Effect of target properties and impact velocity on ejection dynamics and ejecta deposition

Luther, R.; Zhu, M. H.; Collins, G. S.; Wünnemann, K.

doi:10.1111/maps.13143

Cited by 38 publications

(75 citation statements)

References 61 publications

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“…, ) comparable to funneled craters in highly porous snow (Luther et al. , Forthcoming). Saturation of pore space with water at 50 and 90%, respectively, set off the effects of porosity, with crater size increasing with progressive saturation of target pore space (Dufresne et al.…”

Section: Crater Morphologies and Cratering Efficienciesmentioning

confidence: 82%

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Experimental impact cratering: A summary of the major results of the MEMIN research unit

Kenkmann

Deutsch

Thoma

et al. 2018

Meteorit & Planetary Scien

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This paper reviews major findings of the Multidisciplinary Experimental and Modeling Impact Crater Research Network (MEMIN). MEMIN is a consortium, funded from 2009 till 2017 by the German Research Foundation, and is aimed at investigating impact cratering processes by experimental and modeling approaches. The vision of this network has been to comprehensively quantify impact processes by conducting a strictly controlled experimental campaign at the laboratory scale, together with a multidisciplinary analytical approach. Central to MEMIN has been the use of powerful two‐stage light‐gas accelerators capable of producing impact craters in the decimeter size range in solid rocks that allowed detailed spatial analyses of petrophysical, structural, and geochemical changes in target rocks and ejecta. In addition, explosive setups, membrane‐driven diamond anvil cells, as well as laser irradiation and split Hopkinson pressure bar technologies have been used to study the response of minerals and rocks to shock and dynamic loading as well as high‐temperature conditions. We used Seeberger sandstone, Taunus quartzite, Carrara marble, and Weibern tuff as major target rock types. In concert with the experiments we conducted mesoscale numerical simulations of shock wave propagation in heterogeneous rocks resolving the complex response of grains and pores to compressive, shear, and tensile loading and macroscale modeling of crater formation and fracturing. Major results comprise (1) projectile–target interaction, (2) various aspects of shock metamorphism with special focus on low shock pressures and effects of target porosity and water saturation, (3) crater morphologies and cratering efficiencies in various nonporous and porous lithologies, (4) in situ target damage, (5) ejecta dynamics, and (6) geophysical survey of experimental craters.

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Section: Crater Morphologies and Cratering Efficienciesmentioning

confidence: 82%

“…Complementary numerical modeling of the ejection process shows that the ejection angle and velocity depend on porosity, friction, and cohesion (Luther et al. ). Increasing the coefficient of friction and the porosity of the target material leads to a decrease of ejection velocities and the formation of smaller craters.…”

Section: Ejecta Dynamicsmentioning

confidence: 99%

Experimental impact cratering: A summary of the major results of the MEMIN research unit

Kenkmann

Deutsch

Thoma

et al. 2018

Meteorit & Planetary Scien

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“…For example, for ejecta a with a launch velocity of V , we calculate its normal velocity ( V r ) and tangent velocity ( V t ), from which the launch angle is estimated to be θ = atan ( V r / V t ; see Figure a). This method has been used previously in several modeling studies on the ejecta distribution (e.g., Luther et al, ; Wünnemann et al, ). Although the ejecta behave more as a continuous flow with partly fluidized melt, they move along parabolic trajectories and land on the lunar surface with approximately the same velocity as launched.…”

Section: Ejecta and Crustal Thickness Calculation Of Giant Impact Eventmentioning

confidence: 99%

Are the Moon's Nearside‐Farside Asymmetries the Result of a Giant Impact?

et al. 2019

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The Moon exhibits striking geological asymmetries in elevation, crustal thickness, and composition between its nearside and farside. Although several scenarios have been proposed to explain these asymmetries, their origin remains debated. Recent remote sensing observations suggest that (1) the crust on the farside highlands consists of two layers: a primary anorthositic layer with thickness of ~30‐50 km and on top a more mafic‐rich layer ~10 km thick and (2) the nearside exhibits a large area of low‐Ca pyroxene that has been interpreted to have an impact origin. These observations support the idea that the lunar nearside‐farside asymmetries may be the result of a giant impact. Here using quantitative numerical modeling, we test the hypothesis that a giant impact on the early Moon can explain the striking differences in elevation, crustal thickness, and composition between the nearside and farside of the Moon. We find that a large impactor, impacting the current nearside with a low velocity, can form a mega‐basin and reproduce the characteristics of the crustal asymmetry and structures comparable to those observed on the current Moon, including the nearside lowlands and the farside's mafic‐rich layer on top of a primordial anorthositic crust. Our model shows that the excavated deep‐seated KREEP (potassium, rare earth elements, and phosphorus) material, deposited close to the basin rim, slumps back into the basin and covers the entire basin floor; subsequent large impacts can transport the shallow KREEP material to the surface, resulting in its observed distribution. In addition, our model suggests that prior to the asymmetry‐forming impact, the Moon may have had an 182W anomaly compared to the immediate post‐giant impact Earth's mantle, as predicted if the Moon was created through a giant collision with the proto‐Earth.

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“…During the excavation stage of crater formation, a large amount of material is ejected ballistically out of the crater as ejecta (Oberbeck, 1975;Housen et al, 1983). Previous laboratory (Housen and Holsapple, 2011) and numerical studies (Jutzi and Michel, 2014;Luther et al, 2018;Raducan et al, 2019) of impact events into homogeneous targets have shown that the speed and mass of ejecta depends sensitively on target material properties, such as cohesive strength, porosity and the coefficient of internal friction. However, most bodies in the Solar System are not homogeneous, as shown by past missions to asteroids, such as the NEAR-Shoemaker (Veverka et al, 2001), the OSIRIS-REx (Lauretta et al, 2019;Walsh et al, 2012) or the Hayabusa missions (Yano et al, 2006;Watanabe et al, 2019), as well as Earth-based thermal infrared observations (Delbo et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

The effects of asteroid layering on ejecta mass-velocity distribution and implications for impact momentum transfer

Raducan

Davison

Collins

2020

Planetary and Space Science

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Most bodies in the Solar System do not have a homogeneous structure. Understanding the outcome of an impact into regolith layers of different properties is especially important for NASA's Double Asteroid Redirection Test (DART) and ESA's Hera missions. Here we used the iSALE shock physics code to simulate the DART impact into three different target scenarios in the strength regime: a homogeneous porous half-space; layered targets with a porous weak layer overlying a stronger bedrock; and targets with exponentially decreasing porosity with depth. For each scenario we determined the sensitivity of crater morphology, ejecta mass-velocity distribution and momentum transferred from the impact for deflection, β −1, to target properties and structure. We found that for the homogeneous porous half-space, cohesion and porosity play a significant role and the DART impact is expected to produce a β − 1 between 1 and 3. In the two-layer target scenario, the

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Effect of target properties and impact velocity on ejection dynamics and ejecta deposition

Cited by 38 publications

References 61 publications

Experimental impact cratering: A summary of the major results of the MEMIN research unit

Experimental impact cratering: A summary of the major results of the MEMIN research unit

Are the Moon's Nearside‐Farside Asymmetries the Result of a Giant Impact?

The effects of asteroid layering on ejecta mass-velocity distribution and implications for impact momentum transfer

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