Measuring cesium in wild boar and uranium in turtles sheds light on how radioactive materials travel through the environment. Plus, a new study explains why wide receivers on professional football teams feel slimmer and faster when they wear smaller numbers.
Scientists using the James Webb Space Telescope made an exciting discovery this week: Exoplanet K2-18 b, 120 light years away from our solar system, could be covered by a water ocean, similar to Earth. Astronomers say this could be a big leap in our exploration of life on other planets.
This news comes amid another JWST discovery: The earliest black holes seem to be much larger than black holes today. This news also provides evidence that black holes can form without stars, a theorized phenomenon that has never been directly observed.
Joining Ira to talk about these and other science stories of the week is Tim Revell, Deputy U.S. Editor of New Scientist, based in New York, New York.
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When you hear the words “radioactive wildlife,” your brain probably jumps to Chernobyl’s wolves, which—despite the odds—are still thriving at the site of the nuclear disaster. Or maybe you’ve heard of the rat snakes in Fukushima that pick up radioactive contamination as they slither around.
Well, it’s time to add two more to that list of radioactive critters: turtles and wild boar. They’re the subjects of two new studies that looked at radioactivity in wildlife and mapped out where it came from.Â
Ira talks with Dr. Cyler Conrad, archaeologist at Pacific Northwest National Lab in Richland, Washington who worked on the turtle study, and Dr. Georg Steinhauser, professor of applied radiochemistry at the Vienna University of Technology in Austria, who studied boar. They chat about the two studies, how wildlife can clue us into radioactive contamination, and what we can learn from critters in nuclear fallout zones.
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It was a hot summer day and Glory Medina and her daughter Jade, who was 3 at the time, were running a quick errand at the grocery store near their apartment in Gulfton. They had taken the bus and once they arrived, the two of them faced a giant unshaded parking lot, the black asphalt radiating heat into their faces as they walked across it.
The blast of AC felt cool as they entered the store, and Medina bent down to lift her daughter into the grocery cart. That’s when she noticed Jade’s face was red, almost purple.
“I got scared,” Medina said in Spanish, remembering that day four years ago.
Read more at sciencefriday.com.
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Football season is officially here, with the NFL’s first game kicking off last Sunday. And if you’ve been watching the sport for a long time, you may have noticed some changes: better-padded helmets meant to reduce serious brain injury, new “sticky” gloves that make it easier for players to hold the ball, and lighter-weight jerseys that make it harder for other players to grab onto. But you’ll also notice the numbers on those jerseys are different, too.
For most of the NFL’s history, wide receivers could only pick jersey numbers between 80 and 89. But in 2004, the league relaxed this policy, allowing players to also pick numbers between 10 and 19. Many players preferred these smaller values explaining that the 1 looked slimmer than the 8, and made them feel thinner and faster. As of 2019, 80% of wide receivers made the switch.
But is there an actual association between smaller numbers and perception of body size?
To investigate whether this was fact or superstition, Dr. Ladan Shams, professor of psychology, bioengineering, and neuroscience at UCLA, ran a study that found those wide receivers were onto something: the results suggest there is a correlation between smaller numbers and perceived body size. Her team’s research was published in PLOS One. She joins Ira to talk about the study and what it could tell us about implicit bias.
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