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Pebble accretion may accelerate the formation of planets by a factor of 1000 compared to the accretion of planetesimals, allowing giant planets to form before the dissipation of the gas disk. [ 28 ] [ 29 ] However, core growth via pebble accretion appears incompatible with the final masses and compositions of Uranus and Neptune . [ 30 ]
The currently accepted method by which the planets formed is accretion, in which the planets began as dust grains in orbit around the central protostar. Through direct contact and self-organization , these grains formed into clumps up to 200 m (660 ft) in diameter, which in turn collided to form larger bodies ( planetesimals ) of ~10 km (6.2 mi ...
This process increases the cross section over which the large bodies can accrete material, accelerating their growth. The rapid growth of the planetesimals via pebble accretion allows for the formation of giant planet cores in the outer Solar System before the dispersal of the gas disk.
Finally, during the last stages of planet building, a stochastic process of protoplanetary accretion can randomly alter the spin axis of the planet. [81] There is great variation in the length of day between the planets, with Venus taking 243 days to rotate, and the giant planets only a few hours. [ 82 ]
The dynamo ceased within 0.5 billion years of the planet's formation. [2] Hf/W isotopes derived from the martian meteorite Zagami, indicate rapid accretion and core differentiation of Mars; i.e. under 10 million years. [23] Potassium-40 could have been a major source of heat powering the early Martian dynamo. [27]
The accretion process can convert about 10 percent to over 40 percent of the mass of an object into energy as compared to around 0.7 percent for nuclear fusion processes. [5] In close binary systems the more massive primary component evolves faster and has already become a white dwarf , a neutron star, or a black hole, when the less massive ...
Core formation utilizes several mechanisms in order to control the movement of metals into the interior of a planetary body. [3] Examples include percolation, diking, diapirism, and the direct delivery of impacts are mechanisms involved in this process. [3] The metal to silicate density difference causes percolation or the movement of a metal ...
[22] [34] The latter scenario is thought to be the most promising one, because it can explain the formation of the giant planets in relatively low-mass disks (less than 0.1 M ☉). [34] In this model giant planet formation is divided into two stages: a) accretion of a core of approximately 10 M E and b) accretion of gas from the protoplanetary ...