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We\u2019ve never needed good science more than we do right now.<\/strong> The Keck Observatory published this original story on October 22, 2025. Edits by EarthSky.<\/p>\n Astronomers at the Keck Observatory said on October 22, 2025, that they\u2019ve identified a white dwarf star that\u2019s still actively tearing apart its ancient planetary system. A white dwarf is the core of a dead star that has exhausted its fuel supply.<\/p>\n Located 145 light-years from Earth, this white dwarf \u2013 named LSPM J0207+3331 \u2013 hosts the oldest and most heavy metal-rich debris disk ever observed around a hydrogen-rich white dwarf. And now, this raises new questions about the long-term stability of planetary systems billions of years after stellar death. <\/p>\n \u00c9rika Le Bourdais of the Trottier Institute for Research on Exoplanets at Universit\u00e9 de Montr\u00e9al led the study. The Astrophysical Journal<\/em> published the peer-reviewed study on October 22, 2025.<\/p>\n Le Bourdais said:<\/p>\n This discovery challenges our understanding of planetary system evolution. Ongoing accretion at this stage suggests white dwarfs may also retain planetary remnants still undergoing dynamical changes.<\/p>\n<\/blockquote>\n Researchers looked at spectroscopic data from the High-Resolution Echelle Spectrometer (HIRES) instrument on Keck I. The data revealed the white dwarf\u2019s atmosphere is polluted with 13 chemical elements. And those elements provide evidence of a rocky body at least 120 miles (193 kilometers) wide that the star\u2019s gravity tore apart.<\/p>\n Keck Observatory Chief Scientist John O\u2019Meara said:<\/p>\n This is one of the very few times we can see direct evidence of planets being ripped apart and falling onto a dead star. We don\u2019t have many of these systems where we see polluted white dwarfs. This particular system has the largest amount of heavy elements seen to date which proves it was an old, rocky planet.<\/p>\n<\/blockquote>\n Hydrogen-rich atmospheres around white dwarfs typically mask such elemental signatures, making this detection especially significant. Co-investigator John Debes of the Space Telescope Science Institute in Baltimore, Maryland, said: <\/p>\n Something clearly disturbed this system long after the star\u2019s death. There\u2019s still a reservoir of material capable of polluting the white dwarf, even after billions of years.<\/p>\n<\/blockquote>\n Nearly half of all polluted white dwarfs show signs of accreting heavy elements. This is an indication their planetary systems have been dynamically disturbed. In the case of LSPM J0207+3331, a recent perturbation \u2013 within the last few million years \u2013 probably sent a rocky planet spiraling inward. Debes said:<\/p>\n This suggests tidal disruption and accretion mechanisms remain active long after the main-sequence phase of a star\u2019s life. Mass loss during stellar evolution can destabilize orbits, affecting planets, comets and asteroids.<\/p>\n<\/blockquote>\n The system may exemplify delayed instability. Basically, this delay is where multi-planet interactions gradually destabilize orbits over billions of years. Debes added: <\/p>\n This could point to long-term dynamical processes we don\u2019t yet fully understand.<\/p>\n<\/blockquote>\n Now, astronomers are investigating what might have triggered the disruption. Surviving Jupiter-sized planets could be responsible. But they are difficult to detect however, due to their separation from the white dwarf and low temperatures. Data from the European Space Agency\u2019s Gaia space telescope might be sensitive enough to detect such planets through their gravitational influence on the white dwarf.<\/p>\n NASA\u2019s James Webb Space Telescope could also provide insights by taking infrared observations of the system for signs of outer planets. Debes said: <\/p>\n Future observations may help distinguish between a planetary shakeup or the gravitational effect of a stellar close encounter with the white dwarf.<\/p>\n<\/blockquote>\n Bottom line: Astronomers have discovered a dead star is still shredding the remains of its ancient planetary system. The metallic debris is spiraling onto the white dwarf star.<\/p>\n Source: Tracing Planetary Accretion in a 3 Gyr old Hydrogen-rich White Dwarf: The Extremely Polluted Atmosphere of LSPM J0207+3331<\/p>\n Via Keck Observatory<\/p>\n <\/div>\n
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Dead star is still shredding its planetary system<\/h3>\n
Planets falling onto a dead star<\/h3>\n
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Why the delay?<\/h3>\n
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Searching for outer planets<\/h3>\n
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