European probe snaps first images of the sun's south pole

From the spacecraft's observations, scientists discovered that magnetic fields with both north and south polarity are currently present at the sun's south pole. This mishmash of magnetism is expected to last only a short time during the solar maximum before the magnetic field flips.
Once that happens, a single polarity should slowly build up over time at the poles as the sun heads toward its quiet solar minimum phase, according to ESA.
'How exactly this build-up occurs is still not fully understood, so Solar Orbiter has reached high latitudes at just the right time to follow the whole process from its unique and advantageous perspective,' said Sami Solanki, director of the Max Planck Institute for Solar System Research in Germany and lead scientist for Solar Orbiter's PHI instrument, which is mapping the sun's surface magnetic field.
Scientists have enjoyed close-up images of the sun before, but before now, they have all been captured from around the sun's equator by spacecraft and observatories orbiting along a plane similar to Earth's path around the sun.
But Solar Orbiter's journey through the cosmos included close flybys of Venus that helped tilt the spacecraft's orbit, allowing it to see higher-than-normal latitudes on the sun.
The newly released images were taken in late March, when Solar Orbiter was 15 degrees below the sun's equator, and then a few days later when it was 17 degrees below the equator — a high-enough angle for the probe to directly see the sun's south pole.
'We didn't know what exactly to expect from these first observations — the sun's poles are literally terra incognita,' Solanki said in a statement.
Solar Orbiter was launched in February 2020. The European-led mission is being operated jointly with NASA.
In the coming years, Solar Orbiter's path is expected to tilt even further, bringing even more of the sun's south pole into direct view. As such, the best views may be yet to come, according to ESA.
'These data will transform our understanding of the sun's magnetic field, the solar wind, and solar activity,' said Daniel Müller, ESA's Solar Orbiter project scientist.

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Denmark has become a robotics leader through strategic investment in collaborative robots and automation, creating a thriving ecosystem that attracts international companies and talent.' Mr Miller said: 'Other nations aren't waiting - they're building robotics capabilities that will define their economic futures. While we've been developing excellent innovations, our European neighbours and countries like Australia have been creating the systems and support that turn innovation into economic leadership. We risk becoming developers of technology for other countries to commercialise.' The policy paper highlights what is described by the National Robotarium as 'the stark reality of missed opportunities'. The National Robotarium highlighted the potential for Scotland to become a world leader in robotics amid a global revolution in this arena (Image: National Robotarium) Around 20,000 of 27,000 small and medium sized enterprises in the UK manufacturing sector currently operate without robots, 'representing a massive untapped opportunity for productivity improvement and economic growth', the paper states. It adds: 'If UK automation levels matched the world's most automated countries, productivity could increase by 22%. Over the next decade, robotics and automation technologies could contribute £184 billion to the UK economy, transforming our nation's manufacturing capabilities.' The National Robotarium declared 'the healthcare sector presents equally concerning gaps'. It added: 'While the global healthcare robotics market is projected to grow to £3.4 billion by 2028, Scotland struggles to translate its clinical expertise and innovation capability into systematic adoption, potentially missing out on £21.7 million in annual efficiency savings for NHS Scotland alone.' Read more Mr Miller said: 'We have companies like Edinburgh-based BioLiberty developing breakthrough stroke rehabilitation technology, but they're launching in North American markets because we haven't created the pathways for domestic success.' He added: 'We're funding innovations that primarily benefit other countries.' However, his analysis concludes Scotland is 'uniquely positioned to reverse this trend and establish genuine robotics leadership', the National Robotarium noted, adding: 'Unlike countries starting from scratch, Scotland possesses world-class research excellence, outstanding engineering heritage, and proven entrepreneurial spirit.' Stewart Miller, chief executive of Heriot-Watt University's National Robotarium (Image: Ben Glasgow/ National Robotarium) Mr Miller said: 'The difference between concern and optimism is action. Scotland has all the ingredients needed - we just need to combine them more effectively.' He declared the National Robotarium had 'demonstrated what's possible', supporting more than 100 jobs and nurturing 14 innovative companies in less than three years. Mr Miller added: 'This success can be replicated and scaled.' The National Robotarium said: 'The offshore renewables sector offers immediate opportunities, with robotics applications in wind farm operations alone representing a £341 million annual market by 2030. Scotland's global leadership in offshore energy provides a natural platform for marine robotics excellence. 'Healthcare presents extraordinary potential for Scottish innovation. 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It added: 'With over a hundred companies worldwide receiving billions in investment to develop genuinely human-capable systems, Scotland's combination of AI expertise and robotics capability positions it perfectly for this next wave of innovation.' Mr Miller hammered home his view that Scotland's advantages extend beyond technology to include cultural and institutional strengths. He believes Scotland's collaborative approach between industry, academia, and government - 'exemplified by the National Robotarium's 'triple helix' model' - creates 'ideal conditions for rapid ecosystem development'. The National Robotarium declared its track record 'provides compelling evidence of Scotland's potential'. It added: 'Since launching in September 2022, the facility has become internationally recognised, with the Tony Blair Institute for Global Change citing its model in their landmark October 2024 report on robotics leadership. 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