<P> The inner Solar System's period of giant impacts probably played a role in the Earth acquiring its current water content (~ 6 × 10 kg) from the early asteroid belt . Water is too volatile to have been present at Earth's formation and must have been subsequently delivered from outer, colder parts of the Solar System . The water was probably delivered by planetary embryos and small planetesimals thrown out of the asteroid belt by Jupiter . A population of main - belt comets discovered in 2006 has been also suggested as a possible source for Earth's water . In contrast, comets from the Kuiper belt or farther regions delivered not more than about 6% of Earth's water . The panspermia hypothesis holds that life itself may have been deposited on Earth in this way, although this idea is not widely accepted . </P> <P> According to the nebular hypothesis, the outer two planets may be in the "wrong place". Uranus and Neptune (known as the "ice giants") exist in a region where the reduced density of the solar nebula and longer orbital times render their formation highly implausible . The two are instead thought to have formed in orbits near Jupiter and Saturn, where more material was available, and to have migrated outward to their current positions over hundreds of millions of years . </P> <P> The migration of the outer planets is also necessary to account for the existence and properties of the Solar System's outermost regions . Beyond Neptune, the Solar System continues into the Kuiper belt, the scattered disc, and the Oort cloud, three sparse populations of small icy bodies thought to be the points of origin for most observed comets . At their distance from the Sun, accretion was too slow to allow planets to form before the solar nebula dispersed, and thus the initial disc lacked enough mass density to consolidate into a planet . The Kuiper belt lies between 30 and 55 AU from the Sun, while the farther scattered disc extends to over 100 AU, and the distant Oort cloud begins at about 50,000 AU . Originally, however, the Kuiper belt was much denser and closer to the Sun, with an outer edge at approximately 30 AU . Its inner edge would have been just beyond the orbits of Uranus and Neptune, which were in turn far closer to the Sun when they formed (most likely in the range of 15--20 AU), and in 50% of simulations ended up opposite locations, with Uranus farther from the Sun than Neptune . </P> <P> According to the Nice model, after the formation of the Solar System, the orbits of all the giant planets continued to change slowly, influenced by their interaction with the large number of remaining planetesimals . After 500--600 million years (about 4 billion years ago) Jupiter and Saturn fell into a 2: 1 resonance: Saturn orbited the Sun once for every two Jupiter orbits . This resonance created a gravitational push against the outer planets, possibly causing Neptune to surge past Uranus and plough into the ancient Kuiper belt . The planets scattered the majority of the small icy bodies inwards, while themselves moving outwards . These planetesimals then scattered off the next planet they encountered in a similar manner, moving the planets' orbits outwards while they moved inwards . This process continued until the planetesimals interacted with Jupiter, whose immense gravity sent them into highly elliptical orbits or even ejected them outright from the Solar System . This caused Jupiter to move slightly inward . Those objects scattered by Jupiter into highly elliptical orbits formed the Oort cloud; those objects scattered to a lesser degree by the migrating Neptune formed the current Kuiper belt and scattered disc . This scenario explains the Kuiper belt's and scattered disc's present low mass . Some of the scattered objects, including Pluto, became gravitationally tied to Neptune's orbit, forcing them into mean - motion resonances . Eventually, friction within the planetesimal disc made the orbits of Uranus and Neptune circular again . </P>

How did the valley of the moon form