/ Solar System Content for 麻豆传媒 en /blog/aluminum-isotope-early-solar-system <p><span><span><span><span><span><span><span><span>A little over four and a half billion years ago, dust circling our young sun was collecting into balls that would become planets. Heat from radioactive decay melted these balls of dust into blobs of molten rock, growing as they accumulated more material. A small piece of one of these molten objects broke away and traveled around the solar system for eons before falling to Earth as a meteorite in the Algerian desert. Now, very accurate dating of this meteorite is giving new insight into the formation of the Solar System.</span></span></span></span></span></span></span></span></p> September 05, 2023 - 11:02am Andy Fell /blog/aluminum-isotope-early-solar-system /curiosity/news/deep-mantle-krypton-reveals-earths-outer-solar-system-ancestry <p><span><span><span><span><span><span><span>Krypton from the Earth鈥檚 mantle, collected from geologic hot spots in Iceland and the Galapagos Islands, reveals a clearer picture of how our planet formed, according to new research from the University of California, Davis.</span></span></span></span></span></span></span></p> December 15, 2021 - 10:00am Andy Fell /curiosity/news/deep-mantle-krypton-reveals-earths-outer-solar-system-ancestry /blog/dwarf-planet-vesta-window-early-solar-system <p>The dwarf planet Vesta is helping scientists better understand the earliest era in the formation of our solar system. Two recent papers involving scientists from the University of California, Davis, use data from meteorites derived from Vesta to resolve the 鈥渕issing mantle problem鈥� and push back our knowledge of the solar system to just a couple of million years after it began to form. The papers were published in&nbsp;<a href="https://rdcu.be/cyXhE">Nature Communications</a>&nbsp;Sept. 14 and&nbsp;<a href="https://rdcu.be/cyXhE">Nature Astronomy</a>&nbsp;Sept. 30.</p> October 06, 2021 - 4:30pm Andy Fell /blog/dwarf-planet-vesta-window-early-solar-system /curiosity/news/meteorites-show-transport-material-early-solar-system <p>New studies of a rare type of meteorite show that material from close to the sun reached the outer solar system even as the planet Jupiter cleared a gap in the disk of dust and gas from which the planets formed. The results, published this week in <a href="https://www.pnas.org/content/early/2020/09/01/2005235117">Proceedings of the National Academy of Sciences</a>, add to an emerging understanding of how our solar system formed and how planets form around other stars.</p> September 08, 2020 - 3:05pm Andy Fell /curiosity/news/meteorites-show-transport-material-early-solar-system /curiosity/news/explaining-tiger-stripes-enceladus <p>Saturn鈥檚 tiny, frozen moon Enceladus is a strange place. Just 300 miles across, the moon is thought to have an outer shell of ice covering a global ocean 20 miles deep, encasing a rocky core. Slashed across Enceladus鈥� south pole are four straight, parallel fissures or 鈥渢iger stripes鈥� from which water erupts. These fissures aren鈥檛 quite like anything else in the solar system.&nbsp;</p> December 09, 2019 - 11:53am Andy Fell /curiosity/news/explaining-tiger-stripes-enceladus /curiosity/news/mantle-neon-illuminates-earths-formation <p>The Earth formed relatively quickly from the cloud of dust and gas around the sun, trapping water and gases in the planet鈥檚 mantle, according to research published Dec. 5 in the journal&nbsp;<a href="https://www.nature.com/articles/s41586-018-0771-1"><em>Nature</em></a>. Apart from settling Earth鈥檚 origins, the work could help in identifying extrasolar systems that could support habitable planets.&nbsp;</p> December 05, 2018 - 11:19am Andy Fell /curiosity/news/mantle-neon-illuminates-earths-formation /curiosity-gap/how-did-moon-get-where-it <p>Earth鈥檚 moon is an unusual object in our solar system, and now there鈥檚 a new theory to explain how it got where it is, which puts some twists on the current 鈥済iant impact鈥� theory.</p> September 17, 2018 - 4:47pm Karen Michele Nikos /curiosity-gap/how-did-moon-get-where-it /news/how-moon-formed-inside-vaporized-earth-synestia <p>A new explanation for the moon鈥檚 origin has it forming inside the Earth when our planet was a seething, spinning cloud of vaporized rock, called a <strong><a href="/news/synestia-new-type-planetary-object/">synestia</a></strong>. The new model led by researchers at the University of California, Davis, and Harvard University resolves several problems in lunar formation and is published Feb. 28 in the <a href="http://onlinelibrary.wiley.com/doi/10.1002/2017JE005333/abstract"><em>Journal of Geophysical Research 鈥� Planets</em></a>.</p> February 28, 2018 - 1:49pm Andy Fell /news/how-moon-formed-inside-vaporized-earth-synestia /news/synestia-new-type-planetary-object <p>There鈥檚 something new to look for in the heavens, and it鈥檚 called a 鈥渟ynestia,鈥� according to planetary scientists Simon Lock at Harvard University and Sarah Stewart at the University of California, Davis. A synestia, they propose, would be a huge, spinning, donut-shaped mass of hot, vaporized rock, formed as planet-sized objects smash into each other.</p> May 22, 2017 - 2:47pm Andy Fell /news/synestia-new-type-planetary-object /news/new-theory-explains-how-moon-got-there <p>Earth鈥檚 moon is an unusual object in our solar system, and now there鈥檚 a new theory to explain how it got where it is, which puts some twists on the current 鈥済iant impact鈥� theory. The work is published Oct. 31 in the journal <em>Nature</em>.</p> October 31, 2016 - 11:36am Andy Fell /news/new-theory-explains-how-moon-got-there