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\t\t\t\t\t\t21\/02\/2024<\/span> At approximately 18:17 CET (17:17 UTC) on Wednesday 21 February 2024, ESA\u2019s ERS-2 satellite completed its atmospheric reentry over the North Pacific Ocean. No damage to property has been reported. <\/i><\/p>\n<\/p><\/div>\n ESA\u2019s second European Remote Sensing satellite, ERS-2, was launched almost 30 years ago, on 21 April 1995. Together with the almost-identical ERS-1, it provided invaluable long-term data on Earth\u2019s land surfaces, ocean temperatures, ozone layer and polar ice extent that revolutionised our understanding of the Earth system. It was also called upon to monitor and assist the response to natural disasters.<\/p>\n \u201cThe ERS satellites have provided a stream of data which has changed our view of the world in which we live,\u201d said ESA\u2019s Director of Earth Observation Programmes, Simonetta Cheli. \u201cThey have provided us with new insights on our planet, the chemistry of our atmosphere, the behavior of our oceans, and the effects of mankind\u2019s activity on our environment \u2013 creating new opportunities for scientific research and applications.\u201d<\/p>\n Having far exceeded its planned lifetime of three years, ESA took the decision to deorbit ERS-2 in 2011 in light of growing concern over the long-term hazard that orbital debris poses to current and future space activities.<\/p>\n<\/p><\/div>\n The satellite\u2019s altitude had been declining steadily ever since. On 21 February 2024, it reached the critical altitude of around 80 km at which the atmospheric drag was so strong that began to break into pieces.<\/p>\n An international campaign involving the Inter-Agency Space Debris Coordination Committee and ESA\u2019s Space Debris Office monitored the reentry.<\/p>\n<\/p><\/div>\n \u201cUncontrolled Atmospheric reentry has long been a common method for disposing of space objects at the end of their mission,\u201d said Tim Flohrer, Head of ESA\u2019s Space Debris Office. \u201cWe see objects similar in size or larger to ERS-2 reentering the atmosphere multiple times each year.\u201d<\/p>\n \u201cIn the 67 years of spaceflight, thousands of tons of artificial space objects have reentered the atmosphere. Pieces that make it to the surface have only very rarely caused any damage and there has never been a confirmed report of a human injury.\u201d<\/p>\n ERS-2\u2019s reentry was \u2018natural\u2019. All of its remaining fuel was depleted during deorbiting to reduce the risk of an internal malfunction causing the satellite to break up into pieces while still at an altitude used by active satellites. As a result, it was not possible to control ERS-2 at any point during its reentry and the only force driving its descent was unpredictable atmospheric drag.<\/p>\n This was the best option for disposing of the satellite given the way it was designed in the 1980s. However, the time and location of a natural reentry are difficult to predict prior to the satellite\u2019s final few hours in space.<\/p>\n<\/p><\/div>\n Natural reentries are no longer the gold standard in space sustainability. By implementing the \u2018ESA Zero Debris approach\u2019, the Agency is committed to ensuring the long-term sustainability of space activities by mitigating the creation of space debris wherever possible and ensuring the safest possible reentry of satellites at the end of their lives. ESA also aims to encourage others to pursue a similar path through the community-led Zero Debris Charter initiative.<\/p>\n ESA\u2019s missions in Earth orbit are now designed to conduct \u2018controlled\u2019 reentries. During a controlled reentry, spacecraft operators can ensure that the satellite comes down over sparsely populated regions on Earth such as the South Pacific Ocean.<\/p>\n Meanwhile, ESA continues to make efforts to dispose of its older satellites (such as ERS-2, Aeolus, Cluster and Integral) in more sustainable ways than were originally planned.<\/p>\n<\/p><\/div>\n ERS-2, and its predecessor ERS-1, were the most sophisticated satellites ever developed and launched by Europe. The satellite carried a suite of scientific instruments and technologies into orbit that collected valuable data for more than one and a half decades, including Europe’s first instrument to study atmospheric ozone. The ERS heritage datasets are today curated and made accessible through ESA\u2019s Heritage Space Programme.<\/p>\n The ERS satellites also set the stage for many successor missions dedicated to studying our changing world, such as Envisat, the MetOp weather satellites, ESA\u2019s Earth Explorer scientific research missions and the Copernicus Sentinels, as well as many other national satellite missions.<\/p>\n \u201cERS heritage data are still widely used today mostly in combination with data from newer missions as long-term data records are for example essential for identifying and understanding changes to our climate,\u201d said ESA\u2019s Heritage Space Programme Manager, Mirko Albani. \u201cThe mission is also a great example of how ESA pioneers new technologies that later become operational to support services such as weather forecasting and climate monitoring that benefit the citizens of ESA Member States and people around the world\u201d.<\/p>\n<\/p><\/div>\n
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\n\t\t\t\t\t\t\t\t<\/figcaption><\/figure>\nAtmospheric reentry \u2013 past, present and future<\/h2>\n
\n\t\t\t\t\t\t\t\t<\/figcaption><\/figure>\nMission legacy<\/h2>\n