Variation in Magnetic Fabrics at Low Shock Pressure Due to Experimental Impact Cratering

Agarwal, Amar; Kontny, Agnes; Kenkmann, T.; Poelchau, M. H.

doi:10.1029/2018jb017128

Cited by 9 publications

(12 citation statements)

References 61 publications

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“…On the other hand, present observations agree with the trends in cratering experiments. Here experimental shock pressure (< 3 GPa) increases the bulk magnetic susceptibility of rocks with small magnetite grains, < 10 µm (Agarwal et al 2019). Although the mechanism behind this increase is not known, their results agree well with the present observations.…”

Section: Variation In Bulk Magnetic Susceptibilitysupporting

confidence: 90%

“…Until now, the shock demagnetization of magnetic minerals such as magnetite, Ti-magnetite, hematite, Ti-hematite, and pyrrhotite (see Louzada et al 2011 and the references therein) was the only effect of low shock pressures (< 3 GPa), which was considered of importance at a regional scale. However, now, increase in magnetic susceptibility of Ti-magnetite, at low shock pressures, is clear from present investigations Table 1 Table compiles the on naturally shocked target basalts at Lonar impact structure, and from experiments (Agarwal et al 2019).…”

Section: Discussionmentioning

confidence: 51%

“…As most of the target rocks in the crater subsurface are generally weakly shocked, < 3 GPa (Pierazzo and Melosh 2000;Kenkmann et al 2014), such an increase in magnetic susceptibility will affect the induced magnetization, thus, changing the magnetic anomalies at these impact structures. While there are no other studies on the T C of weakly shocked rocks, there is only one study on magnetic susceptibility, which shows its increase with shock pressures below 3 GPa, without commenting on the mechanism (e.g., Agarwal et al 2019). Changes in the crystal lattice, such as straining of (311) peak, decrease in apparent crystallite size, and grain fragmentation may be among the possible reasons for one of the observed trends in T C and magnetic susceptibility.…”

Section: Discussionmentioning

confidence: 99%

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Curie temperature of weakly shocked target basalts at the Lonar impact crater, India

Agarwal

Alva‐Valdivia

2019

Earth Planets Space

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The study investigates Curie temperature (T C), bulk magnetic susceptibility, hysteresis, and X-ray diffraction pattern of in situ target basalts of Lonar impact crater, India. The main magnetic phase in the target basalt is low-Ti titanomagnetite. This study reveals an increase in T C and decrease in magnetic susceptibility and in full width at half maxima of the 311 peaks of titanomagnetite with distance from the crater center. Changes in crystal lattice of titanomagnetite, such as straining of 311 peaks, decrease in apparent crystallite size, and grain fragmentation may be among the possible reasons for the observed trends in T C and magnetic susceptibility. However, they both do not show any correlation between each other, indicating that different shock-induced processes affect them.

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Section: Variation In Bulk Magnetic Susceptibilitysupporting

confidence: 90%

Section: Discussionmentioning

confidence: 51%

Section: Discussionmentioning

confidence: 99%

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Curie temperature of weakly shocked target basalts at the Lonar impact crater, India

Agarwal

Alva‐Valdivia

2019

Earth Planets Space

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“…In agreement to the reorientation of the magnetic fabrics, the Vertical Profile of A38 shows intense straining, which is lower on either side, in the Left and Right Oblique Profiles of A38. Agarwal et al (2019) show that in A37 (horizontal foliation) the reorientation of the magnetic fabrics is less below the crater, but more at the sides. A similar trend is seen in the present study.…”

Section: Control Of the Foliation On The Compressive Strainmentioning

confidence: 88%

Impact Experiment on Gneiss: The Effects of Foliation on Cratering Process

et al. 2019

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Two impact experiments were carried out on blocks of Maggia gneiss to assess the influence of mechanical target anisotropies on the cratering process. The experiments were done within the framework of Multidisciplinary Experimental and Modeling Impact Research Network. In one experiment the metamorphic foliation was vertical, that is, oriented perpendicular to the target surface, and in the other horizontal, that is, parallel to the target surface. This study reveals that due to preferred spallation along the foliation, the cratering efficiency is higher if the foliation is horizontal. The study further presents a comprehensive quantitative strain analysis in the subsurface of these craters. We use biotite kink bands as strain markers. The distribution of strain differs strongly in both experiments. If the foliation is vertical, the area beneath the central crater floor shows a high compressive strain. This is attributed to the ability of biotite to kink more easily when shortened parallel to its basal plane. If the foliation is horizontal, surface kinking is reduced and tensile failure along the foliation deepens the crater during unloading.

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“…Hence, based on these experiments it can be concluded that the shock pressure generated due to impact has affected the rock magnetic properties of the target basalts presently exposed around Lonar crater rim and surrounding areas (Arif et al 2012b). Agarwal et al (2019), in their recent experiments on gneissic target, show that the reorientation of magnetic fabrics is possible at shock pressure as low as 0.1 GPa. This experiment is perhaps not analogous to Lonar impact because like the gneissic target, Lonar target basalt does not have a strong preimpact magnetic fabric that could influence the orientation of AMS axes due to impact.…”

Section: Shock Pressure and Rock Magnetic Properties Of Lonar Crater Rim Basaltsmentioning

confidence: 98%

Rock magnetism of ejected basaltic boulders from Lonar crater, India: Implications for the existence of a short‐lived impact‐generated weak magnetic field

Arif

Misra

2021

Meteorit & Planetary Scien

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The continuous ejecta deposit around the rim of Lonar impact crater, central India, contains angular basaltic boulders of size ≤5 m. These boulders experienced varying level of shock between 2-30 GPa due to impact, as indicated by the extreme fracturing of these basaltic boulders, fragmentation of plagioclase and titanomagnetite constituents of these ejected boulders, and the presence of maskelynite in them. We measure some rock magnetic properties, e.g., NRM/v (natural remanent magnetization [NRM]/bulk magnetic susceptibility [v]), REM (=NRM/saturation isothermal remanent magnetization [SIRM] ratio expressed in %), and anisotropy of magnetic susceptibility (AMS) on 53 subsamples from 18 oriented drill cores of the shocked ejected basaltic boulders from the eastern half of ejecta deposit in the present study. The measured data are similar in many respects to our previous observations on Lonar crater rim shocked basalts (Arif et al. 2012b). For example, a small population of the ejected basaltic boulder samples show very high NRM/v (between 378 and 989 Am À1 ; n = 7) and REM (between 1.5 and 7%; n = 4) and the AMS axes of these ejected basaltic boulders show triaxial distributions in stereographic projections. Moreover, some of the ejected basaltic boulders show higher values of squareness ratio (M rs /M s ) and median destructive field (MDF) suggesting permanent changes in the intrinsic magnetic properties due to impact shock pressure. In stereographic plot, the high coercivity and high temperature (HC_HT) magnetization component of these ejected basaltic boulders are distributed in discrete clusters on the periphery of a small enveloping circle whose center (D = 108.0°, I = +69.2°) lies close to the HC_HT cluster of the crater rim shocked basalts. The center of this enveloping circle and the average HC_HT component of Lonar crater rim shocked basalts have the same statistical orientation, although the former has steeper dip. This distribution suggests the possibility that the ejected basaltic boulders, which were deposited during the modification stage of Lonar crater evolution, were magnetized in an impact-induced magnetic field that was rapidly decaying just after the impact. Our present study suggests that the ejected basaltic boulders and Lonar crater rim shocked basalts experienced high shock pressure (≥2 GPa) magnetization during impact.

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Variation in Magnetic Fabrics at Low Shock Pressure Due to Experimental Impact Cratering

Cited by 9 publications

References 61 publications

Curie temperature of weakly shocked target basalts at the Lonar impact crater, India

Curie temperature of weakly shocked target basalts at the Lonar impact crater, India

Impact Experiment on Gneiss: The Effects of Foliation on Cratering Process

Rock magnetism of ejected basaltic boulders from Lonar crater, India: Implications for the existence of a short‐lived impact‐generated weak magnetic field

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