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Daily Mail: The two massive and mysterious Texas sinkholes on the verge of creating one colossal lake

‘A collapse could be catastrophic. Following our study, we are collecting more high-resolution satellite data over the sinkholes and neighboring regions to monitor further development and collapse.’

Wink sinkholes

London Daily Mail online journalist Ashley Collman covered the research of SMU geophysicists Zhong Lu, professor, Shuler-Foscue Chair, and Jin-Woo Kim research scientist, both in the Roy M. Huffington Department of Earth Sciences at SMU. Collman’s article, “The two massive and mysterious Texas sinkholes on the verge of creating one colossal lake,” published June 16, 2016.

The Dedman College researchers are co-authors of a new analysis using satellite radar images to reveal ground movement of two giant sinkholes near Wink, Texas. They found that the movement suggests the two existing holes are expanding, and new ones are forming as nearby subsidence occurs at an alarming rate.

Lu is world-renowned for leading scientists in InSAR applications, short for a technique called interferometric synthetic aperture radar, to detect surface changes that aren’t visible to the naked eye. Lu is a member of the Science Definition Team for the dedicated U.S. and Indian NASA-ISRO InSAR mission, set for launch in 2020 to study hazards and global environmental change.

InSAR accesses a series of images captured by a read-out radar instrument mounted on the orbiting satellite Sentinel-1A. Sentinel-1A was launched in April 2014 as part of the European Union’s Copernicus program.

Lu and Kim reported the findings in the scientific journal Remote Sensing, in the article “Ongoing deformation of sinkholes in Wink, Texas, observed by time-series Sentinel-1A SAR Interferometry.”

The research was supported by the U.S. Geological Survey Land Remote Sensing Program, the NASA Earth Surface & Interior Program, and the Shuler-Foscue Endowment at Southern Methodist University.

Read the full story.

EXCERPT:

By Ashley Collman
London Daily Mail

Scientists have issued a grave warning to a small Texas community home to two growing sinkholes.

Geologists at Southern Methodist University say the two sinkholes in Wink and neighboring Kermit, Texas are growing more unstable, and could spark more sinkholes or join to create one massive hole.

This will prove devastating to the local community, which has a combined population of almost 7,000.

SMU researchers Zhong Lu and Jin-Woo Kim recently published their sober warning in a recent article in the journal Remote Sensing.

‘This area is heavily populated with oil and gas production equipment and installations, hazardous liquid pipelines, as well as two communities. The intrusion of freshwater to underground can dissolve the interbedded salt layers and accelerate the sinkhole collapse,’ co-author Kim said in a press release.

‘A collapse could be catastrophic. Following our study, we are collecting more high-resolution satellite data over the sinkholes and neighboring regions to monitor further development and collapse.’

Lu and Kim discovered that the two holes were growing more unstable by using satellite images that measures depressions in the earth’s crust.

The satellite data found that the two holes – which are located about a mile apart – are rapidly growing and causing the ground around them to become more and more unstable – opening up the possibility of more sinkholes or the creation of one giant sinkhole.

The sinkhole in Wink is the oldest and smallest of the two sinkholes, but it is growing the fastest.

Right now it is about 361 feet across – or the length of a football field.

‘Even though Wink No. 1 collapsed in 1980, its neighboring areas are still subsiding,’ say the authors, ‘and the sinkhole continues to expand.’

Read the full story.

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Grist: Massive sinkholes in Texas could combine to form even massiver sinkhole

“This area is heavily populated with oil and gas production equipment and installations, hazardous liquid pipelines, as well as two communities,” said study author Jin-Woo Kim in a press release. “A collapse could be catastrophic.”

Wink sinkholes

Grist.org journalist Katie Herzog covered the research of SMU geophysicists Zhong Lu, professor, Shuler-Foscue Chair, and Jin-Woo Kim research scientist, both in the Roy M. Huffington Department of Earth Sciences at SMU. Herzog’s article, “Massive sinkholes in Texas could combine to form even massiver sinkhole,” published June 15, 2016.

The Dedman College faculty are co-authors of a new analysis using satellite radar images to reveal ground movement of two giant sinkholes near Wink, Texas. They found that the movement suggests the two existing holes are expanding, and new ones are forming as nearby subsidence occurs at an alarming rate.

Lu is world-renowned for leading scientists in InSAR applications, short for a technique called interferometric synthetic aperture radar, to detect surface changes that aren’t visible to the naked eye. Lu is a member of the Science Definition Team for the dedicated U.S. and Indian NASA-ISRO InSAR mission, set for launch in 2020 to study hazards and global environmental change.

InSAR accesses a series of images captured by a read-out radar instrument mounted on the orbiting satellite Sentinel-1A. Sentinel-1A was launched in April 2014 as part of the European Union’s Copernicus program.

Lu and Kim reported the findings in the scientific journal Remote Sensing, in the article “Ongoing deformation of sinkholes in Wink, Texas, observed by time-series Sentinel-1A SAR Interferometry.”

The research was supported by the U.S. Geological Survey Land Remote Sensing Program, the NASA Earth Surface & Interior Program, and the Shuler-Foscue Endowment at Southern Methodist University.

Read the full story.

EXCERPT:

By Katie Herzog
Grist.org

Welcome to West Texas, where sometimes the ground just opens up under your feet.

Two existing sinkholes — one in the adorably named town of Wink, the other in the absurdly named town of Kermit — are about a mile away from each other, but data suggests they might be expanding. Researchers from Southern Methodist University analyzed radar images of the area and found some hints of movement in the surrounding ground. If the sinkholes keep growing, it’s possible they will merge into one supermassive sinkhole.

And that would be a big problem indeed.

“This area is heavily populated with oil and gas production equipment and installations, hazardous liquid pipelines, as well as two communities,” said study author Jin-Woo Kim in a press release. “A collapse could be catastrophic.”

Sinkholes are not uncommon in this part of West Texas, thanks to the area’s prolific oil and gas industries. These particular sinkholes, however, are large even by Texas standards: The hole in Wink, which formed in 1980, is 361 feet across — or the length of a football field — and its neighbor in Kermit varies between 600 and 900 feet across. Both are over 100 feet deep.

Sinkholes occur when water dissolves bedrock over time, and then — sometimes suddenly — the ground collapses. They can be just a few feet across, or, like these ones, big enough to hold buildings. (A 2013 sinkhole opened up under the National Corvette Museum in Bowling Green, Ky., and swallowed eight classic cars.) And while sinkholes can form naturally, they are also created by human activity like oil and gas extraction.

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Geohazard: Giant sinkholes near West Texas oil patch towns are growing — as new ones lurk

Satellite radar images reveal ground movement of infamous sinkholes near Wink, Texas; suggest the two existing holes are expanding, and new ones are forming as nearby subsidence occurs at an alarming rate.

Residents of Wink and neighboring Kermit have grown accustomed to the two giant sinkholes that sit between their small West Texas towns.

But now radar images taken of the sinkholes by an orbiting space satellite reveal big changes may be on the horizon.

A new study by geophysicists at Southern Methodist University, Dallas, finds the massive sinkholes are unstable, with the ground around them subsiding, suggesting the holes could pose a bigger hazard sometime in the future.

The two sinkholes — about a mile apart — appear to be expanding. Additionally, areas around the existing sinkholes are unstable, with large areas of subsidence detected via satellite radar remote sensing.

That leaves the possibility that new sinkholes, or one giant sinkhole, may form, said geophysicists and study co-authors Zhong Lu, professor, Shuler-Foscue Chair, and Jin-Woo Kim research scientist, in the Roy M. Huffington Department of Earth Sciences at SMU.

“This area is heavily populated with oil and gas production equipment and installations, hazardous liquid pipelines, as well as two communities. The intrusion of freshwater to underground can dissolve the interbedded salt layers and accelerate the sinkhole collapse,” said Kim, who leads the SMU geophysical team reporting the findings. “A collapse could be catastrophic. Following our study, we are collecting more high-resolution satellite data over the sinkholes and neighboring regions to monitor further development and collapse.”

Lu and Kim reported the findings in the scientific journal Remote Sensing, in the article “Ongoing deformation of sinkholes in Wink, Texas, observed by time-series Sentinel-1A SAR Interferometry.”

The research was supported by the U.S. Geological Survey Land Remote Sensing Program, the NASA Earth Surface & Interior Program, and the Shuler-Foscue Endowment at Southern Methodist University.

Unstable ground linked to rising, falling groundwater
The sinkholes were originally caused by the area’s prolific oil and gas extraction, which peaked from 1926 to 1964. Wink Sink No. 1, near the Hendricks oil well 10-A, opened in 1980. Wink Sink No. 2, near Gulf WS-8 supply well, opened 22 years later in 2002.

It appears the area’s unstable ground now is linked to changing groundwater levels and dissolving minerals, say the scientists. A deep-seated salt bed underlies the area, part of the massive oil-rich Permian Basin of West Texas and southeastern New Mexico.

With the new data, the SMU geophysicists found a high correlation between groundwater level in the underlying aquifer and further sinking of the surface area during the summer months, influenced by successive roof failures in underlying cavities.

Satellite images and groundwater records indicate that when groundwater levels rise, the ground lifts. But the presence of that same groundwater then speeds the dissolving of the underground salt, which then causes the ground surface to subside.

Everything’s bigger in Texas, and the Wink sinkholes are no exception
Officials have fenced off the two sinkholes near Wink, a town of about 940 people, and Kermit, a town of about 6,000 people. The giant holes are notable features on the area’s vast plains, which are dotted mostly with oil pump jacks, storage facilities, occasional brush and mesquite trees.

Based on modeling of satellite image datasets, SMU’s researchers report that Wink Sink No. 1, which is closer to the town of Kermit, appears to be the most unstable. The smaller hole of the two, it has grown to 361 feet (110 meters) across — the length of a football field.

“Even though Wink No. 1 collapsed in 1980, its neighboring areas are still subsiding,” say the authors, “and the sinkhole continues to expand.” An oval-shaped deformation circling the sinkhole measures three-tenths of a mile (500 meters) wide and is subsiding up to 1.6 inches (4 centimeters) a year.

Wink Sink No. 2, which is nine-tenths of a mile south of No. 1 and which sits closer to the town of Wink, is the larger of the sinkholes. It varies from 670 feet to 900 feet across.

Wink No. 2 is not experiencing as much subsidence as Wink No. 1. However, its eastern side is collapsing and eroding westward at a rate of up to 1.2 inches (3 centimeters) a year.

“Wink No. 2 exhibits depression associated with the ongoing expansion of the underground cavity,” the authors report.

Some ground that doesn’t even border the edges of the two sinkholes is also subsiding, the scientists observed. An area more than half a mile (1 kilometer) northeast of No. 2 sank at a rate of 1.6 inches (4 centimeters) in just four months.

Ground northeast of sinkholes is subsiding, suggesting new ones forming
The largest rate of ground subsidence is not at either sinkhole, but at an area about seven-tenths of a mile (1.2 kilometers) northeast of No. 2. Ground there is subsiding at a rate of more than 5 inches (13 centimeters) a year.

It’s aerial extent, the researchers report, has also enlarged over the past eight years when a previous survey was done.

“The enlarged deformation could be an alarming precursor to the potential future development of hazards in the vicinity,” said the authors.

Additionally, ground along a road traveled by oil field vehicles, about a quarter mile (400 meters) directly north of No. 2, is subsiding about 1.2 inches (3 centimeters) a year.

Ground’s movement detected with radar technique
The satellite radar datasets were collected over five months between April 2015 and August 2015. With them, the geophysicists observed both two-dimension east-west deformation of the sinkholes, as well as vertical deformation.

The SMU scientists used a technique called interferometric synthetic aperture radar, or InSAR for short, to detect changes that aren’t visible to the naked eye.

“From 435 miles above the Earth’s surface, this InSAR technique allows us to measure inch-level subsidence on the ground. This is a monumental human achievement, and scientists will not stop endeavoring to improve this technique for more precise measurements,” said Lu, who is world-renowned for leading scientists in InSAR applications. Lu is a member of the Science Definition Team for the dedicated U.S. and Indian NASA-ISRO InSAR mission, set for launch in 2020 to study hazards and global environmental change.

InSAR accesses a series of images captured by a read-out radar instrument mounted on the orbiting satellite Sentinel-1A. Sentinel-1A was launched in April 2014 as part of the European Union’s Copernicus program.

Simply put, Sentinel-1A bounces a radar signal off the earth, then records the signal as it bounces back, delivering measurements. The measurements allow geophysicists to determine the distance from the satellite to the ground, revealing how features on the Earth’s surface change over time.

“Sinkhole formation has previously been unpredictable, but satellite remote sensing provides a great means to detect the expansion of the current sinkholes and possible development of new sinkholes,” said Kim. “Monitoring the sinkholes and modeling the rate of change can help predict potential sinkhole development.”

Sentinel-1A data were obtained from Sentinels Scientific Data Hub – Copernicus. Groundwater well data came from the Texas Water Development Board. — Margaret Allen, SMU

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Dallas Morning News: North Texas dino had tough armor, keen sense of smell

Jacobs said large nostrils that look “like a trumpet bell” and wide air passages helped Pawpawsaurus smell predators, look for food or find mates.

Dallas Morning News journalist Charles Scudder covered the research of SMU Earth Sciences Professor Louis L. Jacobs in a Guide Live article “North Texas dino had tough armor, keen sense of smell.”

A professor in Dedman College‘s Roy M. Huffington Department of Earth Sciences, Jacobs is co-author of a new analysis of the Cretaceous Period dinosaur Pawpawsaurus based on the first CT scans ever taken of the dinosaur’s skull.

A Texas native from what is now Tarrant County, Pawpawsaurus lived 100 million years ago, making its home along the shores of an inland sea that split North America from Texas northward to the Arctic Sea.

The Dallas Morning News article published May 27, 2016.

Pawpawsaurus campbelli is the prehistoric cousin of the well-known armored dinosaur Ankylosaurus, famous for a hard knobby layer of bone across its back and a football-sized club on its tail.

Jacobs, a world-renowned vertebrate paleontologist, joined SMU’s faculty in 1983 and in 2012 was honored by the 7,200-member Science Teachers Association of Texas with their prestigious Skoog Cup for his significant contributions to advance quality science education.

Jacobs is president of SMU’s Institute for the Study of Earth and Man.

Read the full story.

EXCERPT:

By Charles Scudder
Dallas Morning News

A prehistoric skull found 24 years ago by a teenager in Fort Worth is now helping scientists understand the brain functions of a North Texas native. Pawpawsaurus campbelli lived 100 million years ago and was identified in 1996 by Yuong-Nam Lee, then a doctoral student at Southern Methodist University.

Lee and Louis Jacobs, a paleontologist at SMU, have co-authored a new paper that used CT imaging to study the brain of Pawpawsaurus. It’s the first time we’ve seen inside the Pawpawsaurus skull, as few studies have been done on the endocranial anatomy — scientist-speak for brain and skull — of its biological family.

This North Texas dino is named for the Paw Paw Formation, a geological feature where fossils are found in Texas. It lived on the shores of an inland sea that stretched from the Gulf coast to the Arctic. Think the Narrow Sea from Game of Thrones. Dallas is somewhere around Valyria. Arizona is Dorne.

Pawpawsaurus was a herbivore with armored plates on its back and eyelids, but without the clubbed tail characteristic of its younger cousin, Ankylosaurus. It didn’t have the stable vision of Ankylosaurus that helped it wield the clubbed tail. And although Pawpawsaurus had impressive sensory ability compared to its contemporaries, it was still less-evolved than Ankylosaurus.

Read the full story.

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Live Science: Dino Senses: Ankylosaurus Cousin Had a Super Sniffer

Louis Jacobs is co-author of a new analysis of the Cretaceous dinosaur Pawpawsaurus based on the first CT scans ever taken of the dinosaur’s skull.

Science journalist Laura Geggel covered the research of SMU Earth Sciences Professor Louis L. Jacobs in her article “Dino Senses: Ankylosaurus Cousin Had a Super Sniffer.”

A professor in Dedman College‘s Roy M. Huffington Department of Earth Sciences, Jacobs is co-author of a new analysis of the Cretaceous Period dinosaur Pawpawsaurus based on the first CT scans ever taken of the dinosaur’s skull.

A Texas native from what is now Tarrant County, Pawpawsaurus lived 100 million years ago, making its home along the shores of an inland sea that split North America from Texas northward to the Arctic Sea.

Pawpawsaurus campbelli is the prehistoric cousin of the well-known armored dinosaur Ankylosaurus, famous for a hard knobby layer of bone across its back and a football-sized club on its tail.

Jacobs, a world-renowned vertebrate paleontologist, joined SMU’s faculty in 1983 and in 2012 was honored by the 7,200-member Science Teachers Association of Texas with their prestigious Skoog Cup for his significant contributions to advance quality science education.

Jacobs is president of SMU’s Institute for the Study of Earth and Man.

Read the full story.

EXCERPT:

By Laura Geggel
Live Science

The armored cousin of the Ankylosaurus dinosaur didn’t have a football-size club on its tail, but it did have a super sense of smell, said scientists who examined its skull.

The Cretaceous-age Pawpawsaurus campbelli walked on all fours and lived in ancient Texas about 100 million years ago, the researchers said. It was an earlier version, so to speak, of the heavily armored Ankylosaurus, which lived about 35 million years later, they said.

But even without an impressive tail club, P. campbelli wasn’t totally defenseless. It sported armored plates on its back and eyelids. A computerized tomography (CT) scan of its braincase also suggests that the dinosaur had an excellent sense of smell for finding prey and avoiding predators.

“CT imaging has allowed us to delve into the intricacies of the brains of extinct animals, especially dinosaurs, to unlock secrets of their ways of life,” study co-author Louis Jacobs, a vertebrate paleontologist at Southern Methodist University in Dallas, Texas, said in a statement.

P. campbelli could have outsniffed other primitive dinosaur predators, including Ceratosaurus, a bipedal, meat-eating dinosaur with blade-like teeth and a horn on its snoutthat lived during the Jurassic period, the researchers said.

CT scans suggest that P. campbelli’s sense of smell — calculated by comparing the size of the brain’s olfactory bulb to the cerebral hemisphere — is somewhat less powerful than that of Ankylosaurus, said study lead researcher Ariana Paulina-Carabajal, a vertebrate paleontologist at the Biodiversity and Environment Research Institute (CONICET-INIBIOMA) in San Carlos de Bariloche, Argentina.

“Although both [P. campbelli and Ankylosaurus] have high ratios when compared with most carnivorous dinosaurs,” she said, “they are exceeded only by carcharodontosaurids and tyrannosaurids.”

Read the full story.