A compact neutrino detector has successfully identified antineutrinos at a nuclear power plant, marking a significant advancement in particle physics. Unlike conventional detectors that require massive infrastructure, this device weighs less than three kilograms. Despite its size, it effectively detected antineutrinos emitted from a nuclear reactor in Leibstadt, Switzerland. The experiment, which lasted 119 days, involved a detector composed of germanium crystals. Around 400 antineutrinos were recorded, aligning with theoretical predictions. Scientists believe this achievement could lead to improved testing of physics theories and potential applications in nuclear monitoring.

Study Findings and Expert Insights

According to a study submitted to arXiv on January 9, the experiment relied on a specific interaction where neutrinos and antineutrinos scatter off atomic nuclear. This phenomenon, which was first observed in 2017, enables smaller detectors to function effectively. Kate Scholberg, a neutrino physicist at Duke University, told Science News that the accomplishment is significant, as researchers have attempted similar feats for decades. She highlighted the simplicity of the interaction, comparing it to a gentle push rather than a complex nuclear reaction.

Christian Buck, a physicist at the Max Planck Institute for Nuclear Physics and co-author of the study, told Science News that this development opens a new avenue in neutrino physics. He noted that the interaction’s clean nature could help identify undiscovered particles or unexpected magnetic properties in neutrinos.

Potential Applications and Challenges

Physicists suggest that such detectors could play a role in monitoring nuclear reactors. The ability to detect antineutrinos could provide insights into reactor activity, including plutonium production, which has implications for nuclear security. However, challenges remain. Jonathan Link, a neutrino physicist at Virginia Tech, told Science News that while the technique is promising, it is still a difficult approach. The detector, despite its small size, requires shielding to eliminate background noise, limiting its portability.

This experiment also helps clarify past findings. In 2022, a similar claim of reactor antineutrinos scattering off nuclei was made, but inconsistencies with established theories led to controversy. Buck stated that the new study rules out the validity of those earlier results. With ongoing research, the field continues to evolve, potentially leading to further discoveries in particle physics.

The Indian Space Research Organisation (ISRO) has reported an issue with its NVS-02 navigation satellite, launched on January 29 aboard the GSLV-F15 rocket. While the satellite successfully reached orbit and established communication with ground control, a technical malfunction prevented further orbit-raising manoeuvres. The problem was traced to the non-opening of the oxidiser valves, which are crucial for firing the thrusters needed to adjust the satellite’s position. Despite this setback, ISRO has confirmed that the satellite’s systems remain functional, and alternative strategies for its operation are being explored.

Navigation Satellite in Stable Orbit

As reported, according to ISRO’s statement, the NVS-02 satellite remains in an elliptical orbit, and its solar panels are generating power as expected. Communication with the Master Control Facility has been established, ensuring continued monitoring and control. While the intended orbit-raising operations have been stalled, ISRO officials have indicated that the satellite may still be utilised for navigation in its current orbit. Discussions are underway to assess possible adjustments to its mission parameters.

Satellite Positioning Challenges Identified

As per space-tracking data from open-source platforms, the NVS-02 satellite has remained in approximately the same position since its launch, instead of being moved to its designated geostationary slot at 111.75 degrees east. Initial launch data indicated that the satellite had been placed in an elliptical orbit with an apogee of 37,500 km and a perigee of 170 km. While these figures closely matched the planned trajectory, the failure of the onboard thrusters to activate has prevented the intended orbital adjustments.

ISRO’s NavIC Expansion Plans Continue

The NVS-02 is the second satellite in India’s second-generation regional navigation system, known as the Navigation with Indian Constellation (NavIC). The system is designed to provide precise Position, Velocity, and Timing (PVT) services across India and surrounding regions. The first satellite in the series was launched in 2023, and further deployments are planned to strengthen the NavIC network. Despite the current setback, ISRO officials have affirmed that efforts are underway to optimise the mission’s outcome.

A supernova has been captured by the NASA/ESA Hubble Space Telescope in the constellation Gemini. The stellar explosion, visible as a bright blue dot, was detected in the hazy outer disk of a galaxy that lies approximately 600 million light-years away. The image, which also includes several distant galaxies and foreground stars, was taken nearly two months after the supernova, designated SN 2022aajn, was discovered. The phenomenon has not been the subject of detailed research since its detection in November 2022.

Astronomers Use Supernovae to Measure Distances

As per reports, SN 2022aajn is classified as a Type Ia supernova, which occurs when a dead star’s core explodes. Type Ia supernovae are considered vital for measuring distances across the universe since they share a consistent intrinsic brightness. By comparing their observed brightness from Earth to their known luminosity, astronomers can determine how far away they are. However, intergalactic dust presents a challenge, as it can alter the apparent brightness and colour of these explosions, complicating distance calculations.

Hubble’s Role in Supernova Studies

Observations of SN 2022aajn were part of a broader effort to refine distance measurements. As per reports, Hubble is conducting a survey of 100 Type Ia supernovae using seven different wavelength bands, ranging from ultraviolet to near-infrared. The image of SN 2022aajn was created using four infrared wavelengths, which allow scientists to analyse how much of the supernova’s light is obscured by cosmic dust. By comparing brightness variations across these wavelengths, researchers aim to improve methods for determining distances to galaxies billions of light-years away.