Fact-checked by Grok 2 weeks ago

Rubble pile

A rubble pile is a type of celestial body, most commonly an asteroid, that consists of a loose aggregate of rock fragments, boulders, and debris of varying sizes, held together primarily by mutual gravitational attraction rather than by any significant material strength or cohesion.^[1] These structures form when a larger parent body is shattered by collisions or other disruptive events, allowing the resulting debris to re-accumulate under gravity into a porous, low-density object.^[2] Rubble piles typically exhibit high internal porosity, often ranging from 20% to 40% empty space, which contributes to their overall densities of around 1.2–2.0 g/cm³, much lower than solid rock.^[2]^[3] Key characteristics of rubble piles include their irregular shapes, often resembling spinning tops or peanuts due to rotational forces, and surfaces dominated by large boulders rather than fine regolith in some cases.^[3] Despite their fragile composition, these bodies are remarkably resilient to impacts; their porous nature allows them to absorb kinetic energy from collisions, dispersing it through the structure and limiting crater formation or complete disruption.^[3] This durability was demonstrated in NASA's DART mission in 2023, which successfully altered the orbit of the rubble pile asteroid Dimorphos by reshaping it without shattering it entirely.^[3] Prominent examples include the near-Earth asteroid (101955) Bennu, visited by NASA's OSIRIS-REx mission, which revealed a highly porous body formed from debris of a parent asteroid about 100 km wide, coalescing in mere weeks after a catastrophic breakup.^[2] Similarly, Japan's Hayabusa missions confirmed that (25143) Itokawa and (162173) Ryugu are rubble piles, with Itokawa showing up to 44% porosity and a structure akin to a loosely bound pile of gravel.^[4]^[3] These observations, supported by spacecraft imaging, radar data, and numerical modeling, indicate that a significant fraction—possibly the majority—of asteroids larger than a few hundred meters are rubble piles, providing insights into the collisional evolution of the solar system.^[5]

Definition and Characteristics

Definition

A rubble pile is a celestial body composed primarily of numerous loosely consolidated fragments of rock, dust, and ice, held together mainly by their mutual gravitational attraction rather than any significant intrinsic material strength or cohesion. These bodies exhibit substantial internal porosity and void spaces between their constituent particles, which are often irregularly shaped and range in size from fine grains to large boulders. The term "rubble pile" specifically applies to solar system objects typically in the diameter range of 200 meters to about 10 kilometers, where self-gravity dominates as the binding mechanism.^[6] In contrast to monolithic bodies, which are solid and cohesive structures with high tensile strength capable of withstanding significant stress without fracturing, rubble piles lack meaningful tensile strength and instead behave like granular aggregates. Under external stresses such as impacts or tidal forces, energy is absorbed through particle rearrangement and friction rather than being transmitted as tensile waves, making these bodies more resistant to complete disruption once initially shattered. This granular nature results in a low overall density, often 20-50% less than monolithic equivalents, emphasizing their aggregate composition over a unified solid form.^[6] The rubble pile conceptual model posits that many small solar system bodies represent re-accumulations of debris from the catastrophic collisions of larger parent bodies, forming gravitationally bound aggregates without requiring additional cementing agents. This hypothesis emerged in the 1970s as part of broader studies on collisional evolution in the asteroid belt, with the term "rubble pile" coined by Clark R. Chapman in 1978 to describe such strengthless, fractured collections resulting from high-speed impacts. The model underscores gravitational binding as the primary cohesion mechanism, distinguishing these objects from primordial, unfractured planetesimals.^[6]

Physical Properties

Rubble pile asteroids exhibit notably low bulk densities, typically ranging from 1.3 to 2.5 g/cm³, which is substantially lower than the grain densities of their constituent materials (around 2.7–3.3 g/cm³ for common meteorite analogs).^[7] This reduced density arises primarily from high internal porosity, often reaching 30–60% void space (including both macro- and microporosity), reflecting the loose aggregation of fragments rather than a monolithic structure.^[7]^[8] For instance, asteroid (162173) Ryugu has a bulk density of 1.19 g/cm³ corresponding to approximately 58% porosity, while (101955) Bennu has a bulk density of 1.19 g/cm³ with ~63% bulk porosity; sample returns from these missions (as of 2023 for Bennu) confirm ~40-50% microporosity in individual grains, enhancing the total void space.^[8]^[9]^[10] The internal structure of rubble piles is highly heterogeneous, comprising a mix of large boulders, smaller fragments, fines, and significant voids that create a non-uniform distribution of mass.^[11] This composition is often modeled as a granular medium, where inter-particle interactions are dominated by friction between larger components and limited cohesion, primarily from van der Waals forces acting on fine particles (typically <1 mm in size).^[12] These forces provide minimal tensile strength, on the order of 10–100 Pa, insufficient to prevent deformation under moderate stresses but adequate to maintain overall integrity in low-gravity environments.^[13] Such modeling highlights the pile's behavior as a collection of discrete elements rather than a cohesive solid, with voids contributing to the observed low densities.^[14] Surface features of rubble piles include thick layers of regolith—loose, unconsolidated debris covering boulders—that can reach depths of several meters, as seen on asteroids like Itokawa and Bennu.^[15] Craters on these bodies tend to form shallowly compared to those on rigid bodies, due to the lack of structural rigidity, which allows underlying material to flow and absorb impact energy without deep excavation.^[16] Additionally, evidence of seismic shaking from non-disruptive impacts is apparent in the redistribution of regolith, such as boulder movement and crater erasure, which homogenizes surface materials over time.^[17] A key physical limit for rubble piles is their rotational stability, governed by the "spin barrier" at approximately 2.2 hours for asteroids larger than about 150 meters in diameter.^[18] Beyond this period, centrifugal forces exceed gravitational binding and frictional cohesion, leading to equatorial shedding of material and potential disruption.^[19] This barrier distinguishes rubble piles from monolithic asteroids, which can rotate faster without breaking apart, and is evident in the period distributions of observed main-belt asteroids.^[20]

Formation and Stability

Formation Mechanisms

Rubble pile asteroids primarily form through collisional disruption, where hypervelocity impacts shatter larger monolithic parent bodies into fragments, which then reaccumulate under self-gravitation to create porous aggregates.^[6] These impacts, typically exceeding 1 km/s, exceed the critical specific shattering energy of the target, dispersing debris that gravitationally rebounds around the largest remnant, resulting in structures with 20–40% porosity.^[6] This process dominates for small asteroids (<10 km), transitioning from strength-dominated to gravity-dominated regimes around 300 m in size, as shown in numerical simulations.^[6] Another mechanism involves regolith accumulation from prolonged meteoroid bombardment, where repeated impacts and thermal cracking over billions of years fragment surface materials, building loose layers that can constitute entire bodies in low-gravity environments.^[21] Thermal fatigue from diurnal temperature cycles cracks boulders at rates up to 0.5 mm/year, more efficiently than micrometeorite impacts, producing grain sizes from millimeters to centimeters that accumulate without significant escape due to low escape velocities.^[21] For kilometer-sized bodies, this gradual buildup forms rubble piles entirely of regolith, with depths reaching meters.^[21] Primordial formation occurs during the early Solar System's planetesimal accretion phase, where gravitational instability in pebble swarms—concentrated via streaming instability—leads to the collapse of aerodynamically coupled dust and ice particles into porous aggregates rather than dense monoliths.^[22] In low-mass clouds (<20 km), inelastic bouncing collisions preserve pebble structures, yielding high-porosity pebble piles with densities around 0.5 g/cm³, while higher-mass clouds experience fragmentation that compacts material somewhat.^[22] This results in rubble-like bodies from the outset, contributing to the low densities and high porosities observed in many small Solar System objects.^[22] Some models attribute the formation of many main-belt rubble piles to collisional events during the proposed Late Heavy Bombardment, approximately 4.1–3.8 billion years ago, though the hypothesis remains under debate as of 2024; during this period, dynamical instabilities are thought to have excited impact rates, shattering parent bodies and enabling widespread reaccumulation.^[23] This period followed initial planetesimal formation within the first 5 million years of Solar System history and is proposed to have depleted the asteroid belt while producing numerous fragments that reassembled into rubble piles.^[24]

Structural Stability

Rubble pile asteroids maintain structural stability primarily through their self-gravitational binding energy, which must exceed disruptive forces from rotation, impacts, or tidal interactions to prevent disassembly. For cohesionless aggregates composed of loose granular material, this binding energy ensures cohesion only above a critical size threshold of approximately 10–100 meters, below which small but finite cohesive forces, such as van der Waals attractions between regolith grains, are required to counteract disruptive effects and provide relative tensile strength that increases with decreasing body size.^[25] Stability analyses using energy criteria, such as extensions of the Lagrange-Dirichlet theorem for non-smooth granular materials, confirm that rubble piles remain bound when the second-order variation in kinetic energy from perturbations is negative, balancing internal gravitational stresses against external perturbations like centrifugal forces. The YORP (Yarkovsky-O'Keefe-Radzievskii-Paddack) effect contributes to instability by exerting thermal radiation torque that gradually increases the rotation rate of rubble pile asteroids, potentially leading to surface mass shedding or complete fission. This spin-up process operates over timescales of $10^6 to $10^8 years for kilometer-sized bodies in the main belt and near-Earth populations, with outcomes depending on the internal friction angle: higher angles (around 40°) allow reshaping into stable oblate forms before shedding, while lower angles result in more elongated shapes prone to extensive material loss without satellite formation.^[26] Such rotational disruption highlights the tenuous nature of rubble piles, where low tensile strength and high porosity—enabling granular flow—facilitate reconfiguration rather than rigid failure. Rubble piles demonstrate remarkable resilience to hypervelocity impacts, absorbing kinetic energy through inelastic granular flow within their porous structure, which dissipates shocks by rearranging constituent boulders and regolith instead of propagating fractures as in monolithic bodies. Simulations of impacts, informed by the NASA's DART mission outcomes, show that higher boulder packing fractions (≥40 vol%) enhance this resilience, with bodies retaining over 94% of their mass post-impact and reforming via self-gravity, in contrast to lower-packing configurations that undergo near-catastrophic fragmentation at specific energies around 100–1000 J/kg. Post-impact observations from the DART mission (2022), analyzed as of 2024, showed Dimorphos ejected approximately 1.3–2.2 × 10^7 kg of material (about 0.5% of its mass), with boulders comprising ∼0.1%, confirming the structure's ability to retain nearly all mass through reconfiguration.^[27]^[28] A key mathematical framework for assessing rotational stability adapts the Roche limit concept to self-gravitating granular aggregates, evaluating when tidal or spin-induced forces overcome the body's filling factor and internal cohesion. The critical spin parameter is given by

\Gamma = \frac{\omega^2 r^3}{GM} \approx 0.3,

where \omega is the angular velocity, r the equatorial radius, G the gravitational constant, and M the mass; values exceeding this threshold indicate impending disruption as centrifugal acceleration surpasses self-gravitational binding, with granular friction and cohesion modifying the exact limit for rubble piles.

Examples in the Solar System

Asteroids

Rubble pile structures are inferred to characterize nearly all asteroids in the main asteroid belt with diameters between approximately 200 meters and 10 kilometers, based on a combination of low bulk densities measured by spacecraft missions, high macroporosities exceeding 30–40%, and the absence of large monolithic bodies in this size range. These inferences arise from direct observations of over a dozen asteroids visited by spacecraft, such as the Galileo, NEAR Shoemaker, and Hayabusa missions, which revealed densities significantly lower than those of solid rock (typically 2.7–3.3 g/cm³ for silicate materials), implying loosely bound aggregates held together primarily by mutual gravity. For instance, density estimates from satellite discoveries and shape modeling consistently indicate that these bodies possess substantial internal void spaces, supporting the rubble pile model as the dominant form for mid-sized asteroids.^[29]^[30] Observational evidence for rubble pile configurations in asteroids includes spacecraft imagery showing boulder-strewn surfaces and "top-shaped" morphologies, which are attributed to rotational reshaping where centrifugal forces migrate material toward the equator, forming prominent ridges in loosely consolidated bodies. Radar and lightcurve analyses further reveal non-principal axis rotation—tumbling motion—in several asteroids, a phenomenon facilitated by the weak internal cohesion of rubble piles, as rigid monoliths would stabilize into principal axis rotation. These top-shaped forms, observed in objects like Bennu and Ryugu, result from YORP-induced spin-up, where increased rotation rates cause surface deformation without disrupting the overall aggregate. Ryugu exhibits a bulk density of 1.19 g/cm³ and porosity around 50%, as determined by Japan's Hayabusa2 mission in 2019, confirming its rubble pile structure with a diamond-shaped form and boulder-covered surface.^[31]^[32] A prominent example is the near-Earth asteroid 25143 Itokawa, visited by Japan's Hayabusa spacecraft in 2005, which displayed a boulder-dominated surface described as a "sea of boulders" interspersed with fine regolith, and a bulk density of 1.9 ± 0.13 g/cm³ indicating about 40% porosity consistent with a rubble pile. Hayabusa's sample return in 2010 confirmed the composition as primitive LL chondritic material, with particles showing evidence of space weathering and minimal alteration, reinforcing the reaccumulation origin from collisional debris. Similarly, asteroid 101955 Bennu, the target of NASA's OSIRIS-REx mission, exhibits a spinning-top shape with a pronounced equatorial ridge formed by spin-up deformation, and a low density of approximately 1.26 g/cm³, highlighting its rubble pile nature through global boulder coverage and particle ejection events observed during the 2018–2019 encounter. Another notable example is Dimorphos, the satellite of near-Earth asteroid Didymos, confirmed as a rubble pile by NASA's DART mission in 2022, which demonstrated its resilience by reshaping rather than shattering upon kinetic impact.^[33]

Comets

Comets exhibit rubble pile characteristics distinct from their asteroid counterparts due to their volatile-rich composition, which drives dynamic surface activity. Often termed "dirty snowballs," comet nuclei are aggregates of water ice, frozen carbon dioxide, ammonia, and other volatiles mixed with dust and rocky particles, forming loosely bound icy rubble piles with low bulk densities typically around 0.5–0.6 g/cm³. For instance, the nucleus of Comet 67P/Churyumov-Gerasimenko has a measured bulk density of 0.533 ± 0.006 g/cm³, reflecting its highly porous, granular structure composed of centimeter- to meter-sized building blocks. Direct evidence for the rubble pile nature of comets comes from spacecraft missions, particularly the European Space Agency's Rosetta mission to Comet 67P, which operated from 2014 to 2016. Rosetta's observations revealed a bilobed shape resembling two distinct rubble piles that merged early in the Solar System's history, connected by a narrow neck, with overall porosity estimated at 50–85% and no evidence of a monolithic core.^[34] The comet's interior appears homogeneous on large scales but consists of primordial, unprocessed aggregates, supporting models of gentle accretion rather than violent collisions.^[35] The activity of comets further underscores their rubble pile configuration, as solar heating induces sublimation of ices, producing gas jets and outbursts that erode the low-tensile-strength material over time. This process explains the irregular, non-spherical shapes and surface features like pits and cliffs, with tensile strengths as low as 1–10 Pa allowing easy fragmentation and mass loss.^[36] The rubble pile model accounts for how gravitational cohesion holds these volatile structures together despite repeated perihelion passages.^[34] A notable demonstration of this granular, low-strength interior occurred during NASA's Deep Impact mission in 2005, which targeted Comet 9P/Tempel 1. The impactor's collision excavated a shallow crater filled with fine, loose particles (1–100 micrometers in size) rather than forming a deep excavation, confirming the comet's outer layers behave as a cohesive but easily disrupted granular aggregate.^[37]

Moons

Rubble pile moons are predominantly found among the irregular satellites of the outer planets, characterized by their distant, eccentric, and highly inclined orbits relative to the planetary equators. These moons, such as Saturn's Phoebe, exhibit physical properties consistent with loosely bound aggregates of rock and ice fragments rather than monolithic or differentiated bodies. Observations from spacecraft flybys have revealed surfaces marked by heavy cratering and low albedos, suggesting a history of collisional disruption and reaccumulation. For instance, Phoebe displays a heavily cratered, reddish surface with a mean density of approximately 1.6 g/cm³, indicating a porous structure composed of roughly equal parts water ice and silicates covered by a thin layer of dark, organic-rich material.^[38]^[39]^[40] The formation of these irregular moons is attributed to dynamical capture of asteroids or Kuiper Belt objects, or to the reaccumulation of debris from giant impacts involving larger progenitors. Phoebe, for example, is widely regarded as a captured body from the outer Solar System, its retrograde orbit and compositional similarities to Kuiper Belt objects supporting this origin. Similarly, Puck, an inner moon of Uranus imaged by Voyager 2 in 1986, exhibits an irregular, potato-like shape and a low albedo of about 0.11, consistent with a rubble pile reassembled from impact fragments. Jupiter's Himalia, the largest irregular moon at around 140 km in diameter, further exemplifies this, as lightcurve observations indicate an elongated form with a rotation period of 7.78 hours and amplitude of 0.20 magnitudes, implying a non-rigid, aggregate structure unable to maintain a spherical equilibrium.^[41]^[42]^[43]^[44] Supporting evidence for their rubble pile nature includes low bulk densities and high inferred porosities, often estimated through mutual occultations, eclipses, or gravitational perturbations during close approaches. Many irregular moons have densities below 1.5 g/cm³, with porosities exceeding 50% in some cases, far lower than expected for compact icy or rocky bodies, pointing to internal voids within loose aggregates. The absence of significant geological activity, such as cryovolcanism or resurfacing, further aligns with these moons being cohesion-poor collections of debris, as tidal or rotational stresses would disrupt more rigid structures over billions of years. This collisional re-accumulation process, briefly, mirrors mechanisms seen in asteroid families, where fragments coalesce without full lithification.^[45]^[46]^[47]

Scientific Importance

Detection Methods

Detection of rubble pile asteroids relies on a combination of remote sensing techniques and in-situ spacecraft observations, which reveal characteristic low bulk densities, irregular shapes, and surface properties indicative of loosely bound aggregates. These methods identify rubble piles through signatures such as bulk densities below 2.5 g/cm³, often implying high macroporosity of 30-50%, as opposed to monolithic bodies. Remote sensing via radar ranging, particularly from facilities like the former Arecibo Observatory, has been instrumental in determining asteroid shapes and densities by measuring echo delays and Doppler shifts, achieving resolutions down to 7.5 meters. Observations of near-Earth asteroids, such as the bilobed structure of (216) Kleopatra observed in 2000, demonstrated contact-binary forms consistent with rubble pile configurations held together primarily by gravity.^[48] Lightcurve inversion techniques further detect non-principal axis rotation, or tumbling, which is common in rubble piles due to their low internal cohesion; analysis of photometric data from multiple apparitions allows reconstruction of irregular shapes and spin states, as applied to over 100 asteroids showing periods longer than expected for principal axis rotation. Spectroscopic indicators from near-infrared observations highlight hydrated minerals and low reflectance (albedo ~0.04-0.05), suggestive of porous regolith rich in carbonaceous materials and phyllosilicates, as seen in spectra of C-type asteroids. Thermophysical modeling of the Yarkovsky-O'Keefe-Radzievskii-Paddack (YORP) effect, which causes spin-up through asymmetric thermal re-radiation, provides evidence for rubble pile structure; simulations show that such bodies respond to torque by reshaping or shedding material when rotation rates approach the disruption limit, with detections on asteroids like (101955) Bennu confirming this behavior. Ground-based techniques, including mutual occultation events in binary systems, yield precise sizes and densities; for instance, observations of (90) Antiope's components during eclipses and occultations in 2007 determined a bulk density of 1.3 ± 0.1 g/cm³, indicating a rubble pile with ~50% porosity.^[49] Spacecraft missions enable in-situ analysis, such as the OSIRIS-REx mission's use of the OSIRIS-REx Laser Altimeter (OLA) from 2018-2020 to map Bennu's surface roughness (root-mean-square slope of 43°) and detect voids in the subsurface regolith, supporting a near-zero cohesion rubble pile model with packing density below 50%. Recent advancements with the James Webb Space Telescope (JWST), operational since 2022, utilize mid-infrared thermal imaging via the Mid-Infrared Instrument (MIRI) to estimate sizes and albedos of small bodies, enhancing detection of faint thermal emissions from rubble pile candidates in the main belt.^[50]^[51]

Implications for Solar System Evolution

Rubble pile asteroids serve as primordial records of the early solar system's violent collisional environment, where widespread impacts approximately 4.5 billion years ago fragmented larger planetesimals into loose aggregates that self-assembled under gravity. Analysis of regolith particles from asteroid 25143 Itokawa, returned by the Hayabusa mission, reveals formation ages exceeding 4.2 billion years, indicating that these structures have endured since the solar system's infancy due to their shock-absorbent porosity, which allows survival for up to an order of magnitude longer than monolithic bodies.^[52] This longevity implies that rubble piles dominate the present-day asteroid population, preserving evidence of the collisional grinding that shaped the main belt and supplied materials for planetary accretion.^[52] Cometary rubble piles, such as those in Jupiter-family comets like 81P/Wild 2, are implicated in the delivery of volatiles to Earth, including water and organic compounds, with isotopic compositions that align with terrestrial oceans. Samples collected by NASA's Stardust mission in 2006 from Wild 2's coma revealed primitive organics and silicates with deuterium-to-hydrogen (D/H) ratios elevated but comparable to those in interplanetary dust particles (IDPs) and certain carbonaceous chondrites, supporting the hypothesis that such cometary debris contributed to Earth's hydrosphere during the Late Heavy Bombardment.^[53] The oxygen isotopic signatures in Wild 2 materials further match those in primitive carbonaceous chondrites, reinforcing the role of rubble pile comets in volatile transfer from the outer solar system inward.^[54] The rubble pile structure of near-Earth asteroids profoundly influences planetary defense strategies, as their low cohesive strength leads to reshaping rather than catastrophic breakup upon kinetic impact. NASA's DART mission in 2022 demonstrated this by impacting Dimorphos, the moon of asteroid Didymos, resulting in a momentum enhancement factor (β) of approximately 3.6, where ejecta plumes amplified deflection while the body underwent global deformation without fragmenting.^[55] This behavior underscores the need for tailored mitigation approaches, such as enhanced kinetic impacts to exploit ejecta for orbital alteration, rather than relying on disruption for monolithic targets.^[55] Ongoing rotational evolution driven by the YORP effect is expected to induce fission in cohesive rubble pile asteroids, potentially populating debris disks and increasing the fraction of disrupted small bodies among near-Earth objects (NEOs). Models indicate that even modest cohesion (tens of pascals) combined with YORP spin-up causes repeated disaggregation over millions of years, leading to the formation of binary systems or swarms that contribute significantly to the NEO population.^[56] Simulations predict that 10–20% of NEOs could exhibit signs of recent YORP-driven disruption by the 22nd century, highlighting the dynamic reshaping of small body populations in the inner solar system.^[57]

References

[1]
Evidence for Rubble Pile Asteroids - SwRI Boulder Office
A ``rubble pile'' asteroid is defined as a weak aggregate of large and small components held together by gravity rather than material strength. Thus, calling ...Missing: characteristics | Show results with:characteristics
[2]
Ten Things to Know About Bennu - NASA
Oct 16, 2020 · Rubble-pile asteroids like Bennu are celestial bodies made from lots of pieces of rocky debris that gravity compressed together. This kind of ...
[3]
The rocky lives of cosmic rubble piles - Physics Today
Mar 16, 2023 · For all their fragility, rubble-pile asteroids are surprisingly durable. Their abundant pore space ensures that the energy from an impacting ...Missing: characteristics | Show results with:characteristics
[4]
25143 Itokawa - NASA Science
Nov 3, 2024 · Scientists think Itokawa is not solid, but rather is a rubble pile, an agglomeration of rocks loosely held together by their mutual gravity. Few ...
[5]
[PDF] Gravitational Aggregates: Evidence and Evolution
Nearly three decades later,. Chapman (1978) used the term “rubble pile” to describe a gravitationally bound collection of boulders, arguing that high-speed ...<|control11|><|separator|>
[6]
(PDF) Asteroid Density, Porosity, and Structure - ResearchGate
Most asteroids appear to have bulk densities that are well below the grain density of their likely meteorite analogs. This indicates that many asteroids have ...
[7]
Macroporosity and Grain Density of Rubble Pile Asteroid (162173 ...
Nov 2, 2020 · The bulk porosity inside rubble pile asteroids can be separated into two contributions: the first one stems from the intrinsic porosity of ...
[8]
Mechanical properties of rubble pile asteroids (Dimorphos, Itokawa ...
Jul 30, 2024 · Here we perform a detailed morphological analysis of the surface boulders on Dimorphos using images, the primary data set available from the DART mission.
[9]
Heterogeneous mass distribution of the rubble-pile asteroid (101955 ...
Oct 8, 2020 · Similarly, the central core will have a radius of 108 to 245 m, for a region of no density to one that has 95% of the bulk density, respectively ...
[10]
The strength of regolith and rubble pile asteroids - Wiley Online Library
May 13, 2014 · We explore the hypothesis that, due to small van der Waals forces between constituent grains, small rubble pile asteroids have a small but nonzero cohesive ...
[11]
[1306.1622] The Strength of Regolith and Rubble Pile Asteroids - arXiv
Jun 7, 2013 · We explore the hypothesis that, due to small van der Waals forces between constituent grains, small rubble pile asteroids have a small but non-zero cohesive ...
[12]
Dynamical modelling of rubble pile asteroids using data-driven ...
Then, the other parameters considered are the bulk density ρ = [1200.0,1400.0,1600.0,1800.0,2000.0] kg/m3 and initial rotational period P0 = [2.5,3.5,5.8] hours ...
[13]
Numerical simulations suggest asteroids (101955) Bennu and ...
Jul 5, 2024 · Rubble pile asteroids are widely understood to be composed of reaccumulated debris following a catastrophic collision between asteroids in ...
[14]
Shape of (101955) Bennu indicative of a rubble pile with internal ...
Oct 1, 2019 · Nevertheless, Bennu's shape and surface features imply that the asteroid has some structural rigidity, despite being a rubble pile. Evidence for ...
[15]
Segregation on small rubble bodies due to impact-induced seismic ...
Jun 19, 2024 · We present a framework to study regolith segregation on rubble-pile asteroids—self-gravitating granular aggregates—due to seismic shaking ...
[16]
The Spin-Barrier Ratio for S and C-Type Main Asteroids Belt - arXiv
Mar 28, 2019 · Asteroids of size larger than 0.15 km generally do not have periods P smaller than about 2.2 hours, a limit known as cohesionless spin-barrier.
[17]
The spin-barrier ratio for S and C-type main asteroids belt
Nov 1, 2017 · Asteroids of size larger than 0.15 km generally do not have periods P smaller than about 2.2 h, a limit known as cohesionless spin-barrier.
[18]
ASTEROID SPIN-RATE STUDY USING THE INTERMEDIATE ...
The 2.2 hr spin barrier can clearly be seen for objects with D > 150 m, which indicates the spin-rate limit for rubble-pile asteroids under self-gravity. A ...
[19]
[PDF] Origin and Nature of Regolith on Minor Bodies
There is clear evidence of regolith motion and migration on asteroid surfaces, possibly due to seismic shaking induced by non-disruptive impacts and maybe ...<|separator|>
[20]
Formation of pebble-pile planetesimals - Astronomy & Astrophysics
An advantage with gravitational instability is that, if the internal angular momentum of a gravitationally unstable pebble cloud is large, it naturally forms a ...
[21]
[PDF] The Late Heavy Bombardment - SwRI Boulder Office
Jul 19, 2017 · Such velocities seldom occur when main belt asteroids strike one another, which probably explains the paucity of shocked rocks and impact ...
[22]
None
### Summary of Timescales for Formation of Main-Belt Asteroids and Relation to Late Heavy Bombardment
[23]
https://www.annualreviews.org/doi/10.1146/annurev-earth-063016-020131
[24]
https://www2.boulder.swri.edu/~bottke/Reprints/Bottke_Norman_2017_AnnuRev-Earth-Planet_45_619_Late_Heavy_Bombardment.pdf
[25]
https://doi.org/10.1111/maps.12293
[26]
https://doi.org/10.1016/j.icarus.2012.04.029
[27]
Hayabusa2 arrives at the carbonaceous asteroid 162173 Ryugu—A ...
Mar 19, 2019 · Watanabe et al. measured the asteroid's mass, shape, and density, showing that it is a “rubble pile” of loose rocks, formed into a spinning-top ...<|control11|><|separator|>
[28]
The primordial nucleus of comet 67P/Churyumov-Gerasimenko
The mass of 67P determined by Rosetta/RSI is 9.982( ± 0.003) × 1012 kg (Pätzold et al. 2016). This illustrates the accuracy of NGF modeling when the comet spin ...
[29]
Comet 67P/Churyumov–Gerasimenko preserved the pebbles that ...
Sep 12, 2016 · We find that the pebbles have a microporosity of (52 ± 8) per cent (internal volume filling factor ϕP = 0.48 ± 0.08), implying an average ...
[30]
Tensile strength of 67P/Churyumov–Gerasimenko nucleus material ...
Low strengths support the conclusion that comets are primordial rubble piles ... low strengths mean that material is easily eroded by sublimation, gas ...
[31]
Science | AAAS
Insufficient relevant content. The provided URL (https://www.science.org/doi/10.1126/science.1121127) leads to a "Page not found" error, offering no access to the Deep Impact paper or its details on excavation, loose material, deep cratering, or the granular nature of Tempel 1. The page only contains a generic error message and links to the homepage or search functionality.
[32]
Saturn's moon mystery solved : Nature News
Jun 25, 2004 · Putting these two vital statistics together provided the moon's density, which is about 1.6 g cm-3. Water ice has a density of only 0.93 g cm-3, ...
[33]
Cassini-Huygens looks at Phoebe's distant past - ESA
Images collected during the Cassini-Huygens close fly-by of Saturn's moon Phoebe give strong evidence that the tiny moon may be rich in ice and covered by a ...
[34]
Geophysical evolution of Saturn's satellite Phoebe, a large ...
We review the physical and spectral observations obtained during the Cassini–Huygens flyby performed in June 2004. We discuss the information contained in these ...
[35]
Saturn's moon Phoebe as a captured body from the outer Solar ...
Aug 9, 2025 · The orbital properties of Phoebe, one of Saturn's irregular moons, suggest that it was captured by the ringed planet's gravitational field ...
[36]
THE IRREGULAR SATELLITES: THE MOST COLLISIONALLY ...
Feb 2, 2010 · Recent modeling work indicates that they may have been dynamically captured during a violent reshuffling event of the giant planets ∼3.9 billion ...
[37]
https://www.science.org/doi/10.1126/science.1121127
[38]
Photometric lightcurve and rotation period of Himalia (Jupiter VI) - ADS
The combined data set yields for Himalia a unique synodic rotation period of 7.7819 ± 0.0005 h, with a lightcurve amplitude of 0.20 ± 0.01 magnitudes. This ...Missing: moon rubble pile evidence
[39]
[PDF] The Irregular Satellites of Saturn - University of Maryland
bulk density than the “cometary” irregulars, even if they are entirely rubble piles. Consequently, the spin barrier for these potential “Phoebe-debris moons” ...
[40]
Geophysical evidence that Saturn's Moon Phoebe originated from a ...
The density of another irregular satellite, Jupiter's moon Himalia was inferred to be also about 1.63 g cm−3, assuming a mean radius of ∼85 km (Cruikshank ...
[41]
[PDF] The Irregular Satellites: The Most Collisionally Evolved Populations ...
May 28, 2009 · The irregular satellites, on the other hand, were captured into a relatively tiny region of space with short orbital periods. This makes ...
[42]
New determination of the size and bulk density of the binary Asteroid ...
This translates into a bulk density of 3.6 ± 0.4 g/cm3, which implies a macroscopic porosity for Kleopatra of ∼30–50%, typical of a rubble-pile asteroid.
[43]
Near-zero cohesion and loose packing of Bennu's near subsurface ...
Jul 7, 2022 · The low gravity of a small rubble-pile asteroid such as Bennu effectively weakens its near subsurface by not compressing the upper layers, ...Missing: LIDAR | Show results with:LIDAR
[44]
Asteroids seen by JWST-MIRI: Radiometric size, distance, and orbit ...
With JWST-MIRI observations the situation will change and many unknown, often very small, solar system objects will be detected. Later orbit determinations are ...
[45]
Rubble pile asteroids are forever - PNAS
Jan 23, 2023 · Rubble piles asteroids consist of reassembled fragments from shattered monolithic asteroids and are much more abundant than previously thought ...
[46]
[PDF] Organics Captured from Comet Wild 2 by the Stardust Spacecraft
The elevated D/H ratios are comparable to those of many IDPs and meteoritic samples, although none of the cometary samples examined to date have shown ratios as ...
[47]
Oxygen in Comets and Interplanetary Dust Particles
Mar 3, 2017 · Comets are also of considerable interest since they may have delivered volatiles, like H2O, to the early cooling Earth, thereby playing a key ...
[48]
Momentum transfer from the DART mission kinetic impact ... - Nature
Mar 1, 2023 · Therefore, the DART kinetic impact was highly effective in deflecting the asteroid Dimorphos.
[49]
[PDF] Disaggregation of Small, Cohesive Rubble Pile Asteroids ... - arXiv
Jun 11, 2017 · When their spin rates become large enough YORP causes rubble pile asteroids to deform (hence the genesis of the spin deformation limit) and to ...
[50]
Disaggregation of small, cohesive rubble pile asteroids due to YORP
It is shown that small levels of cohesion within a rubble pile asteroid will, when combined with the YORP effect, cause rubble pile asteroids to disaggregate.