Network of thermal cracks in meteorites due to temperature variations: new experimental evidence and implications for asteroid surfaces

Libourel, G.; Ganino, Clément; Delbò, M.; Niezgoda, Mathieu; Rémy, Benjamin; Aranda, Lionel; Michel, Patrick

doi:10.1093/mnras/staa3183

Cited by 16 publications

(38 citation statements)

References 62 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Many returned particles feature curved and straight cracks. Pebbles with a smooth surface could be fragments of particles with straight cracks, possibly formed by shock or thermal fatigue ( 33 ). The common presence of cracks in returned pebbles implies that the small thermal inertia of surface boulders ( 12 , 13 ) is probably due, at least in part, to cracks or fractures in their interior.…”

Section: Samples Returned To Earthmentioning

confidence: 99%

Pebbles and sand on asteroid (162173) Ryugu: In situ observation and particles returned to Earth

Tachibana

Sawada

Okazaki

et al. 2022

Science

100

View full text Add to dashboard Cite

The Hayabusa2 spacecraft investigated the C-type (carbonaceous) asteroid (162173) Ryugu. The mission performed two landing operations to collect samples of surface and subsurface material, the latter exposed by an artificial impact. We present images of the second touchdown site, finding that ejecta from the impact crater was present at the sample location. Surface pebbles at both landing sites show morphological variations ranging from rugged to smooth, similar to Ryugu’s boulders, and shapes from quasi-spherical to flattened. The samples were returned to Earth on 6 December 2020. We describe the morphology of >5 grams of returned pebbles and sand. Their diverse color, shape, and structure are consistent with the observed materials of Ryugu; we conclude that they are a representative sample of the asteroid.

show abstract

Section: Samples Returned To Earthmentioning

confidence: 99%

Pebbles and sand on asteroid (162173) Ryugu: In situ observation and particles returned to Earth

Tachibana

Sawada

Okazaki

et al. 2022

Science

100

View full text Add to dashboard Cite

show abstract

“…Internal stresses caused by differential thermal expansion, as a result of cyclic heating and cooling, lead to regolith breakdown and erosion (Eppes et al 2015). The efficiency of this thermal cycling process has been modeled under the thermal environments of airless solar system bodies (e.g., Molaro & Byrne 2012;Molaro et al 2017), and its feasibility has been experimentally demonstrated on meteorite samples (Delbo et al 2014;Libourel et al 2020). Molaro et al (2020) demonstrated that large cracks observed on rocks seen across Bennu's surface were consistent with thermal fatigue model predictions.…”

Section: Introductionmentioning

confidence: 72%

“…It has been debated whether or not thermal fracturing is a relatively significant weathering mechanism for terrestrial rocks (e.g., Molaro & McKay 2010, and references within), yet Delbo et al (2014) experimentally demonstrated the effectiveness of this process, in vacuo, on a chip of the Murchison (CM2 carbonaceous chondrite) and Sahara 97210 (L/LL3.2 ordinary chondrite) meteorites. Libourel et al (2021) performed a followup study with these two meteorites and Allende (CV3), where they demonstrated that larger temperature gradients, such as those experienced for low perihelion asteroids, result in greater crack growth rates. Images from the encounter of Bennu by OSIRIS-REx provided widespread evidence of thermal cracking across the surface (Molaro et al 2020).…”

Section: Thermal Fatigue Breakdownmentioning

confidence: 99%

Thermophysical Investigation of Asteroid Surfaces. II. Factors Influencing Grain Size

MacLennan

Emery

2022

Planet. Sci. J.

View full text Add to dashboard Cite

Asteroid surfaces are subjected to mechanical weathering processes that result in the development and evolution of regolith. Two proposed mechanisms—impact bombardment and thermal fatigue—have been proposed as viable and dominant weathering processes. Previously, we compiled and estimated thermal inertias of several hundred asteroids (mostly in the main belt) for which we determined dependencies on temperature, diameter, and rotation period. In this work, we estimate grain sizes of asteroid regoliths from this large thermal inertia data set using thermal conductivity models. Following our previous work, we perform multivariate linear model fits to the grain size data set and quantify its dependency on diameter and rotation period. We find that the preferred model indicates that asteroid grain sizes are inversely dependent on object size for <10 km asteroids and exhibit no relationship above this size cutoff. Rotation period and grain size show a positive relationship when the rotation period is greater than ∼5 hr and an inverse relationship below this rotation period. These results indicate that both impact weathering and thermal fatigue are relevant regolith evolution mechanisms. We run post-hoc t-tests between spectral groups to infer the influence of composition on regolith grain sizes. We find that M-type (including suspected metal-rich objects) and E-type asteroids have larger grain sizes relative to our population sample and that P-type asteroids have distinctly smaller grains than other groups.

show abstract

“…The efficiency of thermal fatigue should even increase for bodies with low perihelion distances, i.e., experiencing intense temperature variations, and bodies composed of hydrated minerals, which may experience dehydration. Experiments were performed on meteorites using very high temperature variations to demonstrate the increased efficiency of thermal fatigue for low perihelion objects [154]. In these experiments, meteorites composed of hydrated minerals experienced dehydration, enhancing the cracking process.…”

Section: Thermal Effects On Asteroidsmentioning

confidence: 99%

Shapes, structures, and evolution of small bodies

Yun

Michel

2021

Astrodyn

Self Cite

View full text Add to dashboard Cite

Small bodies are among the best tracers of our Solar System's history. A large number of space missions to small bodies (past and future) offer a unique opportunity to use these bodies as a natural laboratory to study the different processes, mechanical structures, and responses that drive the origin and evolution of small bodies, which are connected to the origin, evolution, and current architecture of the Solar System. Images of small bodies sent by spacecraft have revealed unexpectedly rich and complex geological worlds.In addition to very diverse compositions, small bodies in the Solar System have highly diverse shapes and structures, which reflect both different evolutionary paths and material properties. Furthermore, each individual body has diverse geological features on its surface, which include craters of various sizes and depths, boulders of different sizes and morphologies, lineaments, fractures, pits, signatures of landslides, terraces, and ridges. Such a geological richness could not be detected via ground-based observations, and we are still at the beginning of understanding their significance on the low-gravity surfaces on which they manifest. The combination of space mission data and numerical modeling allows us to enrich our understanding of the origin, evolution, and physical properties of these fascinating bodies. For instance, starting from the shape models, bulk densities, and spin rates determined from space mission data, we can investigate the formation mechanisms that lead to the observed properties of small bodies. We can also infer the interior and mechanical properties (e.g., friction and cohesion) that allow a small body to be structurally stable, as well as its further potential evolution under processes such as a spin rate increase or an impact. Then, considering the various processes that these bodies experience during their evolution, we can investigate how these processes modify their properties and, in turn, how those properties influence the outcome of these processes. This paper reviews our current knowledge of small-body shapes and structures and discusses the various processes that are responsible for their formation and evolution, which can modify the characteristics of the bodies. We separately consider each population of small bodies, although in some cases, such as active asteroids and comets, the distinction between two populations solely in terms of physical properties is not clear. We then summarize the main findings regarding the physical properties of small bodies that have been the target of rendezvous or sample return missions.

show abstract

Network of thermal cracks in meteorites due to temperature variations: new experimental evidence and implications for asteroid surfaces

Cited by 16 publications

References 62 publications

Pebbles and sand on asteroid (162173) Ryugu: In situ observation and particles returned to Earth

Pebbles and sand on asteroid (162173) Ryugu: In situ observation and particles returned to Earth

Thermophysical Investigation of Asteroid Surfaces. II. Factors Influencing Grain Size

Shapes, structures, and evolution of small bodies

Contact Info

Product

Resources

About