Commenting on the achievement, Aspinall said: “This project marks a major milestone for the UK in advancing our space weather monitoring capabilities \u2013 something crucial for safeguarding modern infrastructure and daily life.<\/p>\n
“Bringing this neutron monitor online in collaboration with the Met Office and other international partners adopting our design strengthens global resilience to space weather risks by providing real-time data and new measurement capabilities.<\/p>\n
“With our new design for an instrument that has not fundamentally changed in six decades, we’re not just building on the past \u2013 we’re setting new standards for the future of neutron monitoring.<\/p>\n
“The NM-2023 monitor introduces innovations that improve efficiency, sustainability, and affordability, all the while delivering the critical data needed to better understand and mitigate the impacts of space weather.”<\/p>\n Space weather encompasses a range of environmental phenomena driven by solar activity. Emissions of solar energy and material directed towards Earth can induce changes in the electromagnetic and radiation environment in near-Earth space, the atmosphere, and at the surface.<\/p>\n Under normal solar activity levels, space weather’s impact is minimal. However, natural variations can lead to severe and extreme space weather events.<\/p>\n During such disturbances, the intensity of space weather phenomena can escalate dramatically, posing significant risks to human technology, including satellites, power grids, communications, navigation, and transport infrastructure.<\/p>\n Consequently, space weather is recognised as an environmental risk to critical hardware, infrastructure, and services that underpin our society and economy.<\/p>\n This newly developed neutron monitor joins an international consortium of approximately 45 similar sensors dedicated to continuously observing neutron variations at Earth’s surface.<\/p>\n These observations are crucial for assessing the impacts of space weather phenomena. The project also plans to deploy a smaller monitor at Lancaster University, further bolstering the UK’s monitoring capabilities.<\/p>\n The primary function of the monitor is to detect sudden increases in neutron counts, known as Ground Level Enhancements (GLEs).<\/p>\n These GLEs occur during solar radiation storms, which are triggered by the acceleration of particles near the Sun.<\/p>\n By identifying these neutron spikes, the monitor enables the issuance of timely alerts and aids in validating existing forecasting models for solar radiation storms. Such storms have the potential to disrupt satellites and cause widespread power outages on Earth.<\/p>\n Met Office Space Weather Manager Simon Machin added: \u201cThe new UK-based neutron monitor will enhance global monitoring of space weather events and will be an important part of our ongoing space weather forecasting and validating service.<\/p>\n \u201cWhile severe space weather events are rare, this increased capability and resilience will help scientists and industries to manage risks and mitigate impacts where possible.\u201d<\/p>\n![\"\"](\"https:\/\/www.innovationnewsnetwork.com\/wp-content\/uploads\/2025\/02\/e0e1ab1a-eb31-41ee-8a5f-f2c5ead41b1a-300x171.jpeg\")
Understanding space weather<\/h3>\n
Enhancing global space weather monitoring networks<\/h3>\n
Detecting Ground Level Enhancements<\/h3>\n