head and filled with lead. Archaeologists are currently analyzing these finds and awaiting the results of their study, according to Science in Poland.

Researchers made stunning discoveries on land, too. A separate team identified a road that led to the Acropolis, along with possible observation towers that made up the city’s defense walls. They even found a Greek inscription from the Severan dynasty dating to the 3rd century AD., Heritage Daily reports.

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A Sweater For Buildings To Boost Warmth Inside

A team of American researchers has developed a fabric-based solution that can help buildings retain heat, potentially reducing energy use and lowering heating bills.

The approach uses a photothermal dye applied to simple materials, allowing exterior panels to absorb sunlight and keep interiors warmer.

The system, created by researchers at the University of Massachusetts Amherst, works like a thermal layer for buildings.

When placed on outside walls, the panels can raise indoor temperatures by up to 8.64°F over a day, based on modeling results.

Heating buildings remains a major contributor to energy consumption and emissions. In the United States alone, residential and commercial buildings account for a large share of total energy use, while millions of households struggle to afford heating.

Instead of relying on costly renovations like new insulation or windows, the researchers focused on a low-cost, add-on solution that can be used even by renters.

The idea draws inspiration from clothing. "When you are cold, you put on a sweater," says Carolina Aragón. "So we started thinking: what would you do if you are a building?"

The team initially explored a blanket-like covering but eventually designed removable panels that can be attached to exterior walls. These panels are coated with a photothermal dye that captures and converts sunlight into heat.

"We can put this dye on anything," says Trisha Andrew. "It does not have to be on an expensive fabric." The team tested the concept using durable umbrella fabric, keeping costs low while maintaining performance.

Modeling results suggest the approach could reduce heating energy use by up to 15 percent in residential buildings and as much as 23 percent in larger apartment blocks. Traditional retrofit methods often deliver far smaller gains.

The technology could also address broader social challenges. Many renters are unable to make permanent upgrades to their homes, while renovations can sometimes lead to higher rents.

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