An orbital oopsie has led to new proof of Albert Einstein’s physics prowess.
In 2014, two satellites intended for Europe’s Galileo network, the equivalent of the United States’ GPS network, were placed into orbit incorrectly, causing them to travel around Earth in ellipses rather than circles. That wasn’t ideal for the satellites’ originally intended navigational use, but scientists realized the wayward satellites were perfect for another purpose: testing Einstein’s theory of gravity, the general theory of relativity.
According to general relativity, gravity affects not just space, but also time. The deeper within a gravitational field you are, the slower time passes (SN: 10/17/15, p. 16). So a clock at a higher altitude will tick faster than one closer to Earth’s surface, where Earth’s gravity is stronger. The satellites’ orbital mishap allowed the most precise test yet of this effect, known as gravitational redshift, two teams of scientists report in a pair of papers in the Dec. 7 Physical Review Letters.
As the two misplaced satellites move in their elliptical orbits, their distance from Earth periodically increases and decreases by about 8,500 kilometers. Using the precise atomic clocks on the satellites, the scientists studied how that altitude change affected the flow of time. The clocks sped up and slowed down by tiny fractions of a second as expected, agreeing with the predictions of general relativity within a few thousandths of a percent, the teams report.
SEATTLE — Astronomers have spotted a second repeating fast radio burst, and it looks a lot like the first. The existence of a second repeating burst suggests there could be many more of the mysterious signals in the cosmos.
The burst, called FRB 180814.J0422+73, is one of 13 newly discovered fast radio bursts, or FRBs — brief, bright signals of radio energy that come from distant galaxies. The FRBs were detected over a few weeks last year by the Canadian Hydrogen Intensity Mapping Experiment, or CHIME, in British Columbia. Astronomers reported the discoveries at a meeting of the American Astronomical Society on January 7 and in the Jan. 9 Nature. Most such bursts erupt once, last for a few milliseconds, and are never seen again. So astronomers have puzzled over what causes them for years (SN: 8/9/14, p. 22).
“If you have something that flashes for a millisecond in the sky, and there’s nothing that happens for many years, it’s really hard to study,” says astronomer Shriharsh Tendulkar of McGill University in Montreal, a member of the CHIME team.
But then in 2016, astronomers discovered the first repeating FRB when they realized that a series of bursts all came from a single source, called FRB 121102 (SN: 4/2/16, p. 12). Astronomers tracked the signal to its host galaxy (SN: 2/4/17, p. 10) and determined it was coming from an extremely magnetic environment, such as the region surrounding a black hole (SN: 2/3/18, p. 6). Researchers didn’t know if FRB 121102’s repeating signal was unique. Of the more than 60 FRBs detected, no other was known to repeat — until now. Having spotted a second one, scientists are searching for more.
“Imagine you saw a unicorn,” Tendulkar says. “Then suddenly you discover another one. You know now there is a population of these. There is hope for discovering a lot more.” The CHIME team detected the first of the repeating FRB signals on August 14, with four more coming over the next two months from the same spot on the sky. It wasn’t until the third burst, on September 17, that the team realized they might have a repeater, Tendulkar says.
“Somebody pointed out, hey look, these three bursts seem to have the same properties,” he says. “Everybody got really excited.”
Calculations show that the new repeater is about 1.6 billion light-years away. The CHIME team also saw an odd similarity between the two known repeating bursts. Most FRBs are just a sharp blip, akin to a single note being played on a trumpet. But some of the individual bursts in both repeaters were made up of multiple sub-bursts that descended in frequency, like the “wah wah wah wah” of a sad trombone.
“We’ve seen this in 121102, and we can’t explain it,” says astronomer Emily Petroff of ASTRON, the Netherlands Institute of Radio Astronomy, who was not involved in the new work. “Up until now we’ve only had the one repeater, and it’s given us more questions than answers.” But the fact that both repeaters behave similarly could suggest they have similar origins, she says.
Astronomers may have already caught a third repeating burst, too. FRB 110523, discovered in 2015, has some similar features to the first known repeating FRB, so it was worth checking to see if it also repeats, said astronomer Allison McCarthy of the University of Alabama in Tuscaloosa.
Together with Andrew Seymour of the Green Bank Observatory in West Virginia, McCarthy analyzed more than 41 hours of observations of FRB 110523 taken at the Arecibo Observatory in Puerto Rico. They found one potential repeat burst, McCarthy reported January 9 in a poster at the AAS meeting, but they’re not declaring victory just yet. “It wasn’t strong enough for us to be very sure we had detected one,” McCarthy said, adding that they’re about 60 percent certain. “But it’s still a promising candidate.”
Astronomers’ theories for what causes FRBs are almost as numerous as known FRBs themselves. At one point, astronomers even considered the idea that FRBs could be signals from intelligent aliens. But it’s unclear if the repeating bursts and single bursts both come from the same kinds of sources, or even if one-offs might also repeat if watched for long enough.
“It’s the wild, wild west out there,” Tendulkar says. “We have tantalizing clues, but it’s hard to make definitive conclusions.”
CHIME is likely to catch a lot more of these fast radio bursts. The telescope was still being tested when it caught the 13 new ones, so was not operating at peak performance. “They just barely turned on the telescope,” Petroff says, “and they’re already finding things.”
SAN FRANCISCO — Seizures during sleep can scramble memories — a preliminary finding that may help explain why people with epilepsy sometimes have trouble remembering.
The sleeping brain normally rehashes newly learned material, a nocturnal rehearsal that strengthens those memories. Neuroscientist Jessica Creery and her colleagues forced this rehearsal by playing certain sounds while nine people with epilepsy learned where on a screen certain pictures of common objects were located. Then, while the subjects later slept, the researchers played the sounds to call up some of the associated memories.
This sneaky method of strengthening memories, called targeted memory reactivation, worked as expected for five people who didn’t have seizures during the process. When these people woke up, they remembered the picture locations reactivated by a tone better than those that weren’t reactivated during sleep, said Creery, of Northwestern University in Evanston, Ill. She presented the research March 25 at the annual meeting of the Cognitive Neuroscience Society.
The opposite was true, however, for four people who had mild seizures, detected only by electrodes implanted deep in the brain, while they slept. For these people, memory reactivation during sleep actually worsened memories, making the reactivated memories weaker than the memories that weren’t reactivated during sleep. The combination of seizures and memory reactivation “seems like it’s actually scrambling the memory,” Creery says, a finding that suggests that seizures somehow accelerate forgetting.
Just beyond the tip of the Antarctic Peninsula lies an iceberg graveyard.
There, in the Scotia Sea, many of the icebergs escaping from Antarctica begin to melt, depositing sediment from the continent that had been trapped in the ice onto the seafloor. Now, a team of researchers has embarked on a two-month expedition to excavate the deposited debris, hoping to discover secrets from the southernmost continent’s climatic past.
That hitchhiking sediment, the researchers say, can help piece together how Antarctica’s vast ice sheet has waxed and waned over millennia. And knowing how much the ice melted in some of those warmest periods, such as the Pliocene Epoch about 3 million years ago, may provide clues to the ice sheet’s future. That includes how quickly the ice may melt in today’s warming world and by how much, says paleoclimatologist Michael Weber of the University of Bonn in Germany. Weber and Maureen Raymo, a paleoclimatologist at Lamont-Doherty Earth Observatory in Palisades, N.Y., are leading the expedition, which set sail on March 25.
“By looking at material carried by icebergs that calved off of the continent, we should be able to infer which sectors of the ice sheet were most unstable in the past,” Raymo says. “We can correlate the age and mineralogy of the ice-rafted debris to the bedrock in the section of Antarctica from which the bergs originated.” Icebergs breaking off from the edges of Antarctica’s ice sheet tend to stay close to the continent, floating counterclockwise around the continent. But when the bergs reach the Weddell Sea, on the eastern side of the peninsula, they are shunted northward through a region known as Iceberg Alley toward warmer waters in the Scotia Sea.
Because so many icebergs from all around the continent converge in one region, it is the ideal place to collect sediment cores and take stock of the debris that the bergs have dropped over millions of years.
“That area in the Scotia Sea is so exciting, because it’s a focus point between South America and the Antarctic Peninsula where the currents flow through, and there are a lot of icebergs,” says Gerhard Kuhn, a marine geologist at the Alfred Wegener Institute in Bremerhaven, Germany. “You get a picture of more or less [all of] Antarctica in that area,” says Kuhn, who has studied the region but is not aboard the current cruise. The expedition, known as leg 382 of the International Ocean Discovery Program, plans to drill at six different sites in the Scotia Sea. At three sites, the team plans to penetrate about 600 meters into the seafloor. “That would likely bring us back to the mid-Miocene, which could translate into 12 million to 18 million years back in time,” Weber says.
At another site, the team plans to drill even deeper, 900 meters, to go further back in time, in hopes of finding sediments that date to the opening of the Drake Passage about 41 million years ago. That passage, a body of water that now lies between South America and Antarctica, opened a link between the Atlantic and Pacific oceans and may have played a role in building up Antarctica’s ice sheets at different times in its history.
A graveyard turned crystal ball How much a melting Antarctica might have contributed to global sea-level rise following the last great ice age, which ended about 19,000 years ago, has been a subject of debate. Seas rose by about 130 meters from 19,000 to 8,000 years ago, Weber says, and much of the melting happened in the northern hemisphere.
But Antarctica may have played a larger role than once thought. In a study published in Nature in 2014, Kuhn, Weber and other colleagues reported that ice-rafted debris from that time period, as recorded in relatively short sediment cores from Iceberg Alley, often occurred in large pulses lasting a few centuries to millennia. Those data suggested that the southernmost continent was shedding lots of bergs much more quickly during those times than once thought.
Now, the researchers want to see even further into the past, to understand how quickly Antarctica’s ice sheet might have melted during even warmer periods, and how much it may have contributed to episodes of past sea-level rise.
The new drilling expedition targets several periods when the climate is thought to have warmed dramatically. One is a warm period in the middle Pliocene about 3.3 million to 3 million years ago, when average global temperatures were 2 to 3 degrees warmer than today; another is the ending of an older ice age about 130,000 years ago, when sea levels rose by about 5 to 9 meters.
Such periods may serve as analogs to the continent’s future behavior due to anthropogenic global warming. Currently, global average temperatures on Earth are projected to increase by between about 1.5 degrees and 4 degrees Celsius relative to preindustrial times, depending on greenhouse gas emissions to the atmosphere over the next few decades (SN: 10/22/18, p. 18).
“The existing [ice core] record from Iceberg Alley taught us Antarctica lost ice through a threshold reaction,” Weber says. That means that when the continent reached a certain transition point, there was sudden and massive ice loss rather than just a slow, gradual melt.
“We have rather firm evidence that this threshold is passed once the ice sheet loses contact with the underlying ocean floor,” he says, adding that at that point, the shedding of ice becomes self-sustaining, and can go on for centuries. “With mounting evidence of recent ice-mass loss in many sectors of West Antarctica of a similar fashion, we need to be concerned that a new ice-mass loss event is already underway, and there is no stopping it.”
