June 10, 2022
Release Type: Research News
Headline: What happened before, during and after solar system formation? A recent study of the Asteroid Ryugu holds the answers!
Subheadline:
A team of scientists undertake a comprehensive analysis of samples
returned from the Japan Aerospace Exploration Agency’s Hayab#usa2
mission and provide invaluable insights into the formation and evolution
of our solar system.
Summary
The Japan Aerospace Exploration Agency’s (JAXA) Hayabusa2 mission
returned uncontaminated primitive asteroid samples to Earth. A
comprehensive analysis of 16 particles from the asteroid Ryugu revealed
many insights into the processes that operated before, during and after
the formation of the solar system, with some still shaping the surface
of the present-day asteroid. Elemental and isotopic data revealed that
Ryugu contains the most primitive pre-solar nebular (an ancient disk of
gas and dust surrounding what would become the Sun) material yet
identified and that some organic materials may have been inherited from
before the solar system formed. Among the organic materials identified
were amino acids, which are the building blocks of the proteins that are
in all living things on Earth. The discovery of protein forming amino
acids in uncontaminated asteroid samples indicates that asteroids such
as Ryugu may have seeded the Earth with the raw materials required for
the origin of life. Furthermore, Ryugu samples provided both physical
and chemical evidence that Ryugu originated from a large (at least
several 10’s of km) icy body in outer solar system, which experienced
aqueous alteration (complex chemical reactions involving liquid water).
The icy body was then broken up to yield a comet-like fragment (several
km in size). The fragment evolved through sublimation of ice to yield
the dry porous asteroid observed today. Subsequently, space weathering,
involving the bombardment of the asteroid by particles from the sun and
distant stars, altered the surface materials, such as organic matter, to
give materials with a distinct albedo (reflective properties), defining
how the asteroid currently appears.
Full Text
Asteroids and comets represent the material that was left over after the
formation of the planets that orbit the Sun. Such bodies would have
initially formed in a vast disk of gas and dust (protosolar nebular)
around what would eventually become the Sun (protosun) and thus can
preserve clues about the processes that operated during this period of
the Solar system. The protosolar nebular would have been spinning
fastest towards its center and this would have concentrated much of the
material within this region. Some of the material then began to fall
onto the surface of the protosun, increasing its temperature. The higher
temperature of the protosun would have led to an increased output of
radiation, which could have caused photoevaporation (evaporation due to
energy from light) of the material within the inner solar system. Later,
as the inner solar system cooled, new material condensed with distinct
compositions to what had been present before. Eventually such materials
would stick together to produce large bodies (planetesimals) that would
then break up from collisions, with some forming S-type asteroids. One
S-type asteroid (Itokawa) was the target of the Hayabusa mission, the
predecessor of Hayabusa2. The samples that were returned to Earth
revealed a lot about such asteroids, including how their surfaces are
affected by continuous small impacts and confirming identifications made
through telescopes on Earth.
Haybusa2 targeted a very different type of asteroid, C-type, which
unlike S-types preserve far more of the primitive outer solar system
material, which was much less affected by heating from the protosun.
Initial Earth based telescope and remote sensing information from the
Hayabusa2 spacecraft suggested that Ryugu may contain organic matter and
small amounts water (stuck to the surface of minerals or contained
within their structure). However, C-type asteroids are incredibly hard
to study using such methods, because they are very dark and the
resulting data has very little information that can be used to identify
specific materials. As such, the sample return represented a very
important step in improving our understanding of C-type asteroids.
Around 5.4 g of sample was returned to the Earth in December 2020 and
the samples were initially studied at the Japan Aerospace Exploration
Agency’s (JAXA) phase-1 curation facility at Sagamihara, Japan.
Comprehensive geochemical analysis was begun in June 2021 once the
samples had arrived at the phase-2 curation facility of the Pheasant Memorial Laboratory (PML), Institute for Planetary Materials, Okayama University, Japan.
Initially, the external and physical information of the samples was
obtained (Figure 1), but shortly after the particles were cut open using
a microtome equipped with a diamond knife. Inside, the particles
revealed textures indicative of freeze-thawing and a fine-grained mass
of different minerals, with some coarser-grained components being
dispersed throughout (Figure 2). The majority of the minerals were
hydrous silicates called phyllosilicates (clay), which formed through
chemical reactions involving non-hydrous silicate minerals and liquid
water (aqueous alteration). Together with the freeze-thaw textures, the
evidence indicated that the samples had experienced both liquid and
frozen water in the past.
The aqueous alteration (Figure 3) was found to have peaked before ~2.6
Myr after the formation of the solar system, through analysis of
manganese and chromium within magnetite (iron oxide) and dolomite
(calcium-magnesium carbonate) minerals. This means that the materials
from Ryugu experienced liquid water very early in the Solar System’s
history and the heat that melted the ice would have been supplied from
radioactive elements (Figure 4) that only survive for a relatively short
period of time (almost all would be gone after 5 Myr). After much of
the radioactive elements had decayed the body would cool and freeze
again. Ryugu also contains chromium, calcium and oxygen isotopes that
indicate it preserved the most primitive source of materials from the
protosolar nebular. Furthermore, organic materials from Ryugu record
primitive isotopic signatures suggestive of their formation within the
interstellar medium (the region of space between solar systems) or outer
protosolar nebular. Together with the abundant water and the lack of
any inner solar system material or signatures, the above findings
suggest that the material within Ryugu was stuck together (accreted) and
aqueously altered very early in the outer solar system (Figure 5).
However, to form liquid water, from the heating of a rocky-icy body by
radioactive decay, requires the body to be at least several 10’s of km
in size. Accordingly, Ryugu must have originally been a part of a much
bigger body, termed a planetesimal. Icy planetesimals are thought to be
the source of comets, which can be formed by their collisional break up.
If the planetesimal precursor of Ryugu was impacted after it had
re-frozen, then a comet preserving many of the original textures and
physical and chemical properties of the planetesimal could be produced.
As a comet the fragment would have needed to move from the outer to
inner solar system by some dynamical pathway, involving the interactions
of the planets. Once in the inner solar system Ryugu would have then
undergone significant sublimation (transition of solid ice to gas).
Modelling in a previous study indicated that the sublimation could
increase the rate at which Ryugu spins and lead to its distinctive
spinning top shape. The sublimation could have also led to the formation
of water vapor jets (as seen on the comet 67P) that would have
redeposited subsurface material onto the surface and frozen it in place
(Figure 6).
Moreover, the jets may be able to explain some interesting differences
between the sampling sites where the Ryugu samples were obtained. The
Hayabusa2 mission sampled material from the very surface at touch down
site 1 (TD1) and most likely subsurface material from an artificial
impact crater at touch down site 2 (TD2). Some of the TD1 samples show
elemental fractionation beyond the mm scale and scattered B and Be
abundances. However, all TD2 samples record elemental abundances similar
to CI chondrites (a type of meteorite with elemental abundances similar
to the Sun) and show no evidence of elemental fractionation over the mm
scale. One explanation is that the TD1 site records the material
entrained in a jet, brought to the surface of the comet-like fragment
from many distinct regions of the subsurface and thus represents a wide
variety of compositions. Meanwhile, the TD2 samples may represent
material sourced from one part of Ryugu and as such have a more uniform
composition.
After complete sublimation of the ice at the surface of Ryugu, a low
density and highly porous rocky asteroid was formed. While water related
processes ceased, space weathering began. The surface of Ryugu was
bombarded over time by large quantities of energetic particles from
solar wind and cosmic rays from the sun and distant stars. The particles
modified the materials on the surface of Ryugu, causing the organic
matter to alter in terms of its structure. The effects of such a process
were more obvious in TD1 particles from the surface of Ryugu when
compared to those from TD2, which had likely been brought to the surface
during the creation of an artificial impact crater. As such, space
weathering is a process that still shapes the surfaces of asteroids
today and will continue to do so in the future.
Despite the effects of space weathering, which act to alter and destroy
the information contained within organic matter, primitive organic
materials were also detected by the comprehensive geochemical analysis
of the Ryugu samples. Amino acids, such as those found within the
proteins of every living organism on Earth, were detected in a Ryugu
particle. The discovery of protein forming amino acids is important,
because Ryugu has not been exposed to the Earth’s biosphere, like
meteorites, and as such their detection proves that at least some of the
building blocks of life on Earth could have been formed in space
environments. Hypotheses concerning the origin of life, such as those
involving hydrothermal activity, require sources of amino acids, with
meteorites and asteroids like Ryugu representing strong candidates due
to their inventory of amino acids and because such material would have
been readily delivered to the surface of the early Earth. Additionally,
the isotopic characteristics of the Ryugu samples suggest that
Ryugu-like material could have supplied the Earth with its water,
another resource essential for the origin and sustainment of life on
Earth.
In conjunction the findings reported by the study provide invaluable
insights into the processes that have affected the most primitive
asteroid sampled by human kind. Such insights have already begun to
change our understanding of the events that occurred from before the
solar system and up until the current day. Future work on the Ryugu
samples will no doubt continue to advance our knowledge of the solar
system and beyond.
Website : Pheasant Memorial Laboratory
https://www.okayama-u.ac.jp/eng/research_highlights/index_id161.html
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