Nasa spacecraft around the Moon photographs crash site of Japanese lunar lander

A Nasa spacecraft around the moon has photographed the crash site of a Japanese company's lunar lander.
Nasa released the pictures on Friday, two weeks after ispace's lander slammed into the moon.
The images show a dark smudge where the lander, named Resilience, and its mini rover crashed into Mare Frigoris or Sea of Cold, a volcanic region in the moon's far north.
As of 8:00 a.m. on June 6, 2025, mission controllers have determined that it is unlikely that communication with the lander will be restored and therefore completing Success 9, is not achievable. It has been decided to conclude the mission.
'Given that there is currently no… pic.twitter.com/q6e87usCLt
— ispace (@ispace_inc) June 6, 2025
A faint halo around the area was formed by the lunar dirt kicked up by the impact.
Nasa's Lunar Reconnaissance Orbiter captured the scene last week.
The crash was the second failure in two years for Tokyo-based ispace. Company officials plan to hold a news conference next week to explain what doomed the latest mission, launched from Cape Canaveral in January.

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The signals came from below the horizon, suggesting they had passed through thousands of miles of rock before reaching the detector. But the radio waves should have been absorbed by the rock. The ANITA team believed these anomalous signals could not be explained by the current understanding of particle physics. Follow-up observations and analyses with other instruments, including one recently conducted by the Pierre Auger Observatory in Argentina, have not been able to find the same signals. The results of the Pierre Auger Collaboration were published in the journal Physical Review Letters in March. The origin of the anomalous signals remains unclear, said study coauthor Stephanie Wissel, associate professor of physics, astronomy and astrophysics at the Pennsylvania State University. 'Our new study indicates that such (signals) have not been seen by an experiment … like the Pierre Auger Observatory,' Wissel said. 'So, it does not indicate that there is new physics, but rather more information to add to the story.' Larger, more sensitive detectors may be able to solve the mystery, or ultimately prove whether the anomalous signals were a fluke, while continuing the search for enigmatic neutrinos and their sources, scientists say. Detecting neutrinos on Earth allows researchers to trace them back to their sources, which scientists believe are primarily cosmic rays that strike our planet's atmosphere. The most highly energetic particles in the universe, cosmic rays are made up mostly of protons or atomic nuclei, and they are unleashed across the universe because whatever produces them is such a powerful particle accelerator that it dwarfs the capabilities of the Large Hadron Collider. Neutrinos could help astronomers better understand cosmic rays and what launches them across the cosmos. 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'By using computer simulations of what such a shower of particles would look like if it had behaved like the ANITA anomalous events, they are able to generate a kind of template for similar events and then search their data to see if anything like that appears.' Gorham, who was not involved with the new research, designed the ANITA experiment and has conducted other research to understand more about the anomalous signals. While the Auger Observatory was designed to measure downward-going particle showers produced in the atmosphere by ultrahigh-energy cosmic rays, the team redesigned their data analysis to search for upward-going air showers, Vandenbroucke said. Vandenbroucke did not work on the new study, but he peer-reviewed it prior to publication. 'Auger has an enormous collecting area for such events, larger than ANITA,' he said. 'If the ANITA anomalous events are produced by any particle traveling through the Earth and then producing upward-going showers, then Auger should have detected many of them, and it did not.' A separate follow-up study using the IceCube Experiment, which has sensors embedded deep in the Antarctic ice, also searched for the anomalous signals. 'Because IceCube is very sensitive, if the ANITA anomalous events were neutrinos then we would have detected them,' wrote Vandenbroucke, who served as colead of the IceCube Neutrino Sources working group between 2019 and 2022. 'It's an interesting problem because we still don't actually have an explanation for what those anomalies are, but what we do know is that they're most likely not representing neutrinos,' Wissel said. Oddly enough, a different kind of neutrino, called a tau neutrino, is one hypothesis that some scientists have put forth as the cause of the anomalous signals. Tau neutrinos can regenerate. 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