show some love for the losers Delightfully irreverent Underdogs isn’t your parents’ nature docuseries Ryan Reynolds narrates NatGeo's new series highlighting nature's much less cool and majestic creatures Jennifer Ouellette – Jun 15, 2025 3:11 pm | 5 The indestructible honey badger is just one of nature's "benchwarmers" featured in Underdogs Credit: National Geographic/Doug Parker The indestructible honey badger is just one of nature's "benchwarmers" featured in Underdogs Credit: National Geographic/Doug Parker Story text Size Small Standard Large Width * Standard Wide Links Standard Orange * Subscribers only   Learn more Narrator Ryan Reynolds celebrates nature's outcasts in the new NatGeo docuseries Underdogs. Most of us have seen a nature documentary or two (or three) at some point in our lives, so it's a familiar format: sweeping majestic footage of impressively regal animals accompanied by reverently high-toned narration (preferably with a tony British accent). Underdogs, a new docuseries from National Geographic, takes a decidedly different and unconventional approach. Narrated by with hilarious irreverence by Ryan Reynolds, the five-part series highlights nature's less cool and majestic creatures: the outcasts and benchwarmers, more noteworthy for their "unconventional hygiene choices" and "unsavory courtship rituals." It's like The Suicide Squad or Thunderbolts*, except these creatures actually exist. Per the official premise, "Underdogs features a range of never-before-filmed scenes, including the first time a film crew has ever entered a special cave in New Zealand—a huge cavern that glows brighter than a bachelor pad under a black light thanks to the glowing butts of millions of mucus-coated grubs. All over the world, overlooked superstars like this are out there 24/7, giving it maximum effort and keeping the natural world in working order for all those showboating polar bears, sharks and gorillas." It's rated PG-13 thanks to the odd bit of scatalogical humor and shots of Nature Sexy Time Each of the five episodes is built around a specific genre. "Superheroes" highlights the surprising superpowers of the honey badger, pistol shrimp, and the invisible glass frog, among others, augmented with comic book graphics; "Sexy Beasts" focuses on bizarre mating habits and follows the format of a romantic advice column; "Terrible Parents" highlights nature's worst practices, following the outline of a parenting guide; "Total Grossout" is exactly what it sounds like; and "The Unusual Suspects" is a heist tale, documenting the supposed efforts of a macaque to put together the ultimate team of masters of deception and disguise (an inside man, a decoy, a fall guy, etc.).  Green Day even wrote and recorded a special theme song for the opening credits. Co-creators Mark Linfield and Vanessa Berlowitz of Wildstar Films are longtime producers of award-winning wildlife films, most notably Frozen Planet, Planet Earth and David Attenborough's Life of Mammals—you know, the kind of prestige nature documentaries that have become a mainstay for National Geographic and the BBC, among others. They're justly proud of that work, but this time around the duo wanted to try something different. Madagascar's aye-aye: "as if fear and panic had a baby and rolled it in dog hair" National Geographic/Eleanor Paish Madagascar's aye-aye: "as if fear and panic had a baby and rolled it in dog hair" National Geographic/Eleanor Paish An emerald jewel wasp emerges from a cockroach. National Geographic/Simon De Glanville An emerald jewel wasp emerges from a cockroach. National Geographic/Simon De Glanville A pack of African hunting dogs is no match for the honey badger's thick hide. National Geographic/Tom Walker A pack of African hunting dogs is no match for the honey badger's thick hide. National Geographic/Tom Walker An emerald jewel wasp emerges from a cockroach. National Geographic/Simon De Glanville A pack of African hunting dogs is no match for the honey badger's thick hide. National Geographic/Tom Walker A fireworm is hit by a cavitation bubble shot from the claw of a pistol shrimp defending its home. National Geographic/Hugh Miller As it grows and molts, the mad hatterpillar stacks old head casings on top of its head. Scientists think it is used as a decoy against would-be predators and parasites, and when needed, it can also be used as a weapon. National Geographic/Katherine Hannaford Worst parents ever? A young barnacle goose chick prepares t make the 800-foot jump from its nest to the ground. National Geographic An adult pearlfish reverses into a sea cucumber's butt to hide. National Geographic A vulture sticks its head inside an elephant carcass to eat. National Geographic A manatee releases flatulence while swimming to lose the buoyancy build up of gas inside its stomach, and descend down the water column. National Geographic/Karl Davies "There is a sense after awhile that you're playing the same animals to the same people, and the shows are starting to look the same and so is your audience," Linfield told Ars. "We thought, okay, how can we do something absolutely the opposite? We've gone through our careers collecting stories of these weird and crazy creatures that don't end up in the script because they're not big or sexy and they live under a rock. But they often have the best life histories and the craziest superpowers." Case in point: the velvet worm featured in the "Superheroes" episode, which creeps up on unsuspecting prey before squirting disgusting slime all over their food. (It's a handy defense mechanism, too, against predators like the wolf spider.) Once Linfield and Berlowitz decided to focus on nature's underdogs and to take a more humorous approach, Ryan Reynolds became their top choice for a narrator—the anti-Richard Attenborough. As luck would have it, the pair shared an agent with the mega-star. So even though they thought there was no way Reynolds would agree to the project, they put together a sizzle reel, complete with a "fake Canadian Ryan Reynolds sound-alike" doing the narration. Reynolds was on set when he received the reel, and loved it so much he recoded his own narration for the footage and sent it back. "From that moment he was in," said Linfield, and Wildstar Films worked closely with Reynolds and his company to develop the final series. "We've never worked that way on a series before, a joint collaboration from day one," Berlowitz admitted. But it worked: the end result strikes the perfect balance between scientific revelation and accurate natural history, and an edgy comic tone. That tone is quintessential Reynolds, and while he did mostly follow the script (which his team helped write), Linfield and Berlowitz admit there was also a fair amount of improvisation—not all of it PG-13.  "What we hadn't appreciated is that he's an incredible improv performer," said Berlowitz. "He can't help himself. He gets into character and starts riffing off [the footage]. There are some takes that we definitely couldn't use, that potentially would fit a slightly more Hulu audience."  Some of the ad-libs made it into the final episodes, however—like Reynolds describing an Aye-Aye as "if fear and panic had a baby and rolled it in dog hair"—even though it meant going back and doing a bit of recutting to get the new lines to fit. Cinematographer Tom Beldam films a long-tailed macaque who stole his smart phone minutes later. National Geographic/Laura Pennafort Cinematographer Tom Beldam films a long-tailed macaque who stole his smart phone minutes later. National Geographic/Laura Pennafort The macaque agrees to trade ithe stolen phone for a piece of food. National Geographic The macaque agrees to trade ithe stolen phone for a piece of food. National Geographic A family of tortoise beetles defend themselves from a carnivorous ant by wafting baby poop in its direction. National Geographic A family of tortoise beetles defend themselves from a carnivorous ant by wafting baby poop in its direction. National Geographic The macaque agrees to trade ithe stolen phone for a piece of food. National Geographic A family of tortoise beetles defend themselves from a carnivorous ant by wafting baby poop in its direction. National Geographic A male hippo sprays his feces at another male who is threatening to take over his patch. National Geographic A male proboscis monkey flaunts his large nose. The noses of these males are used to amplify their calls in the vast forest. National Geographic Dream girl: A blood-soaked female hyena looks across the African savanna. National Geographic A male bowerbird presents one of the finest items in his collection to a female in his bower. National Geographic The male nursery web spider presents his nuptial gift to the female. National Geographic Cue the Barry White mood music: Two leopard slugs suspend themselves on a rope of mucus as they entwine their bodies to mate with one another. National Geographic Despite their years of collective experience, Linfield and Berlowitz were initially skeptical when the crew told them about the pearl fish, which hides from predators in a sea cucumber's butt (along with many other species). "It had never been filmed so we said, 'You're going to have to prove it to us,'" said Berlowitz. "They came back with this fantastic, hilarious sequence of a pearl fish reverse parking [in a sea cucumber's anus)." The film crew experienced a few heart-pounding moments, most notably while filming the cliffside nests of barnacle geese for the "Terrible Parents" episode. A melting glacier caused a watery avalanche while the crew was filming the geese, and they had to quickly grab a few shots and run to safety. Less dramatic: cinematographer Tom Beldam had his smartphone stolen by a long-tailed macaque mere minutes after he finished capturing the animal on film. If all goes well and Underdogs finds its target audience, we may even get a follow-up. "We are slightly plowing new territory but the science is as true as it's ever been and the stories are good. That aspect of the natural history is still there," said Linfield. "I think what we really hope for is that people who don't normally watch natural history will watch it. If people have as much fun watching it as we had making it, then the metrics should be good enough for another season." Verdict: Underdogs is positively addictive; I binged all five episodes in a single day. (For his part, Reynolds said in a statement that he was thrilled to "finally watch a project of ours with my children. Technically they saw Deadpool and Wolverine but I don't think they absorbed much while covering their eyes and ears and screaming for two hours.") Underdogs premieres June 15, 2025, at 9 PM/8 PM Central on National Geographic (simulcast on ABC) and will be available for streaming on Disney+ and Hulu the following day.  You should watch it, if only to get that second season. Jennifer Ouellette Senior Writer Jennifer Ouellette Senior Writer Jennifer is a senior writer at Ars Technica with a particular focus on where science meets culture, covering everything from physics and related interdisciplinary topics to her favorite films and TV series. Jennifer lives in Baltimore with her spouse, physicist Sean M. Carroll, and their two cats, Ariel and Caliban. 5 Comments

Best of the rest Research roundup: 7 stories we almost missed Also: drumming chimpanzees, picking styles of two jazz greats, and an ancient underground city's soundscape Jennifer Ouellette – May 31, 2025 5:37 pm | 4 Time lapse photos show a new ping-pong-playing robot performing a top spin. Credit: David Nguyen, Kendrick Cancio and Sangbae Kim Time lapse photos show a new ping-pong-playing robot performing a top spin. Credit: David Nguyen, Kendrick Cancio and Sangbae Kim Story text Size Small Standard Large Width * Standard Wide Links Standard Orange * Subscribers only   Learn more It's a regrettable reality that there is never time to cover all the interesting scientific stories we come across each month. In the past, we've featured year-end roundups of cool science stories we (almost) missed. This year, we're experimenting with a monthly collection. May's list includes a nifty experiment to make a predicted effect of special relativity visible; a ping-pong playing robot that can return hits with 88 percent accuracy; and the discovery of the rare genetic mutation that makes orange cats orange, among other highlights. Special relativity made visible Credit: TU Wien Perhaps the most well-known feature of Albert Einstein's special theory of relativity is time dilation and length contraction. In 1959, two physicists predicted another feature of relativistic motion: an object moving near the speed of light should also appear to be rotated. It's not been possible to demonstrate this experimentally, however—until now. Physicists at the Vienna University of Technology figured out how to reproduce this rotational effect in the lab using laser pulses and precision cameras, according to a paper published in the journal Communications Physics. They found their inspiration in art, specifically an earlier collaboration with an artist named Enar de Dios Rodriguez, who collaborated with VUT and the University of Vienna on a project involving ultra-fast photography and slow light. For this latest research, they used objects shaped like a cube and a sphere and moved them around the lab while zapping them with ultrashort laser pulses, recording the flashes with a high-speed camera. Getting the timing just right effectively yields similar results to a light speed of 2 m/s. After photographing the objects many times using this method, the team then combined the still images into a single image. The results: the cube looked twisted and the sphere's North Pole was in a different location—a demonstration of the rotational effect predicted back in 1959. DOI: Communications Physics, 2025. 10.1038/s42005-025-02003-6  (About DOIs). Drumming chimpanzees A chimpanzee feeling the rhythm. Credit: Current Biology/Eleuteri et al., 2025. Chimpanzees are known to "drum" on the roots of trees as a means of communication, often combining that action with what are known as "pant-hoot" vocalizations (see above video). Scientists have found that the chimps' drumming exhibits key elements of musical rhythm much like humans, according to  a paper published in the journal Current Biology—specifically non-random timing and isochrony. And chimps from different geographical regions have different drumming rhythms. Back in 2022, the same team observed that individual chimps had unique styles of "buttress drumming," which served as a kind of communication, letting others in the same group know their identity, location, and activity. This time around they wanted to know if this was also true of chimps living in different groups and whether their drumming was rhythmic in nature. So they collected video footage of the drumming behavior among 11 chimpanzee communities across six populations in East Africa (Uganda) and West Africa (Ivory Coast), amounting to 371 drumming bouts. Their analysis of the drum patterns confirmed their hypothesis. The western chimps drummed in regularly spaced hits, used faster tempos, and started drumming earlier during their pant-hoot vocalizations. Eastern chimps would alternate between shorter and longer spaced hits. Since this kind of rhythmic percussion is one of the earliest evolved forms of human musical expression and is ubiquitous across cultures, findings such as this could shed light on how our love of rhythm evolved. DOI: Current Biology, 2025. 10.1016/j.cub.2025.04.019  (About DOIs). Distinctive styles of two jazz greats Jazz lovers likely need no introduction to Joe Pass and Wes Montgomery, 20th century guitarists who influenced generations of jazz musicians with their innovative techniques. Montgomery, for instance, didn't use a pick, preferring to pluck the strings with his thumb—a method he developed because he practiced at night after working all day as a machinist and didn't want to wake his children or neighbors. Pass developed his own range of picking techniques, including fingerpicking, hybrid picking, and "flat picking." Chirag Gokani and Preston Wilson, both with Applied Research Laboratories and the University of Texas, Austin, greatly admired both Pass and Montgomery and decided to explore the underlying the acoustics of their distinctive playing, modeling the interactions of the thumb, fingers, and pick with a guitar string. They described their research during a meeting of the Acoustical Society of America in New Orleans, LA. Among their findings: Montgomery achieved his warm tone by playing closer to the bridge and mostly plucking at the string. Pass's rich tone arose from a combination of using a pick and playing closer to the guitar neck. There were also differences in how much a thumb, finger, and pick slip off the string:  use of the thumb (Montgomery) produced more of a "pluck" compared to the pick (Pass), which produced more of a "strike." Gokani and Wilson think their model could be used to synthesize digital guitars with a more realistic sound, as well as helping guitarists better emulate Pass and Montgomery. Sounds of an ancient underground city Credit: Sezin Nas Turkey is home to the underground city Derinkuyu, originally carved out inside soft volcanic rock around the 8th century BCE. It was later expanded to include four main ventilation channels (and some 50,000 smaller shafts) serving seven levels, which could be closed off from the inside with a large rolling stone. The city could hold up to 20,000 people and it  was connected to another underground city, Kaymakli, via tunnels. Derinkuyu helped protect Arab Muslims during the Arab-Byzantine wars, served as a refuge from the Ottomans in the 14th century, and as a haven for Armenians escaping persecution in the early 20th century, among other functions. The tunnels were rediscovered in the 1960s and about half of the city has been open to visitors since 2016. The site is naturally of great archaeological interest, but there has been little to no research on the acoustics of the site, particularly the ventilation channels—one of Derinkuyu's most unique features, according to Sezin Nas, an architectural acoustician at Istanbul Galata University in Turkey.  She gave a talk at a meeting of the Acoustical Society of America in New Orleans, LA, about her work on the site's acoustic environment. Nas analyzed a church, a living area, and a kitchen, measuring sound sources and reverberation patterns, among other factors, to create a 3D virtual soundscape. The hope is that a better understanding of this aspect of Derinkuyu could improve the design of future underground urban spaces—as well as one day using her virtual soundscape to enable visitors to experience the sounds of the city themselves. MIT's latest ping-pong robot Robots playing ping-pong have been a thing since the 1980s, of particular interest to scientists because it requires the robot to combine the slow, precise ability to grasp and pick up objects with dynamic, adaptable locomotion. Such robots need high-speed machine vision, fast motors and actuators, precise control, and the ability to make accurate predictions in real time, not to mention being able to develop a game strategy. More recent designs use AI techniques to allow the robots to "learn" from prior data to improve their performance. MIT researchers have built their own version of a ping-pong playing robot, incorporating a lightweight design and the ability to precisely return shots. They built on prior work developing the Humanoid, a small bipedal two-armed robot—specifically, modifying the Humanoid's arm by adding an extra degree of freedom to the wrist so the robot could control a ping-pong paddle. They tested their robot by mounting it on a ping-pong table and lobbing 150 balls at it from the other side of the table, capturing the action with high-speed cameras. The new bot can execute three different swing types (loop, drive, and chip) and during the trial runs it returned the ball with impressive accuracy across all three types: 88.4 percent, 89.2 percent, and 87.5 percent, respectively. Subsequent tweaks to theirrystem brought the robot's strike speed up to 19 meters per second (about 42 MPH), close to the 12 to 25 meters per second of advanced human players. The addition of control algorithms gave the robot the ability to aim. The robot still has limited mobility and reach because it has to be fixed to the ping-pong table but the MIT researchers plan to rig it to a gantry or wheeled platform in the future to address that shortcoming. Why orange cats are orange Credit: Astropulse/CC BY-SA 3.0 Cat lovers know orange cats are special for more than their unique coloring, but that's the quality that has intrigued scientists for almost a century. Sure, lots of animals have orange, ginger, or yellow hues, like tigers, orangutans, and golden retrievers. But in domestic cats that color is specifically linked to sex. Almost all orange cats are male. Scientists have now identified the genetic mutation responsible and it appears to be unique to cats, according to a paper published in the journal Current Biology. Prior work had narrowed down the region on the X chromosome most likely to contain the relevant mutation. The scientists knew that females usually have just one copy of the mutation and in that case have tortoiseshell (partially orange) coloring, although in rare cases, a female cat will be orange if both X chromosomes have the mutation. Over the last five to ten years, there has been an explosion in genome resources (including complete sequenced genomes) for cats which greatly aided the team's research, along with taking additional DNA samples from cats at spay and neuter clinics. From an initial pool of 51 candidate variants, the scientists narrowed it down to three genes, only one of which was likely to play any role in gene regulation: Arhgap36. It wasn't known to play any role in pigment cells in humans, mice, or non-orange cats. But orange cats are special; their mutation (sex-linked orange) turns on Arhgap36 expression in pigment cells (and only pigment cells), thereby interfering with the molecular pathway that controls coat color in other orange-shaded mammals. The scientists suggest that this is an example of how genes can acquire new functions, thereby enabling species to better adapt and evolve. DOI: Current Biology, 2025. 10.1016/j.cub.2025.03.075  (About DOIs). Not a Roman "massacre" after all Credit: Martin Smith In 1936, archaeologists excavating the Iron Age hill fort Maiden Castle in the UK unearthed dozens of human skeletons, all showing signs of lethal injuries to the head and upper body—likely inflicted with weaponry. At the time, this was interpreted as evidence of a pitched battle between the Britons of the local Durotriges tribe and invading Romans. The Romans slaughtered the native inhabitants, thereby bringing a sudden violent end to the Iron Age. At least that's the popular narrative that has prevailed ever since in countless popular articles, books, and documentaries. But a paper published in the Oxford Journal of Archaeology calls that narrative into question. Archaeologists at Bournemouth University have re-analyzed those burials, incorporating radiocarbon dating into their efforts. They concluded that those individuals didn't die in a single brutal battle. Rather, it was Britons killing other Britons over multiple generations between the first century BCE and the first century CE—most likely in periodic localized outbursts of violence in the lead-up to the Roman conquest of Britain. It's possible there are still many human remains waiting to be discovered at the site, which could shed further light on what happened at Maiden Castle. DOI: Oxford Journal of Archaeology, 2025. 10.1111/ojoa.12324  (About DOIs). Jennifer Ouellette Senior Writer Jennifer Ouellette Senior Writer Jennifer is a senior writer at Ars Technica with a particular focus on where science meets culture, covering everything from physics and related interdisciplinary topics to her favorite films and TV series. Jennifer lives in Baltimore with her spouse, physicist Sean M. Carroll, and their two cats, Ariel and Caliban. 4 Comments

here comes the boom! Falcon 9 sonic booms can feel more like seismic waves Trajectories, wind shear, temperature gradients, topography, and weather can affect how a sonic boom spreads. Jennifer Ouellette – May 27, 2025 12:36 pm | 1 A Falcon 9 rocket lifted SPHEREx into orbit in March. Credit: NASA/Jim Ross A Falcon 9 rocket lifted SPHEREx into orbit in March. Credit: NASA/Jim Ross Story text Size Small Standard Large Width * Standard Wide Links Standard Orange * Subscribers only   Learn more The Vandenberg Space Force Base in Santa Barbara, California, serves military space launch missions as well as launches for NASA and commercial entities like SpaceX. But how do all those launches affect residents living along the Central Coast? People might marvel at the spectacular visual display, but as launch activity at the base has ramped up, so have the noise complaints, particularly about the sonic booms produced by Falcon 9 launches, which can reach as far south as Ventura County. The booms rattle windows, frighten pets, and have raised concerns about threats to the structural integrity of private homes. There have been rockets launching from Vandenberg for decades, so why are the Falcon 9 launches of such concern? "Because of the Starlink satellites, the orbital mechanics for where they're trying to place these in orbit is bringing [the trajectories] closer to the coast," said Brigham Young University's Kent Gee, who described his research into sonic boom effects on neighboring communities in a press briefing at a meeting of the Acoustical Society of America in New Orleans. And the launches are occurring much more frequently, from two to three launches per year in the 1980s to between five and seven launches each month today. There were 46 Falcon 9 launches out of the Vandenberg base in 2024 alone, per Gee. Gee joined a project called ECOBOOM (Environmental and Community Observation of Sonic Booms) to study the factors that can impact just how jarring those sonic booms might be, conducted jointly by BYU and California State University, Bakersfield, with cooperation from the Space Force. "Space Force is interested in this because they feel a sense of stewardship," said Gee. "These rockets from SpaceX and other providers are launched from the base for a variety of missions and they want to understand the effects both on and off base, trying to understand how they can complete the mission while minimizing [negative] impacts." Gee and his cohorts monitored 132 separate sonic booms last summer, relying on data gathered via a network of 25 or so acoustic monitoring stations located along 500 square miles, including the beaches of Isla Vista and further inland to the hills of Ojai. "The measurements were made in parks, people's backyards, parking lots, wastewater plants, and all sorts of different locations," said Gee. More bang than boom A view of a Falcon 9 rocket launch from a park in Ventura County. Credit: Kent Gee There has been a great deal of research on supersonic aircraft, but the sonic booms produced by rockets like the Falcon 9 are acoustically distinct, according to Gee. For instance, most sonic booms have two shock waves, but the Falcon 9 booster produces a boom with three shocks as it descends through the atmosphere after launch. Gee co-authored a paper earlier this year analyzing the acoustic signatures of three Falcon 9 flyback sonic booms. While the first and third shocks were what one might typically expect, the second central shock "is formed by a combination of the grid fins and the lower portions of the booster, including the folded landing legs," Gee and BYU colleague Mark C. Anderson wrote. "These lower portions of the booster produce a rarefaction wave that tends to migrate toward the back of the shock system while the grid fins produce a shock wave that tends to migrate toward the front of the shock system." Those shock waves merge, and their relative strengths determine where this second shock appears in the full sonic boom acoustic signature. Sonic booms from rockets are also lower frequency, with peaks of less than 1 Hz—below the range of human hearing. The result is less of a "boom" and more of a "bang," according to Gee, that can last a few seconds, compared to milliseconds for a typical acoustic wave. It's more akin to a seismic wave, particularly if one is indoors when it hits. "Sometimes you get a very low amplitude rumble, but it comes on suddenly, and it's there for a few seconds and disappears," he said. It's also one reason why the sonic booms can travel so far afield of the Vandenberg base. Could the similarities confuse California residents who might mistake a sonic boom for an earthquake? Perhaps, at least until residents learn otherwise. "Since we're often setting up in people's backyard, they text us the results of what they heard," said Gee. "It's fantastic citizen science. They'll tell us the difference is that the walls shake but the floors don't. They're starting to be able to tell the difference between an earthquake or a sonic boom from a launch." Launch trajectories of Falcon 9 rockets along the California coast. Credit: Kent Gee A rocket's trajectory also plays an important role. "Everyone sees the same thing, but what you hear depends on where you're at and the rocket's path or trajectory," said Gee, adding that even the same flight path can nonetheless produce markedly different noise levels. "There's a focal region in Ventura, Oxnard, and Camarillo where the booms are more impactful," he said. "Where that focus occurs changes from launch to launch, even for the same trajectory." That points to meteorology also being a factor: Certain times of year could potentially have more impact than others as weather conditions shift, with wind shears, temperature gradients, and topography, for instance, potentially affecting the propagation of sonic booms. In short, "If you can change your trajectory even a little under the right meteorological conditions, you can have a big impact on the sonic booms in this region of the country," said Gee. And it's only the beginning of the project; the team is still gathering data. "No two launches look the same right now," said Gee. "It's like trying to catch lightning." As our understanding improves, he sees the conversation shifting to more subjective social questions, possibly leading to the development of science-based local regulations, such as noise ordinances, to address any negative launch impacts. The next step is to model sonic booms under different weather conditions, which will be challenging due to coastal California's microclimates. "If you've ever driven along the California coast, the weather changes dramatically," said Gee. "You go from complete fog at Vandenberg to complete sun in Ventura County just 60 miles from the base." Jennifer Ouellette Senior Writer Jennifer Ouellette Senior Writer Jennifer is a senior writer at Ars Technica with a particular focus on where science meets culture, covering everything from physics and related interdisciplinary topics to her favorite films and TV series. Jennifer lives in Baltimore with her spouse, physicist Sean M. Carroll, and their two cats, Ariel and Caliban. 1 Comments

drop it like it's hot The key to a successful egg drop experiment? Drop it on its side Eggs are less likely to crack when dropped horizontally vs. vertically, contradicting conventional wisdom. Jennifer Ouellette – May 26, 2025 11:05 am | 7 A physics teacher drops a package designed to protect three eggs from a fall of ten meters Credit: Ben Wildeboer/CC BY-SA 3.0 A physics teacher drops a package designed to protect three eggs from a fall of ten meters Credit: Ben Wildeboer/CC BY-SA 3.0 Story text Size Small Standard Large Width * Standard Wide Links Standard Orange * Subscribers only   Learn more Egg drop competitions are a staple of high school and college physics classes. The goal is for students to build a device using bubble wrap, straws, or various other materials designed to hold an egg and keep it intact after being dropped from a substantial height—say, ten meters (nearly 33 feet). There's even a "naked egg" version in which a raw egg is dropped into a container below.  The competition is intended to teach students about structural mechanics and impact physics, and it is not an easy feat; most of the dropped eggs break. MIT engineering professor Tal Cohen decided to investigate why the failure rate was so high and reported her team's findings in a paper published in the journal Communications Physics. "The universal convention is that the egg should be in a vertical orientation when it hits the ground," Cohen told Physics Magazine. But their results from controlled trials simulating the egg drop challenge in the lab calls this conventional wisdom into question. It is not an unreasonable assumption to make. Another popular physics party trick is to walk on several cartons of eggs without breaking them. Typically it only takes about five and a half pounds of force to crack a single eggshell, much less than the average adult human. As I wrote for Slate back in 2012, "The key is to align the eggs so that the narrow pole is pointing upward, and step in such a way to distribute your weight over the entire surface area, to avoid overloading any one eggshell." (Being barefoot also helps.) In fact, I noted at the time a surprisingly long history of scientific studies of eggshells and how cracks propagate, particularly in the 1950s and 1960s, when they served as useful models for failure analysis when building airplanes. The toughness comes from the egg shell's structure; it is made up mostly of calcium carbonate (calcite) crystals, similar to tooth enamel or sea shells,  embedded within a protein matrix. The egg shell is strengthened further by a thin inner collagen layer. This tends to keep damage localized as cracks spread little by little rather than one clean break. Chef instructor demonstrates the one-handed technique for cracking an egg in 1954's Sabrina. Paramount Pictures Chef instructor demonstrates the one-handed technique for cracking an egg in 1954's Sabrina. Paramount Pictures Sabrina needs a new egg. Paramount Pictures Sabrina needs a new egg. Paramount Pictures Chef instructor demonstrates the one-handed technique for cracking an egg in 1954's Sabrina. Paramount Pictures Sabrina needs a new egg. Paramount Pictures Cohen et al. give a shoutout in their introduction to Jonathan Swift's Gulliver's Travels, specifically the longstanding quarrel between the people of Lilliput and Blefuscu on the best orientation for cracking an egg. Of course, there is the classic chef's one-handed egg-cracking technique—immortalized in the 1954 romantic comedy, Sabrina—which involves holding the egg between the fingers and thumb and rapping the edge sharply against the rim of the bowl to achieve a clean break. Alas, this usually ends in a crushed eggy mess when attempted by amateurs. (Practicing with a golf ball can improve one's skill.) MIT scientists have previously studied precisely how much force to apply to the center of an egg. Specifically, the scientists devised a mathematical formula linking the ovoid geometry of the eggshell and its rigidity—a property that, along with strength (a related but distinct concept), accounts for how much force a given object can withstand before breaking. It's the narrow tip that is the most crack-resistant part of the egg, since the shell becomes more rigid the more the egg curves. That's why pressing down on both the bottom and top of an egg with your fingers won't work. But turn the egg horizontally and press right at the center, and the shell cracks easily. Stiffness vs. toughness So what's going on with these latest MIT findings? To find out, Cohen et al. bought 180 chicken eggs—Costco's Kirkland Signature brand— and conducted their own egg drop experiments in the lab. They dropped 60 eggs each from three different heights (8, 9, and 10 millimeters) onto a hard surface in three different orientations: horizontal, vertical on the sharp end, and vertical on the blunt end. They also subjected an additional 60 eggs to compression tests to determine the force required to break the eggs in both the vertical and horizontal orientations. Experimental snapshots for vertical (top) and horizontal (bottom) egg drops. Credit: A. Sutanto et al., 2025 The results: over half of the eggs broke when dropped vertically from an 8-millimeter (31-inch) height, regardless of which end of the egg was pointing downwards. Yet less than ten percent of the horiztonally-dropped eggs broke. The eggs broke when the force exceeded 45 Newtons, an impressive per-egg load bearing capacity that is independent of its orientation. There was a key difference, however, between how vertically and horizontally  squeezed eggs deformed in the compression experiments—namely, the former deformed less than the latter. The shell's greater rigidity along its long axis was an advantage because the heavy load was distributed over the surface. (It's why the one-handed egg-cracking technique targets the center of a horizontally held egg.) But the authors found that this advantage when under static compression proved to be a disadvantage when dropping eggs from a height, with the horizontal position emerging as the optimal orientation.  It comes down to the difference between stiffness—how much force is needed to deform the egg—and toughness, i.e., how much energy the egg can absorb before it cracks. Cohen et al.'s experiments showed that eggs are tougher when loaded horizontally along their equator, and stiffer when compressed vertically, suggesting that "an egg dropped on its equator can likely sustain greater drop heights without cracking," they wrote. "Even if eggs could sustain a higher force when loaded in the vertical direction, it does not necessarily imply that they are less likely to break when dropped in that orientation. In contrast to static loading, to remain intact following a dynamic impact, a body must be able to absorb all of its kinetic energy by transferring it into reversible deformation." "Eggs need to be tough, not stiff, in order to survive a fall," Cohen et al. concluded, pointing to our intuitive understanding that we should bend our knees rather than lock them into a straightened position when landing after a jump, for example. "Our results and analysis serve as a cautionary tale about how language can affect our understanding of a system, and improper framing of a problem can lead to misunderstanding and miseducation." DOI: Communications Physics, 2025. 10.1038/s42005-025-02087-0  (About DOIs). Jennifer Ouellette Senior Writer Jennifer Ouellette Senior Writer Jennifer is a senior writer at Ars Technica with a particular focus on where science meets culture, covering everything from physics and related interdisciplinary topics to her favorite films and TV series. Jennifer lives in Baltimore with her spouse, physicist Sean M. Carroll, and their two cats, Ariel and Caliban. 7 Comments

i ate a rock from the moon Have we finally solved mystery of magnetic moon rocks? Simulations show how effects of asteroid impact could amplify the early Moon's weak magnetic field. Jennifer Ouellette – May 23, 2025 2:36 pm | 5 NASA Lunar sample 60015 on display at Space Center Houston Lunar Samples Vault, at NASA's Johnson Space Center Credit: OptoMechEngineer/CC BY-SA 4.0 NASA Lunar sample 60015 on display at Space Center Houston Lunar Samples Vault, at NASA's Johnson Space Center Credit: OptoMechEngineer/CC BY-SA 4.0 Story text Size Small Standard Large Width * Standard Wide Links Standard Orange * Subscribers only   Learn more NASA's Apollo missions brought back moon rock samples for scientists to study. We've learned a great deal over the ensuing decades, but one enduring mystery remains. Many of those lunar samples show signs of exposure to strong magnetic fields comparable to Earth's, yet the Moon doesn't have such a field today. So, how did the moon rocks get their magnetism? There have been many attempts to explain this anomaly. The latest comes from MIT scientists, who argue in a new paper published in the journal Science Advances that a large asteroid impact briefly boosted the Moon's early weak magnetic field—and that this spike is what is recorded in some lunar samples. Evidence gleaned from orbiting spacecraft observations, as well as results announced earlier this year from China's Chang'e 5 and Chang'e 6 missions, is largely consistent with the existence of at least a weak magnetic field on the early Moon. But where did this field come from? These usually form in planetary bodies as a result of a dynamo, in which molten metals in the core start to convect thanks to slowly dissipating heat. The problem is that the early Moon's small core had a mantle that wasn't much cooler than its core, so there would not have been significant convection to produce a sufficiently strong dynamo. There have been proposed hypotheses as to how the Moon could have developed a core dynamo. For instance, a 2022 analysis suggested that in the first billion years, when the Moon was covered in molten rock, giant rocks formed as the magma cooled and solidified. Denser minerals sank to the core while lighter ones formed a crust. Over time, the authors argued, a titanium layer crystallized just beneath the surface, and because it was denser than lighter minerals just beneath, that layer eventually broke into small blobs and sank through the mantle (gravitational overturn). The temperature difference between the cooler sinking rocks and the hotter core generated convection, creating intermittently strong magnetic fields—thus explaining why some rocks have that magnetic signature and others don't. Or perhaps there is no need for the presence of a dynamo-driven magnetic field at all. For instance, the authors of a 2021 study thought earlier analyses of lunar samples may have been altered during the process. They re-examined samples from the 1972 Apollo 16 mission using CO2 lasers to heat them, thus avoiding any alteration of the magnetic carriers. They concluded that any magnetic signatures in those samples could be explained by the impact of meteorites or comets hitting the Moon. Bracing for impact In 2020, two of the current paper's authors, MIT's Benjamin Weiss and Rona Oran, ran simulations to test whether a giant impact could generate a plasma that, in turn, would amplify the Moon's existing weak solar-generated magnetic field sufficiently to account for the levels of magnetism measured in the moon rocks. Those results seemed to rule out the possibility. This time around, they have come up with a new hypothesis that essentially combines elements of the dynamo and the plasma-generating impact hypotheses—taking into account an impact's resulting shockwave for good measure. Amplification of the lunar dynamo field by an Imbrium-­sized impact at the magnetic equator. Credit: Isaac S. Narrett et al., 2025 They tested their hypothesis by running impact simulations, focusing on the level of impact that created the Moon's Imbrium basin, as well as plasma cloud simulations. Their starting assumption was that the early Moon had a dynamo that generated a weak magnetic field 50 times weaker than Earth's. The results confirmed that a large asteroid impact, for example, could have kicked up a plasma cloud, part of which spread outward into space. The remaining plasma streamed around to the other side of the Moon, amplifying the existing weak magnetic field for around 40 minutes. A key factor is the shock wave created by the initial impact, similar to seismic waves, which would have rattled surrounding rocks enough to reorient their subatomic spins in line with the newly amplified magnetic field. Weiss has likened the effect to tossing a deck of 52 playing cards into the air within a magnetic field. If each card had its own compass needle, its magnetism would be in a new orientation once each card hit the ground. It's a complicated scenario that admittedly calls for a degree of serendipity. But we might not have to wait too long for confirmation one way or the other. The answer could lie in analyzing fresh lunar samples and looking for telltale signatures not just of high magnetism but also shock. (Early lunar samples were often discarded if they showed signs of shock.) Scientists are looking to NASA's planned Artemis crewed missions for this, since sample returns are among the objectives. Much will depend on NASA's future funding, which is currently facing substantial cuts, although thus far, Artemis II and III remain on track. Science Advances, 2025. DOI: 10.1126/sciadv.adr7401  (About DOIs). Jennifer Ouellette Senior Writer Jennifer Ouellette Senior Writer Jennifer is a senior writer at Ars Technica with a particular focus on where science meets culture, covering everything from physics and related interdisciplinary topics to her favorite films and TV series. Jennifer lives in Baltimore with her spouse, physicist Sean M. Carroll, and their two cats, Ariel and Caliban. 5 Comments

shrinking Nemo Incredible shrinking clownfish beats the heat Shrinking down to size boosted clownfish survival rates up to 78 percent during heat waves. Jennifer Ouellette – May 21, 2025 2:00 pm | 7 Credit: Morgan Bennett-Smith Credit: Morgan Bennett-Smith Story text Size Small Standard Large Width * Standard Wide Links Standard Orange * Subscribers only   Learn more Pixar's Finding Nemo immortalized the colorful clownfish, with its distinctive orange body and white stripes, in the popular imagination. Clownfish, like many other species, are feeling the stress of rising temperatures and other environmental stressors. Fortunately, they have a superpower to cope: They can shrink their body size during dangerous heat waves to substantially boost their odds of survival, according to a new paper published in the journal Science Advances. “This is not just about getting skinnier under stressful conditions; these fish are actually getting shorter," said co-author Melissa Versteeg, a graduate student at Newcastle University. "We don’t know yet exactly how they do it, but we do know that a few other animals can do this too." Many vertebrates have shown growth decline in response to environmental stressors, especially higher temperatures. Marine iguanas, for example, reabsorb some of their bone material to shrink when their watery habitat gets warmer, while young salmon have been known to shrink at winter's onset. This can also happen when there is less food available. And social factors can also influence growth. When female meerkats, for example, are dominant, they have growth spurts, while a disruption in their social status can cause stunted growth in male cichlids What has been lacking in prior research is an investigation into how environmental and social factors interact to influence growth rates, according to Versteeg et al. They thought clownfish were the best species to study to fill that gap, since they've been extensively studied and are well understood. The fish live on Indo-Pacific coral reefs where heat stress has been increasing and has become more severe—an environment that is close to the thermal tolerance limits of clownfish. Clownfish also live in social groups: They form breeding pairs with a dominant female and subdominant male, sometimes adding subordinate non-breeding fish. The dominants tend to grow to match the size of the host anemone, while the subordinates only grow to a size that ensures there are sufficient resources—otherwise they risk being evicted and likely dying. Let’s get small The team observed 67 breeding pairs of wild clownfish—briefly caught and photographed for distinctive markings and measured before being returned to the water—living on single anemones in Kimbe Bay, Papua New Guinea, between February and August 2023. This happened to coincide with the world's fourth global bleaching event. They measured the body size of the fish once a month and measured the temperature around the individual anemones every four to six days. Then the team analyzed the collected data. "Individual fish can shrink in response to heat stress." Credit: Morgan Bennett-Smith The results: Over the course of those months, 101 of the 134 clownfish shrank at least once in response to heat stress, and doing so boosted their likelihood of survival up to 78 percent compared to the 33 fish that did not shrink. And between breeding pairs, there were distinctive growth ratios between the dominant and subordinate fish; those pairs that shrank together were also more likely to survive the heat waves. “We were so surprised to see shrinking in these fish that, to be sure, we measured each fish individual repeatedly over a period of five months," said Versteeg. "In the end, we discovered it was very common in this population. It was a surprise to see how rapidly clownfish can adapt to a changing environment, and we witnessed how flexibly they regulated their size, as individuals and as breeding pairs, in response to heat stress as a successful technique to help them survive.” Versteeg et al. have not yet identified a possible mechanism for the shrinkage, but suggest the triggering of neuroendocrine pathways via thyroid hormones might play a role, since those hormones regulate growth. The adaptive strategy could also be a means of adjusting to changing metabolic needs. But there are trade-offs: While shrinking in response to heat waves ensures greater survivability, there can also be a corresponding decrease in birth rates. "Our findings show that individual fish can shrink in response to heat stress, which is further impacted by social conflict, and that shrinking can lead to improving their chances of survival," said senior author Theresa Rueger, also of Newcastle University. "If individual shrinking were widespread and happening among different species of fish, it could provide a plausible alternative hypothesis for why the size of many fish species is declining, and further studies are needed in this area.” Science Advances, 2025. DOI: 10.1126/sciadv.adt7079  (About DOIs). Jennifer Ouellette Senior Writer Jennifer Ouellette Senior Writer Jennifer is a senior writer at Ars Technica with a particular focus on where science meets culture, covering everything from physics and related interdisciplinary topics to her favorite films and TV series. Jennifer lives in Baltimore with her spouse, physicist Sean M. Carroll, and their two cats, Ariel and Caliban. 7 Comments

resistance is futile A peer’s promise can help kids pass the marshmallow test Younger children were slightly more likely to successfully delay gratification than older children. Jennifer Ouellette – May 15, 2025 9:46 am | 0 For decades, Walter Mischel's "marshmallow test" was viewed as a key predictor for children's future success, but reality is a bit more nuanced. Credit: Igniter Media For decades, Walter Mischel's "marshmallow test" was viewed as a key predictor for children's future success, but reality is a bit more nuanced. Credit: Igniter Media Story text Size Small Standard Large Width * Standard Wide Links Standard Orange * Subscribers only   Learn more You've probably heard of the infamous "marshmallow test," in which young children are asked to wait to eat a yummy marshmallow placed in front of them while left alone in a room for 10 to 15 minutes. If they successfully do so, they get a second marshmallow; if not, they don't. The test has become a useful paradigm for scientists interested in studying the various factors that might influence one's ability to delay gratification, thereby promoting social cooperation. According to a paper published in the journal Royal Society Open Science, one factor is trust: If children are paired in a marshmallow test and one promises not to eat their treat for the specified time, the other is much more likely to also refrain from eating it. As previously reported, psychologist Walter Mischel's landmark behavioral study involved 600 kids between the ages of four and six, all culled from Stanford University's Bing Nursery School. He would give each child a marshmallow and give them the option of eating it immediately if they chose. But if they could wait 15 minutes, they would get a second marshmallow as a reward. Then Mischel would leave the room, and a hidden video camera would tape what happened next. Some kids just ate the marshmallow right away. Others found a handy distraction: covering their eyes, kicking the desk, or poking at the marshmallow with their fingers. Some smelled it, licked it, or took tiny nibbles around the edges. Roughly one-third of the kids held out long enough to earn a second marshmallow. Several years later, Mischel noticed a strong correlation between the success of some of those kids later in life (better grades, higher self-confidence) and their ability to delay gratification in nursery school. Mischel's follow-up study confirmed the correlation. Mischel himself cautioned against over-interpreting the results, emphasizing that children who simply can't hold out for that second marshmallow are not necessarily doomed to a life of failure. A more nuanced picture was offered in a 2018 study that replicated the marshmallow test with preschoolers. It found the same correlation between later achievement and the ability to resist temptation in preschool, but that correlation was much less significant after the researchers factored in such aspects as family background, home environment, and so forth. Attentiveness might be yet another contributing factor, according to a 2019 paper. There have also been several studies examining the effects of social interdependence and similar social contexts on children's ability to delay gratification, using variations of the marshmallow test paradigm. For instance, in 2020, a team of German researchers adapted the classic experimental setup using Oreos and vanilla cookies with German and Kenyan schoolchildren, respectively. If both children waited to eat their treat, they received a second cookie as a reward; if one did not wait, neither child received a second cookie. They found that the kids were more likely to delay gratification when they depended on each other, compared to the standard marshmallow test. An online paradigm Rebecca Koomen, a psychologist now at the University of Manchester, co-authored the 2020 study as well as this latest one, which sought to build on those findings. Koomen et al. structured their experiments similarly, this time recruiting 66 UK children, ages five to six, as subjects. They focused on how promising a partner not to eat a favorite treat could inspire sufficient trust to delay gratification, compared to the social risk of one or both partners breaking that promise. Any parent could tell you that children of this age are really big on the importance of promises, and science largely concurs; a promise has been shown to enhance interdependent cooperation in this age group. Koomen and her Manchester colleagues added an extra twist: They conducted their version of the marshmallow test online to test the effectiveness compared to lab-based versions of the experiment. (Prior results from similar online studies have been mixed.) "Given face-to-face testing restrictions during the COVID pandemic, this, to our knowledge, represents the first cooperative marshmallow study to be conducted online, thereby adding to the growing body of literature concerning the validity of remote testing methods," they wrote. The type of treat was chosen by each child's parents, ensuring it was a favorite: chocolate, candy, biscuits, and marshmallows, mostly, although three kids loved potato chips, fruit, and nuts, respectively. Parents were asked to set up the experiment in a quiet room with minimal potential distractions, outfitted with a webcam to monitor the experiment. Each child was shown a video of a "confederate child" who either clearly promised not to eat the treat or more ambiguously suggested they might succumb and eat their treat. (The confederate child refrained from eating the treat in both conditions, although the participant child did not know that.) Then the scientist running the experiment would leave the Zoom meeting for an undisclosed period of time, after telling the child that if both of them resisted eating the treat (including licking or nibbling at it), they would each receive a second one; if one of them failed, neither would be rewarded. Children could not see or communicate with their paired confederates for the duration of the experiment. The scientist returned after ten minutes to see if the child had managed to delay gratification. Once the experiment had ended, the team actually did reward the participant child regardless of the outcome, "to end the study on a positive note." The results were controlled for unavoidable accidental distractions, so the paper includes the results from both the full dataset of all 68 participants and a subset of 48 children, excluding those who experienced some type of disruption during the ten-minute experiment. In both cases, children whose confederate clearly promised not to eat their treat waited longer to eat their treat compared to the more ambiguous "social risk" condition. And younger children were slightly more likely to successfully delay gratification than older children, although this result was not statistically significant. The authors suggest this small difference may be due to the fact that older children are more likely to have experienced broken promises, thereby learning "that commitments are not always fulfilled." Of course, there are always caveats. For instance, while specific demographic data was not collected, all the children had predominantly white middle-class backgrounds, so the results reflect how typical children in northern England behave in such situations. The authors would like to see their online experiment repeated cross-culturally in the future. And the limitation of one-way communication "likely prevented partners from establishing common ground, namely their mutual commitment to fulfilling their respective roles, which is thought to be a key principle of interdependence," the authors wrote. DOI: Royal Society Open Science, 2025. 10.1098/rsos.250392  (About DOIs). Jennifer Ouellette Senior Writer Jennifer Ouellette Senior Writer Jennifer is a senior writer at Ars Technica with a particular focus on where science meets culture, covering everything from physics and related interdisciplinary topics to her favorite films and TV series. Jennifer lives in Baltimore with her spouse, physicist Sean M. Carroll, and their two cats, Ariel and Caliban. 0 Comments

en pointe Ana de Armas is caught in Wick’s crosshairs in final Ballerina trailer "When you think of me, you should think of fire. Risen from ashes, again and again." Jennifer Ouellette – May 13, 2025 10:08 am | 0 Credit: Lionsgate Entertainment Credit: Lionsgate Entertainment Story text Size Small Standard Large Width * Standard Wide Links Standard Orange * Subscribers only   Learn more One last trailer for From the World of John Wick: Ballerina. We're about three weeks out from the theatrical release of From the World of John Wick: Ballerina,  starring Ana de Armas. So naturally Lionsgate has released one final trailer to whet audience appetites for what promises to be a fiery, action-packed addition to the hugely successful franchise. (Some spoilers for 2019's John Wick Chapter 3: Parabellum.) Chronologically, Ballerina takes place during the events of John Wick Chapter 3: Parabellum. As previously reported, Parabellum found Wick declared excommunicado from the High Table for killing crime lord Santino D'Antonio on the grounds of the Continental. On the run with a bounty on his head, he makes his way to the headquarters of the Ruska Roma crime syndicate, led by the Director (Anjelica Huston). The Director also trains young girls to be ballerina-assassins, and one young ballerina (played by Unity Phelan) is shown rehearsing in the scene. That dancer, Eve Macarro, is the main character in Ballerina, now played by de Armas. Huston returns as the Director, Ian McShane is back as Winston, and Lance Reddick makes one final (posthumous) appearance as the Continental concierge, Charon. New cast members include Gabriel Byrne as the main villain, the Chancellor, who turns an entire town against Eve; Sharon Duncan-Brewster as Nogi, Eve's mentor; Norman Reedus as Daniel Pine; and Catalina Sandino Moreno and David Castaneda in as-yet-undisclosed roles. The first trailer was released last September and focused heavily on Eve's backstory: Having been orphaned, she chose to train with the Ruska Roma in hopes of avenging her father's brutal death. Wick only made a brief appearance, but he had more screen time in the second trailer, released in March, in which the pair face off in an atmospheric wintry landscape. This final trailer opens with Eve looking up while directly in Wick's crosshairs. Much of the ensuing footage isn't new, but it does show de Armas to her best deadly advantage as she takes on combatant after combatant in true John Wick style. Her vow: "This isn't done until they're dead." From the World of John Wick: Ballerina hits theaters on June 6, 2025. Jennifer Ouellette Senior Writer Jennifer Ouellette Senior Writer Jennifer is a senior writer at Ars Technica with a particular focus on where science meets culture, covering everything from physics and related interdisciplinary topics to her favorite films and TV series. Jennifer lives in Baltimore with her spouse, physicist Sean M. Carroll, and their two cats, Ariel and Caliban. 0 Comments