olivine and ferrous-oxide

olivine has been researched along with ferrous-oxide* in 2 studies

Other Studies

2 other study(ies) available for olivine and ferrous-oxide

Article	Year
Surface microstructures of lunar soil returned by Chang'e-5 mission reveal an intermediate stage in space weathering process. Science bulletin, 2022, 08-31, Volume: 67, Issue:16 The lunar soils evolution over time is mainly caused by space weathering that includes the impacts of varying-sized meteoroids and charged particles implantation of solar/cosmic winds as well. It has long been established that space weathering leads to the formation of outmost amorphous layers (50-200 nm in thickness) embedded nanophase iron (npFe Topics: Animals; Extraterrestrial Environment; Female; Horses; Mars; Minerals; Silicon Dioxide; Soil	2022
The use of a high-FeO olivine rock as a redox buffer in a nuclear waste repository. Journal of contaminant hydrology, 2006, Feb-01, Volume: 83, Issue:1-2 Due to the higher stability of the spent nuclear fuel (mainly composed of UO2) under reducing conditions, and in order to enhance the retention/retardation of some key radionuclides, the olivine rock from the Lovasjärvi intrusion has been proposed as a potential redox-active backfill-additive in deep high-level nuclear waste (HLNW) repositories. In this work, two different approaches have been undertaken in order to establish the redox buffer capacity of olivine rock: (1) The capacity of the rock to respond to changes in pH or pe has been demonstrated and the final (pH, pe) coordinates agree with the control exerted by the system Fe(II)/Fe(III). (2) The rate of consumption of oxygen has been determined at different pH values. These rates are higher than the ones reported in the literature for other solids, what would point to the possibility of using this rock as an additive to the backfill material in a HLNW. Topics: Buffers; Ferrous Compounds; Geological Phenomena; Geology; Hydrogen-Ion Concentration; Iron Compounds; Magnesium Compounds; Oxidation-Reduction; Oxygen; Radioactive Waste; Silicates; Waste Management; Water Pollution, Radioactive	2006

Article

Year

Surface microstructures of lunar soil returned by Chang'e-5 mission reveal an intermediate stage in space weathering process.

Science bulletin, 2022, 08-31, Volume: 67, Issue:16

The lunar soils evolution over time is mainly caused by space weathering that includes the impacts of varying-sized meteoroids and charged particles implantation of solar/cosmic winds as well. It has long been established that space weathering leads to the formation of outmost amorphous layers (50-200 nm in thickness) embedded nanophase iron (npFe

Topics: Animals; Extraterrestrial Environment; Female; Horses; Mars; Minerals; Silicon Dioxide; Soil

2022

The use of a high-FeO olivine rock as a redox buffer in a nuclear waste repository.

Journal of contaminant hydrology, 2006, Feb-01, Volume: 83, Issue:1-2

Due to the higher stability of the spent nuclear fuel (mainly composed of UO2) under reducing conditions, and in order to enhance the retention/retardation of some key radionuclides, the olivine rock from the Lovasjärvi intrusion has been proposed as a potential redox-active backfill-additive in deep high-level nuclear waste (HLNW) repositories. In this work, two different approaches have been undertaken in order to establish the redox buffer capacity of olivine rock: (1) The capacity of the rock to respond to changes in pH or pe has been demonstrated and the final (pH, pe) coordinates agree with the control exerted by the system Fe(II)/Fe(III). (2) The rate of consumption of oxygen has been determined at different pH values. These rates are higher than the ones reported in the literature for other solids, what would point to the possibility of using this rock as an additive to the backfill material in a HLNW.

Topics: Buffers; Ferrous Compounds; Geological Phenomena; Geology; Hydrogen-Ion Concentration; Iron Compounds; Magnesium Compounds; Oxidation-Reduction; Oxygen; Radioactive Waste; Silicates; Waste Management; Water Pollution, Radioactive

2006