How Earth Survived Birth
New Simulation Reveals Planet Migration Prevents Plunge into Sun
Planets form out of swirling disks of gas and dust.
Credit: Gemini Observatory/Jon Lombergem
For the last 20 years, the best models of planet formation – or how planets grow from dust in a gas disk – have contradicted the very existence of Earth. These models assumed locally constant temperatures within a disk. Now, new simulations from researchers at the American Museum of Natural History and the University of Cambridge show that variations in temperature can lead to regions of outward and inward migration that trap planets on orbits. When the protoplanetary disk begins to dissipate, planets are left behind, safe from impact with their parent star.
“We are trying to understand how planets interact with the gas disks from which they form as the disk evolves over its lifetime,” says Mordecai-Mark Mac Low, Curator of Astrophysics and Division Chair of Physical Sciences at the Museum. “We show that the planetoids from which the Earth formed can survive their immersion in the gas disk without falling into the Sun.”
During the birth of a star, a disk of gas and dust forms. The midplane of this dusty disk is opaque and cannot quickly cool by radiating heat to outer space. Until recently, no one has included temperature variation in models of planet formation. Co-author Sijme-Jan Paardekooper of the University of Cambridge ran new simulations like that most recently published online (http://arxiv.org/abs/0909.4552). His work shows that the direction of migration of low-mass planets in disks depends on the detailed temperature structure of the disk. This key insight lays the groundwork for the current work.
The American Astronomical Society presentation incorporates the results of Paardekooper’s local models into the long-term evolution of the temperature and density structure of a protoplanetary disk. The result of the simulation is that, over the lifetime of a disk, planets get trapped in orbits between regions of inward and outward migration.
Visualization of the Sun’s interior in relation to planetary orbits and surrounding stars (all pulled from American Museum of Natural History’s curated three dimensional atlas of the universe). The image is taken from AMNH’s new space show, Journey to the Stars.
The orbits slowly move inward as the disk dissipates. Once the gas densities drop low enough for the planets to no longer be influenced by disk, the planets are dropped into an orbit similar to the orbits of planets around the Sun. The radius of the orbit at which a planet is released depends on its mass.
“We used a one-dimensional model for this project,” says co-author Wladimir Lyra, a postdoctoral researcher in the Department of Astrophysics at the Museum. “Three dimensional models are so computationally expensive that we could only follow the evolution of disks for about 100 orbits — about 1,000 years. We want to see what happens over the entire multimillion year lifetime of a disk.”
Mac Low presented this research at the American Astronomical Society meeting in Washington, D.C., on January 6. A research paper is currently submitted to The Astrophysical Journal, authored by Lyra, Paardekooper, and Mac Low. This research was funded by the American Museum of Natural History, the National Science Foundation, and NASA.