Astronauts perplexed as long-dead Nasa space probe suddenly emits powerful energy blast
A long-dead experimental Nasa satellite suddenly emitted a powerful energy blast recently, leaving scientists perplexed.
Astronomers at Australia's Curtin University discovered the strange pulse from the satellite, dead in space since the late 1960s, after recording a signal that briefly outshone everything else in the night sky.
At first, they thought it was coming from a pulsar or another undiscovered cosmic object. But an analysis revealed the origin of the signal was too close to the Earth.
'The 4,500km distance to the burst suggests an Earth satellite as the origin,' they concluded in a yet-to-be peer-reviewed study.
The 'incredibly powerful' energy blast could have been generated by the satellite colliding with a small meteoroid or a piece of space junk.
The astronomers eventually traced the source of the pulse to Nasa 's Relay 2, an experimental satellite that was launched in 1964 and went dead three years later.
They said electricity likely building up inside the craft for decades sparked an 'electrostatic discharge' when it collided with another object.
'We consider an electrostatic discharge or plasma discharge following a micrometeoroid impact to be plausible explanations for the burst,' they wrote in the study.
Such charging of spacecraft from interactions with their space environment is well documented. It happens due to the accumulation of electrons and charged particles within spacecraft, leading to large voltage differentials between their surfaces and between the craft and space. 'Spacecraft primarily charge through the accumulation of electrons through interactions with plasma in the space environment,' they explained. 'When sufficient voltage is achieved, electrostatic discharge occurs, typically between nearby surfaces/materials on the spacecraft.'
Energy released from such charged space probes was thought to last at least several microseconds. In the latest discovery, however, the high-energy discharge was sharp, lasting only a billionth of a second.
'We suggest that the burst originated from an electrostatic discharge event, or potentially a micrometeoroid impact, and consider that such events may be relatively common,' the astronomers concluded.
They hoped future space probes and sky monitoring equipment could be 'appropriately retrofitted' to better detect such energy discharge events.
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
The Independent
2 hours ago
- The Independent
Fossilised log reveals secrets of 120 million-year-old polar forests
Imagine a lush forest with tree ferns, their trunks capped by ribbon-like fronds. Conifers tower overhead, bearing triangular leaves almost sharp enough to pierce skin. Flowering plants are both small and rare. You're standing in what is now Victoria, Australia, about 127 million years ago during the Early Cretaceous Period. Slightly to your south, a massive river – more than a kilometre wide – separates you from Tasmania. This river flows along the valley forming between Australia and Antarctica as the two continents begin to split apart. During the Early Cretaceous, southeastern Australia was some of the closest land to the South Pole. Here, the night lasted for three months in winter, contrasting with three months of daytime in summer. Despite this extreme day-night cycle, various kinds of dinosaurs still thrived here, as did flies, wasps and dragonflies. And, as our recently published research in Palaeogeography, Palaeoclimatology, Palaeoecology reveals, termites also chewed through the decaying wood of fallen trees. This is the first record of termites living in a polar region – and their presence provides key insights into what these ancient forests were like. Home makers, not homewreckers Termites might have a public reputation as homewreckers. But these wood-eating bugs are a key part of many environments, freeing up nutrients contained in dead plants. They are one of the best organisms at breaking down large amounts of wood, and significantly speed up the decay of fallen wood in forests. The breakdown of wood by termites makes it easier for further consumption by other animals and fungi. Their role in ancient Victoria's polar forests would have been just as important, as the natural decay of wood is very slow in cold conditions. Although the cold winters would have slowed termites too, they may have thrived during long periods of darkness, just as modern termites are more active during the night. The oldest termite nest in Australia Our new paper, led by Monash University palaeontology research associate Jonathan Edwards, reports the discovery of an ancient termite nest near the coastal town of Inverloch in southeastern Victoria. Preserved in a 80-centimetre-long piece of fossilised log, the nest tunnels carved out by termites were first spotted by local fossil-hunter extraordinaire Melissa Lowery. Without its discoverers knowing what it was then, the log was brought into the lab and we began investigating the origins of its structures. Understanding the nest was challenging at first: the tunnels exposed on the surface were filled with what looked like tiny grains of rice, each around 2 millimetres long. We suspected they were most likely the coprolites (fossilised poo) of the nest-makers. Once we took a look under the microscope we noticed something very interesting: this poo was hexagonal. How did this shape point to termites as the 'poopetrators'? Modern termites have a gut with three sets of muscle bands. Just before excretion, their waste is squeezed to save as much water as possible, giving an almost perfect hexagonal shape to the pellets. The size, shape, distribution and quantity of coprolites meant we had just discovered the oldest termite nest in Australia – and perhaps the largest termite wood nest from dinosaur times. A global distribution We continued to investigate the nest with more specific methods. For example, we scanned parts of it with the Australian Synchrotron – a research facility that uses X-rays and infrared radiation to see the structure and composition of materials. This showed us what the unweathered coprolites inside the log looked like. We also made very thin slices of the nest and looked at these slices with high-powered microscopes. And we analysed the chemistry of the log, which further supported our original theory of the nest's identity. The oldest fossilised termites have been found in the northern hemisphere about 150 million years ago, during the Late Jurassic Period. What is exciting is that our trace fossils show they had reached the southernmost landmasses by 127 million years ago. This presence means they had likely spread all over Earth by this point. The termites weren't alone Surprisingly, these termites also had smaller wood-eating companions. During our investigation, we also noticed coprolites more than ten times smaller than those made by termites. These pellets likely belonged to wood-eating oribatid mites – minuscule arachnids with fossils dating back almost 400 million years. Many of their tunnels ring those left by the termites, telling us they inhabited this nest after the termites abandoned it. Termite tunnels may have acted as mite highways, taking them deeper into the log. Moreover, because both groups ate the toughest parts of wood, these two invertebrates might have directly competed at the time. Modern oribatid mites only eat wood affected by fungi. Regardless, our study documents the first known interaction of wood-nesting termites and oribatid mites in the fossil record. This nest also provides important support for the idea that Australia's polar forests weren't dominated by ice, as modern termites can't tolerate prolonged freezing. This is the first record of termites living in a polar region, and their presence suggests relatively mild polar winters — something like 6°C on average. Termites would've been key players in these ecosystems, kickstarting wood breakdown and nutrient cycling in an otherwise slow environment. So maybe next time you spot a termite nest, you'll see a builder, not a bulldozer. Alistair Evans is a Professor in the School of Biological Sciences at Monash University. Anthony J. Martin is a Professor of Practice in the Department of Environmental Sciences at Emory University.
The Independent
3 hours ago
- The Independent
How climate change is threatening airline passenger safety
Unexpected severe turbulence injured crew and passengers on a Qantas Boeing 737 during descent at Brisbane on May 4, 2024. The subsequent Australian Transport Safety Bureau investigation suggested the severity of the turbulence caught the captain by surprise. This is not an isolated event. Thunderstorms featuring severe wind gusts, such as violent updrafts and downbursts, are hazardous to aircraft. Downbursts, in particular, have been known to cause many serious accidents. Our new research suggests global warming is increasing the frequency and intensity of wind gusts from thunderstorm 'downbursts', with serious consequences for air travel. We used machine learning techniques to identify the climate drivers causing more thunderstorm downbursts. Increased heat and moisture over eastern Australia turned out to be the key ingredients. The findings suggest air safety authorities and airlines in eastern Australia must be more vigilant during takeoff and landing in a warming world. Warm, moist air spells trouble for planes Global warming increases the amount of water vapour in the lower atmosphere. That's because 1°C of warming allows the atmosphere to hold 7 per cent more water vapour. The extra moisture typically comes from adjacent warmer seas. It evaporates from the surface of the ocean and feeds clouds. Increased heat and water vapour fuel stronger thunderstorms. So, climate change is expected to increase thunderstorm activity over eastern Australia. For aircraft, the main problem with thunderstorms is the risk of hazardous, rapid changes in wind strength and direction at low levels. Small yet powerful Small downbursts, several kilometres wide, are especially dangerous. These 'microbursts' can cause abrupt changes in wind gust speed and direction, creating turbulence that suddenly moves the plane in all directions, both horizontally and vertically. Microburst wind gusts can be extremely strong. Brisbane Airport recorded a microburst wind gust at 157km per hour in November 2016. Three planes on the tarmac were extensively damaged. On descent or ascent, aircraft encountering microbursts can experience sudden, unexpected losses or gains in altitude. This has caused numerous aircraft accidents in the past. Microbursts will become increasingly problematic in a warming climate. Microburst analysis and prediction Microbursts are very difficult to predict because they are so small. So we used machine learning to identify the environmental factors most conducive to the formation of microbursts and associated severe wind gusts. We accessed observational data from the Bureau of Meteorology 's extensive archives. Then we applied eight different machine learning techniques to find the one that worked best. Machine learning is a field of study in artificial intelligence that uses algorithms and statistical models to enable computers to learn from data without explicit programming. It enables systems to identify patterns, make predictions and improve performance over time as they take in more information. We found that atmospheric conditions in eastern Australia are increasingly favouring the development of stronger, more frequent thunderstorm microbursts. We investigated a microburst outbreak from a storm front in 2018. It produced severe surface wind gusts at six regional airports in New South Wales: Bourke, Walgett, Coonamble, Moree, Narrabri and Gunnedah. Regional airports in Australia and around the world often use small aircraft. Small planes with 4–50 passenger seats are more vulnerable to the strong, even extreme, wind gusts spawned by thunderstorm microbursts. Widespread consequences Our extensive regional case study identified the weather patterns that create severe thunderstorms in eastern Australia during the warmer months. High cloud water content creates a downward force in the cloud. This force induces a descending air current. When the heavier air reaches the ground, wind gusts spray out in multiple directions. These wind gusts endanger aircraft during takeoff and landing, because rapid wind shifts from tail winds to head winds can cause the aircraft to dangerously gain or lose altitude. Our analysis highlights the elevated aviation risks of increased atmospheric turbulence from thunderstorm microbursts across eastern Australia. Smaller aircraft at inland regional airports in southeastern Australia are especially vulnerable. But these sudden microburst-generated wind gusts will require monitoring by major east coast airports, such as Sydney and Brisbane. Beware of heightened microburst activity Flying has long been recognised as a very safe mode of travel, with an accident rate of just 1.13 per million flights. However, passenger numbers worldwide have increased dramatically, implying even a small risk increase could affect a large number of travellers. Previous research into climate-related risks to air travel has tended to focus on high-altitude cruising dangers, such as clear air turbulence and jet stream instability. In contrast, there has been less emphasis on dangers during low-level ascent and descent. Our research is among the first to detail the heightened climate risk to airlines from thunderstorm microbursts, especially during takeoff and landing. Airlines and air safety authorities should anticipate stronger microbursts. More frequent wind gust turbulence from microbursts is to be expected over eastern Australia, in our ongoing warming climate. Milton Speer is a Visiting Fellow in the School of Mathematical and Physical Sciences at the University of Technology Sydney.
The Guardian
4 hours ago
- The Guardian
Plutonium levels at nuclear test site in WA up to 4,500 times higher than rest of coast, study finds
Samples of marine sediment taken from the location of three 1950s British government nuclear bomb tests off the coast of Western Australia have revealed plutonium levels up to 4,500 times higher than the rest of the coastline. Sixty six samples were taken from the shallow waters at the Montebello Islands, and scientists are now working to understand how marine life may be being affected by the sediment. The British government performed three nuclear tests on the uninhabited, remote islands – about 80 kilometres off the WA coastline – between October 1952 and June 1956. The first bomb, known as Operation Hurricane, was detonated in a ship moored 600 metres off Trimouille Island. Two further bombs were detonated from towers on Trimouille and neighbouring Alpha Island. The area is now a marine park known for its turquoise waters, corals, dolphins and threatened turtles. Madison Williams-Hoffman, a PhD student at Edith Cowan University and lead author of the research, said the plutonium would have been part of the 'fallout' from the nuclear tests that would have fallen from the blast cloud and into the surrounding waters and land. Radiation from plutonium cannot travel through skin and is most dangerous when ingested or inhaled. The 66 samples were collected in 2020 by divers who took the top 10cm of sediment, with analysis done at the university in Perth and also by the Australian Nuclear Science and Technology Organisation. Sign up for Guardian Australia's breaking news email Williams-Hoffman said little was known about the amounts of plutonium that remained in the marine environment and it was too early to speculate on any ongoing risks. Further research would look at those risks, she said. She said: 'This is a baseline that tells us what the levels are. Next we look at the risks to what's living there.' Williams-Hoffman said because plutonium was entirely human-made it could only be released by nuclear bombs, nuclear facilities or nuclear accidents. The contamination will persist for many thousands of years, she said. While the islands are not inhabited, they are visited by recreational fishing boats. The research, published in the journal Marine Pollution Bulletin, showed concentrations of plutonium at the islands were four to 4,500 times higher than those found in sediment samples taken at two distant coastal sites more than 1,000 kilometres away on the Western Australian coastline. Williams-Hoffman said it was curious that levels of contamination at the Montebello Islands were similar to those at the Marshall Islands in the Micronesia region of the Pacific in the northern hemisphere, even though nuclear testing there by the US government was 'orders of magnitude' greater. 'This is a really important question for us as a country,' she said. 'We have unique ecosystems and environments and we need to understand how these materials behave in the environment once they are released.' A previous study of animals in the Montebello area found low levels of plutonium in all tested species, but levels in fish muscles were so low that anyone eating them 'would receive an increase in dose from the [plutonium] many orders of magnitude lower than that from the natural radionuclides in the same fish', the research said. Visitors to the marine park are warned to limit any visits on Trimouille and Alpha Island to an hour a day, and not to disturb soils. Tim Hunt, the marine program coordinator for the Pilbara region of the WA government's parks and wildlife service, said while it was useful to know that plutonium persisted in the marine environment, advice from nuclear experts was that the risk to humans was much lower in a marine environment than on land. 'Because this radiation will persist for generations, we are looking to build on information and adjust our management if needed. But the information we have is that our measures are sufficient to mitigate the radiation risk that's there, and will continue to be there.'
