Formation History of Asteroid Itokawa Analyzed by Synchrotron Radiation Technique (Press Release)
- Release Date
- 26 Aug, 2011
- BL15XU (WEBRAM)
Tohoku University
High Energy Accelerator Research Organization (KEK)
Key research findings
• The mineral composition of granular samples of asteroid Itokawa was analyzed, for the first time in the world, using synchrotron radiation X-ray diffraction.*1
• Itokawa is made of materials having a composition similar to LL3-LL6 chondrite meteorites.
• The temperature at the core of the parent body of Itokawa increased to approximately 800oC. Then, another asteroid struck and smashed Itokawa. Itokawa now is an asteroid made of reassembled pieces of the original interior.
Tomoki Nakamura (Associate Professor) at the Department of Earth and Planetary Material Sciences, Faculty of Science, Tohoku University, and his colleagues, in cooperation with scientists from KEK (Director General, Atsuto Suzuki), analyzed granular samples of the asteroid Itokawa, returned to Earth in a capsule by the asteroid explorer Hayabusa developed by the Japan Aerospace Exploration Agency (JAXA), using a high-resolution electron microscope and synchrotron X-rays at SPring-8. They clarified, for the first time in the world, the material composition of Itokawa and its formation history. It is considered that the dust constituting the primordial solar nebula accumulated in the early stages of solar system formation to form near-Earth asteroids, such as Itokawa, which were the first small asteroids created in the solar system. Therefore, we can determine the mineral composition of asteroids when the solar system was formed by analyzing samples collected from asteroids. In addition, the history of thermal metamorphism reveals the formation history of asteroids as well as information on the early stages of planet formation. It is considered that most of the meteorites that fall to Earth originate from asteroids, which is also confirmed by the results of this study. For the 38 granular samples (with diameters in the range of 30-150 µm) recovered from the surface of the asteroid Itokawa by the asteroid explorer Hayabusa, the mineral content and chemistry of the samples were examined in detail using synchrotron radiation X-ray diffraction (Fig. 1) and high-resolution electron microscopy (Fig. 2). The results indicate that the 38 granular samples are pieces of LL chondrites*2 (Fig. 3). It was found that some samples had been heated to a high temperature inside the parent asteroid, whereas others had not (Fig. 2). From these findings, the scientists concluded the following about the origin and formation process of Itokawa (Fig. 4). It is considered that the parent body of Itokawa was initially approximately 20 km in diameter. The temperature at the core of the parent asteroid reached 800oC, then slowly decreased. After that, another asteroid struck and smashed Itokawa; the scattered pieces of the original interior reassembled to form the present asteroid Itokawa. The achievements of this study were obtained through an initial analysis of samples recovered from a near-Earth asteroid for the first time in human history. It is expected that results of the future detailed analysis will help clarify the formation process of small asteroids in the primordial solar system and the metamorphic process of surface materials after asteroid formation. The results were published online in the special issue "Hayabusa at Asteroid Itokawa" of the American scientific journal Science on 25 August 2011 along with five other papers reporting the results of the analysis of Itokawa granular samples by other methods. Publication: |
<<Glossary>>
*1 Synchrotron radiation X-ray diffraction
Extremely intense electromagnetic waves that are generated when electrons travelling at approximately the speed of light are deflected by magnets are called synchrotron radiation. It is possible to determine the type, content, and crystal orientation of minerals contained in granular samples using diffraction patterns obtained from synchrotron radiation X-rays within a certain wavelength region. In addition, results for the atomic distance in the crystals can provide clues to understanding the environment in which the minerals were formed. The intensity and parallelism of synchrotron radiation X-rays are especially high, which increases the measurement accuracy by sharpening the diffraction peaks.
*2 LL chondrites
Meteorites are divided into three types depending on their constituents; aerolites, siderolites, and iron meteorites. Among the aerolites, chondrites refer to meteorites that have spherules with a diameter of approximately 1 mm consisting of chondrules (which are mainly silicate minerals, such as olivine and pyroxene). Chondrites are further divided into five types depending on the metallic iron content in the chondrite and the iron content in the silicate mineral included: E chondrites, H chondrites, L chondrites, LL chondrites, and carbonaceous chondrites. H chondrites, L chondrites, and LL chondrites are collectively called ordinary chondrites. Depending on the thermal metamorphic grade of the chondrite, the petrologic type, represented by a number from 3 to 6, is added to the group name (e.g., LL6).
<<Figures>>
using synchrotron radiation from KEK Photon Factory
The type and content of the minerals existing in the particle (approximately 100 µm in size) were determined nondestructively. The particle contains olivine (O), low-Ca pyroxene (LPx), high-Ca pyroxene (HPx), and plagioclase (Pl).
by thermal annealing (left) and an LL5-6 particle significantly
affected by thermal annealing (right)
In the high-Mg and low-Ca clinopyroxene (left), bright and dark areas coexist, indicating an inhomogeneous distribution of elements in the crystals. In the crystals shown on the right, no such inhomogeneous distribution is observed.
contained in the 38 granular particles analyzed by electron microscopy
Fs refers to the molar ratio (%) of iron to iron+magnesium contained in the low-Ca pyroxene. Fa refers to the molar ratio (%) of iron to iron+magnesium contained in the olivine.
(1) Original materials such as chondrules accumulated in the primordial solar nebula, and formed the parent body of Itokawa.
(2) The diameter of the parent body of Itokawa increased to approximately 20 km. The temperature at the core of the parent body of Itokawa increased to approximately 800oC. The red region indicates the high-temperature region (LL5-6), whereas the green region indicates the low-temperature region (LL4), where information on the original materials remains.
(3) After the parent body cooled down, another asteroid struck and smashed the original Itokawa.
(4) Most of the pieces dissipated into the cosmic space.
(5) Some of the scattered pieces reassembled to form Itokawa, and LL3-6 breccia were formed.
(6) As a result of space weathering, the present Itokawa was formed.
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For more information, please contact: Dr. Hironori Nakao (KEK) |
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