ГеохимияГеохимия0016-7525The Russian Academy of Sciences1588410.31857/S0016-7525648859-868Research ArticleShock-wave experiment with the Chelyabinsk LL5 meteorite: experimental parameters and the texture of the shock-affected material)PetrovaE. V.evgeniya.petrova@urfu.ruGrokhovskyV. I.evgeniya.petrova@urfu.ruKohoutT.<p>Faculty of Science</p>evgeniya.petrova@urfu.ruMuftakhetdinovaR. F.evgeniya.petrova@urfu.ruYakovlevG. G.evgeniya.petrova@urfu.ruUral Federal University, Institute of Physics and TechnologyHelsinki University0309201964885986829082019Copyright © 2019, Russian Academy of Sciences2019<p style="text-align: justify;">The shock experiment with Chelyabinsk LL5 light lithology material was performed as a spherical geometry shock. The material experienced shock and thermal metamorphism from the initial S34 up to complete melt stage. Temperature and pressure realized were estimated above 2000С and 90 GPa. Textural shock effects were studied by the means of optical and electron microscopy. By the only experimental impact, all the range of the shock pressures and temperatures was realized. Four zones were revealed from the petrographic analysis: 1 melt zone, 2 melted silicates zone, 3 black ring zone, 4 weakly shocked initial material. Several features of the material texture were noted: displacement of the metal and troilite phases from the central melt zone; mixed lithology zone formation (light-colored chondrules within the silicate melt); dark-colored lithology ring formation; generation of radial-oriented shock veins. Thus, at the experimental fragment, four texture zones were formed. These zones correspond to the different lithology types of the Chelyabinsk LL5 meteorite, which could be found in different fragments of the meteoritic shower from UrFU collection. The results obtained prove that the shock wave loading experiment could be used for space shock modeling. 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