The origin of water on Earth is the subject of a significant body of research in the fields of planetary science, astronomy, and astrobiology. Earth is unique among the rocky planets in the Solar System in that it is the only planet with oceans of liquid water
on its surface. Liquid water, which is necessary for life, continues to
exist on the surface of Earth because the planet is distant enough from
the Sun that it does not lose its water to the runaway greenhouse effect, but not so far that low temperatures cause all water on the planet to freeze.
Earth could not have condensed from the protoplanetary disk
with its current oceans of water because the early inner Solar System
was far too hot for water to condense. Instead, water and other volatiles must have been delivered to Earth from the outer Solar System later in its history. Modern geochemical evidence suggests that water was delivered to Earth by impacts from icy planetesimals similar in composition to modern asteroids in the outer edges of the asteroid belt. However, when and how that water was delivered to Earth is the subject of ongoing research.
History of water on Earth
One factor in estimating when water appeared on Earth is that water is continually being lost to space. H2O molecules in the atmosphere are broken up by photolysis, and the resulting free hydrogen atoms can sometimes escape Earth's gravitational pull. When the Earth was younger and less massive, water would have been lost to space more easily. Lighter elements like hydrogen and helium are expected to leak from the atmosphere continually, but isotopic ratios of heavier noble gases in the modern atmosphere suggest that even the heavier elements in the early atmosphere were subject to significant losses. In particular, xenon
is useful for calculations of water loss over time. Not only is it a
noble gas (and therefore is not removed from the atmosphere through
chemical reactions with other elements), but comparisons
between abundances of its seven stable isotopes in the modern
atmosphere reveal that the Earth lost at least one ocean of water early
in its history, between the Hadean and Archean eras.
Any water on Earth during the later part of its accretion would have been disrupted by the Moon-forming impact (~4.5 billion years ago), which likely vaporized much of Earth's crust and upper mantle and created a rock-vapor atmosphere around the young planet.
The rock vapor would have condensed within two thousand years, leaving
behind hot volatiles which probably resulted in a majority carbon dioxide atmosphere with hydrogen and water vapor.
Afterwards, liquid water oceans may have existed despite the surface
temperature of 230 °C (446 °F) due to the increased atmospheric pressure
of the CO2 atmosphere. As cooling continued, most CO2 was removed from the atmosphere by subduction and dissolution in ocean water, but levels oscillated wildly as new surface and mantle cycles appeared.
There is also geological evidence that helps constrain the time frame
for liquid water existing on Earth. A sample of pillow basalt (a type
of rock formed during an underwater eruption) was recovered from the Isua Greenstone Belt and provides evidence that water existed on Earth 3.8 billion years ago. In the Nuvvuagittuq Greenstone Belt, Quebec, Canada, rocks dated at 3.8 billion years old by one study and 4.28 billion years old by another show evidence of the presence of water at these ages.
If oceans existed earlier than this, any geological evidence either has
yet to be discovered or has since been destroyed by geological
processes like crustal recycling.
Unlike rocks, minerals called zircons
are highly resistant to weathering and geological processes and so are
used to understand conditions on the very early Earth. Mineralogical
evidence from zircons has shown that liquid water and an atmosphere must
have existed 4.404 ± 0.008 billion years ago, very soon after the
formation of Earth. This presents somewhat of a paradox, as the cool early Earth
hypothesis suggests temperatures were cold enough to freeze water
between about 4.4 billion and 4.0 billion years ago. Other studies of
zircons found in Australian Hadean rock point to the existence of plate tectonics as early as 4 billion years ago. If true, that implies that rather than a hot, molten
surface and an atmosphere full of carbon dioxide, early Earth's surface
was much as it is today. The action of plate tectonics traps vast
amounts of CO2, thereby reducing greenhouse effects, and leading to a much cooler surface temperature, and the formation of solid rock and liquid water.
Earth's water inventory
While
the majority of Earth's surface is covered by oceans, those oceans make
up just a small fraction of the mass of the planet. The mass of Earth's
oceans is estimated to be 1.37 x 1021 kg, which is 0.023% of the total mass of Earth, 6.0 x 1024 kg. An additional 0.5 x 1021 kg of water is estimated to exist in ice, lakes, rivers, groundwater, and atmospheric water vapor. A significant amount of water is also stored in Earth's crust, mantle, and core. Unlike molecular H2O that is found on the surface, water in the interior exists primarily in hydrated minerals or as trace amounts of hydrogen bonded to oxygen atoms in anhydrous minerals. Hydrated silicates on the surface transport water into the mantle at convergent plate boundaries, where oceanic crust is subducted underneath continental crust.
While it is difficult to estimate the total water content of the mantle
due to limited samples, approximately three times the mass of the
Earth's oceans could be stored there. Similarly, the Earth's core could contain four to five oceans worth of hydrogen.
Hypotheses for the origins of Earth's water
Extraplanetary sources
Water
has a much lower condensation temperature than other materials that
compose the terrestrial planets in the Solar System, such as iron and
silicates. The region of the protoplanetary disk
closest to the Sun was very hot early in the history of the Solar
System, and it is not feasible that oceans of water condensed with the
Earth as it formed. Further from the young Sun where temperatures were
cooler, water could condense and form icy planetesimals. The boundary of the region where ice could form in the early Solar System is known as the frost line (or snow line), and is located in the modern asteroid belt, between about 2.7 and 3.1 astronomical units (AU) from the Sun. It is therefore necessary that objects forming beyond the frost line–such as comets, trans-Neptunian objects, and water-rich meteoroids (protoplanets)–delivered water to Earth. However, the timing of this delivery is still in question.
One theory claims that Earth accreted (gradually grew by accumulation of) icy planetesimals about 4.5 billion years ago, when it was 60 to 90% of its current size.
In this scenario, Earth was able to retain water in some form
throughout accretion and major impact events. This hypothesis is
supported by similarities in the abundance and the isotope ratios of
water between the oldest known carbonaceous chondrite meteorites and meteorites from Vesta, both of which originate from the Solar System's asteroid belt. It is also supported by studies of osmium isotope ratios, which suggest that a sizeable quantity of water was contained in the material that Earth accreted early on. Measurements of the chemical composition of lunar samples collected by the Apollo 15 and 17 missions further support this, and indicate that water was already present on Earth before the Moon was formed.
One problem with this hypothesis is that the noble gas
isotope ratios of Earth's atmosphere are different from those of its
mantle, which suggests they were formed from different sources.
To explain this observation, a so-called "late veneer" theory has been
proposed in which water was delivered much later in Earth's history,
after the Moon-forming impact. However, our current understanding of
Earth's formation allows for less than 1% of Earth's material accreting
after the Moon formed, implying that the material accreted later must
have been very water-rich. Models of early Solar System dynamics have
shown that icy asteroids could have been delivered to the inner Solar
System (including Earth) during this period if Jupiter migrated closer
to the Sun.
Yet a third hypothesis, supported by evidence from molybdenum isotope ratios, suggests that the Earth gained most of its water from the same interplanetary collision that caused the formation of the Moon.
Geochemical analysis of water in the Solar System
Isotopic ratios provide a unique "chemical fingerprint" that is used
to compare Earth's water with reservoirs elsewhere in the Solar System.
One such isotopic ratio, that of deuterium
to hydrogen (D/H), is particularly useful in the search for the origin
of water on Earth. Hydrogen is the most abundant element in the
universe, and its heavier isotope deuterium can sometimes take the place
of a hydrogen atom in molecules like H2O. Most deuterium was created in the Big Bang or in supernovae, so its uneven distribution throughout the protosolar nebula was effectively "locked in" early in the formation of the Solar System.
By studying the different isotopic ratios of Earth and of other icy
bodies in the Solar System, we can search for the likely origins of
Earth's water.
Earth
The deuterium to hydrogen ratio for ocean water on Earth is known very precisely to be (1.5576 ± 0.0005) × 10−4.
This value represents a mixture of all of the sources that contributed
to Earth's reservoirs, and is used to identify the source or sources of
Earth's water. The ratio of deuterium to hydrogen may have increased
over the Earth's lifetime as the lighter isotope is more likely to leak
to space in atmospheric loss processes. However no process is known that can decrease Earth's D/H ratio over time. This loss of the lighter isotope is one explanation for why Venus
has such a high D/H ratio, as that planet's water was vaporized during
the runaway greenhouse effect and subsequently lost much of its hydrogen
to space.
Because Earth's D/H ratio has increased significantly over time, the
D/H ratio of water originally delivered to the planet was lower than
what we currently measure. This is consistent with a scenario in which a
significant proportion of the water on Earth was already present during
the planet's early evolution.
Asteroids
Multiple geochemical studies have concluded that asteroids are most likely the primary source of Earth's water. Carbonaceous chondrites–which are a subclass of the oldest meteorites in the Solar System–have isotopic levels most similar to ocean water. The CI and CM subclasses of carbonaceous chondrites specifically have hydrogen and nitrogen
isotope levels that closely match Earth's seawater, which suggests
water in these meteorites could be the source of Earth's oceans.
Two 4.5 billion-year-old meteorites found on Earth that contained
liquid water alongside a wide diversity of deuterium-poor organic
compounds further support this. Earth's current deuterium to hydrogen ratio also matches ancient eucrite chondrites, which originate from the asteroid Vesta in the outer asteroid belt.
CI, CM, and eucrite chondrites are believed to have the same water
content and isotope ratios as ancient icy protoplanets from the outer asteroid belt that later delivered water to Earth.
Comets
Comets are kilometer-sized bodies made of dust and ice that originate from the Kuiper Belt (20-50 AU) and the Oort Cloud
(>5,000 AU), but have highly elliptical orbits which bring them into
the inner solar system. Their icy composition and trajectories which
bring them into the inner solar system make them a target for remote and
in situ measurements of D/H ratios.
It is implausible that Earth's water originated only from comets,
since isotope measurements of the deuterium to hydrogen (D/H) ratio in
comets Halley, Hyakutake, Hale–Bopp, 2002T7, and Tuttle, yield values approximately twice that of oceanic water. Using this cometary D/H ratio, models predict that less than 10% of Earth's water was supplied from comets.
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is one such comet that was the subject of isotopic measurements by the Rosetta spacecraft, which found the comet has a D/H ratio three times that of Earth's seawater. Another Jupiter family comet, 103P/Hartley 2, has a D/H ratio which is consistent with Earth's seawater, but its nitrogen isotope levels do not match Earth's.