Newswise — Imagine descending nearly a mile and a half into a watery abyss, watching the sunlight disappear as the world around you turns completely black. Then suddenly, you find yourself surrounded by a shower of brilliant, bioluminescent fireworks.

This is just the beginning of an ocean expedition into the realm of deep-sea hydrothermal vents — alien ecosystems teeming with life we have yet to fully understand. Here, a place where the sunlight never reaches, crabs, rays and fish thrive even under the extreme hydrostatic pressure.

A team of intrepid researchers from Arizona State University embarked on a recent journey to these hidden depths to learn more about nitrogen cycling and the microbial life thriving in these extreme conditions. These microscopic organisms play a vital role in the ocean’s delicate chemistry.

“I think the deep sea is one of the final frontiers of exploration on Earth,” said Carolynn Harris, a postdoctoral researcher in ASU’s School of Earth and Space Exploration. “We know more about the surface of the moon than we know about the bottom of the ocean on our own planet.”

Sheryl Murdock, a postdoctoral research scholar with ASU’s School of Ocean Futures, part of the Julie Ann Wrigley Global Futures Laboratory, led the expedition along with Elizabeth Trembath-Reichert, an associate professor with the School of Earth and Space Exploration. Six ASU students and staff participated, working on everything from taking samples and planning the next day’s dive, to testing equipment and leading the team’s experiments and school outreach.

Murdock and her research team are working to understand exactly what the smallest inhabitants of the ocean are contributing to ocean chemistry. While microbes are tiny, they have a tremendous impact, and Murdock says they’re not something that gets thought about often when it comes to protecting and managing the ocean.

“Nobody’s going to buy the ‘save the microbes’ bumper sticker,” Murdock said. “We need the public to know that the way the chemistry of the ocean stays in balance has loads to do with microbes and how they cycle nitrogen and other chemical elements. And by understanding what microbes contribute, we can learn how that plays into the wider ocean chemistry and, importantly, ocean health.”

One way the researchers learn more is by taking samples of microbes that thrive under deep-sea pressure — gathered from water and sediment samples. But this team is trying something that has never been done before.

“We are working to understand the microbes living in tubeworm communities by sampling the fluids and then bringing the water back onto the ship, running incubations, and looking at how those microbes use different sources of nitrogen,” Murdock said. “What’s novel about this is bringing them to the surface but keeping them under seafloor pressure and running experiments at that high pressure.”

This process is difficult at best. The team must travel far out to sea on a ship called the R/V Atlantis — a U.S. Navy-owned research vessel operated by the Woods Hole Oceanographic Institution. This ship is designed specifically to launch Alvin, a specialized “human occupied vehicle,” or HOV, used by researchers to explore the deep sea.

Once the team reached its final destination in the Pacific northwest — a spreading center between tectonic plates called the Juan de Fuca Ridge — the team performed multiple dives in the submersible, as weather conditions allowed.

Their innovative approach to collecting water, sediment and microbial samples — bringing them to the surface under the same pressure — is expected to bring new insights to our understanding of ocean chemistry, what roles microbes play on the seafloor, and how they contribute to ecosystem health and function.

Ship to shore: Bringing deep-sea exploration to the classroom

Beyond the scientific breakthroughs, the expedition sparked a wave of inspiration among hundreds of students back on land. The cruise carried a dedicated outreach team — responsible for a ship-to-shore “virtual field trip” program that brought live video, interviews and demonstrations into classrooms thousands of miles away.

Will Carter, an outreach coordinator with the ASU Bermuda Institute of Ocean Sciences, or BIOS, helped build the pipeline.

“We had a full Zoom setup,” Carter said, describing a dizzying array of gear: a handheld gimbal and iPhone for roaming footage, a 360 conference camera to show a room, and microphones that had to survive both wind and poor bandwidth. “You can imagine with all of these different tech elements, especially being on a ship where there’s limited Wi-Fi, it took a long time to really set up and master.”

Carter, who has a background in biology and media studies, edited dive footage each night and crafted short, punchy videos for the next day’s calls. Their goal was modest at first — reach a few hundred students — but the appetite for real-time science grew fast.

For students at Osborne Middle School in Phoenix, the experience wasn’t a distant slideshow. Science teacher Jim Hess watched his seventh and eighth graders press toward the screen, leaning in to see hydrothermal chimneys and hear Alvin crew explain life in a tin can at the bottom of the world.

“They decorated Styrofoam cups before the team left to go to the boat,” Hess said. The cups were taken down on the outside of the submersible; at 2,300 meters (more than six Empire State Buildings) deep, the air is crushed out of the foam. “Your regular six-inch Styrofoam cup shrinks down to about the size of your thumb,” he told students. The cups were returned as tiny souvenirs — a reminder that sometimes science is a tactile thrill as much as it is data.

Middle schoolers asked the questions adults skip. 

“How do you use the bathroom?” one asked. And the answer — “you try to go before, and if not, then you go on this little red bedpan” — produced exactly the reaction the outreach team wanted: awe and laughter, followed by curiosity. 

“Those middle school questions,” Carter said, “are perfect.”

From the beginning, the ship-to-shore goal was simple but ambitious: bring real impact and working science directly to students in real time, as discovery is unfolding live.

“We knew to get this over the goal line, it couldn’t just be creating a curriculum module,” said Kaitlin Noyes, director of education and community engagement at ASU BIOS. “It needed to be something bigger.” 

That “something bigger” became a series of live broadcasts from the research vessel and the submersible using special communications tools, connecting students from third grade through college — and even professional educators — to science, as it was happening at sea.

Over the course of the two-week expedition, they hosted 29 live shows and reached 857 participants.

“A lot of these kids have never had interaction with anything outside of their immediate area,” Hess said. “They hear about ASU, but they don’t really know what that means. This shows them the world is bigger — and that they can be part of it.”

From under the sea to under the microscope

Back on deck, the science had its own setbacks: rough weather grounded dives, forcing the team to compress their goals into fewer opportunities. Harris described how team dynamics became essential in cramped, chilly, sometimes seasick conditions.

“Anytime you take a group of people and put them in a confined, isolated situation, the group dynamics are so important,” she said. “We had a quarter fewer dives than we had hoped, but we still accomplished all of our major science objectives.”

Now the team’s samples — including water, sediments and microbes — will be analyzed. The next phase will take time and precision: sequencing DNA from microbes, measuring nitrogen species and piecing together how these unseen organisms move nutrients through a world without sunlight.

As the team measures the samples over the next several months, the researchers share a message: The deep sea is not a desolate wasteland but a vibrant ecosystem facing unprecedented threats due to climate impacts, overfishing and bottom-trawling, pollution and potential deep-sea mining.

“Industrialization of the deep sea is really knocking at the door,” Murdock said. “Our research is but one important step to reaching a better understanding of how our ocean works, and by doing that, we hope to contribute to strategies that ensure future ocean health.”

Corpses leave clues behind in the soil long after they’re gone

ASU research has potential to help forensic teams solve cases when a victim’s body has been moved

Newswise — President’s Professor Pamela Marshall (left) and Assistant Professor Katelyn Bolhofner pose with soil samples in one of their labs on Thursday, Feb. 19, on the West Valley campus. The researchers analyze the microbial and chemical traces left behind when remains are moved, uncovering patterns of postmortem change that can guide forensic investigations. Photo by Charlie Leight/ASU News.  Download article assets

 It is not uncommon for a body to be moved after a murder, usually to hide or eliminate evidence.

And while the Arizona desert may seem like the perfect place to commit such a crime, a new study shows that a cadaver can still leave critical clues behind in that harsh environment.

Arizona State University researchers have found that trace elements linger at an original dump site even after an extensive amount of time. These elements can provide insights into postmortem processes, helping forensic investigators uncover clandestine burials and relocate the remains of murder victims.

“A lot of times a murderer will kill someone and put the body somewhere, stash it, panic and then move it. And how can you ever trace where they have done this?” said Assistant Professor Katelyn Bolhofner with the School of Interdisciplinary Forensics, who collaborated with President’s Professor Pam Marshall from the School of Mathematical and Natural Sciences on the study.

“The surprising result was that even with the hot Arizona summer, we could still tell that there had been something that was dying and decomposing in that spot in the desert,” Bolhofner said.

Uncovering signatures in the soil

Prior to the study, Bolhofner and Marshall believed that any evidence on the original site of a transported body would be baked under Arizona’s scorching summer sun.

That was far from the case.

The study used two 200-pound pig models that were dressed up in jeans and a button-up shirt by students, since murder victims are commonly clothed. They were left to decompose in large cages (to keep scavenging animals away) in various environments and seasons in the Sonoran Desert.

After 25 days, the remains were moved to a secondary burial location. Then, over a period of nine months, the researchers tested the soil where the model was originally placed, where it was moved and in a location adjacent to the original burial as a control.

“It’s a multifaceted, year-round project to try to determine timing, insects involved, and the humidity and the temperature and many other of these factors,” Bolhofner said.

What they found were distinct microbial fingerprints where death gave way to new life — bacteria and fungi that once lived inside or on the body and were released into the surrounding ground as decomposition occurred.

“It turned out to be a really crazy finding,” Bolhofner said. “It’s like the murder victim is leaving a signature of themselves in death … almost like leaving breadcrumbs right around the desert (indicating) that they had been there, and those breadcrumbs stayed there in the soil, invisible to the naked eye for a year.”

“No one has ever done an experiment like this,” Marshall said. “It was unique because no one had looked at a dumped body that was then moved. It was also unusual because no one’s been looking at the Sonoran Desert.”

It’s like the murder victim is leaving a signature of themselves in death … almost like leaving breadcrumbs right around the desert.

Kaitlyn BolhofnerAssistant professor of forensics

Counting on collaboration

The study was a collective and collaborative effort.

ASU graduate Jennifer Matta Salinas worked on the study for her honors thesis. She collected and processed the data, and extracted DNA for the study.

“I felt like my results definitely opened the door to a novel area of forensic science that has many avenues to explore and to still verify,” said Salinas, who earned a bachelor’s degree in forensic science. “I’m hoping someday it is used to help find someone’s loved ones months or years after their disappearance no matter where the environment is.”

The DNA was then prepped and analyzed by Kristina Buss in ASU’s Bioinformatics Facility and Desert Southwest Genomics Center, and Teaching Professor Ken G. Sweat performed the chemical analysis of the soil.

“We here in the School of Mathematical and Natural Sciences and the School of Interdisciplinary Forensics are very collaborative — we depend on each other,” Marshall said. “Without Jennifer needing to write her thesis, this wouldn’t have happened. Without Ken doing the elemental analysis, that part wouldn’t have happened either.”

Future forensic potential

Stuart Somershoe, a retired police detective with the Phoenix Police Department’s missing-persons division, was also a part of the project.

According to the World Population Review, Arizona has one of the highest number of missing persons in the nation, with more than 1,000 people missing and 1,588 resolved cases in 2025.

Somershoe says the desert plays into those statistics. He sees the potential application of this study in cold cases and missing persons cases both now and in the future.

“I read the study and could see the value in police investigations,” Somershoe said. “It would certainly be something that could be used.”

Somershoe said that as this research develops and becomes more well-known, it could become a technique as commonly used as DNA testing.

But first, more experiments and studies will be needed.

“We’re way in our infancy,” Marshall said.

The researchers are interested in taking the study on the road to see if the findings can be confirmed in other climates, but Marshall is hopeful.

“This study is really specific to this climate and this landscape and this geography,” Marshall said. “Our soil and our climate (are) so harsh and so odd. The fact that this can be proven here should show that in other climates, it’s much more doable. Those climates are much friendlier.”

The researchers also plan to verify that human remains would yield similar results.

“We need to confirm that the things we’re seeing in pigs are the same in humans,” she said. “We need to figure out how what we have discovered is transferable.”

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