Your search keyword '"I. Gyollai"' showing total 15 results

1. Review of meteorite irradiation tests to support next C-type asteroid missions

Author

Á Kereszturi, I Gyollai, Z Juhász, B D Pál, R Rácz, D Rezes, and B Sulik

Subjects

Space and Planetary Science, Astronomy and Astrophysics

Abstract

Effect of space weathering of airless asteroids could be better understood by artificial irradiation tests on meteorites in laboratories. This work surveys the infrared and Raman analysis based interpretation of simulated charged particle irradiation tests in order to better understand near-future observational possibilities of asteroid visiting missions and also to support the planning of next missions and directions of detector improvement. Recent works properly targeted different meteors and meteor relevant minerals, evaluating bulk meteorite spectra, during the irradiation tests. He+, (Ne+, Kr+), and Ar+ ions were used with fluxes characteristic for inner planetary system solar wind, considering 1–10 million yr exposure durations. Although main meteorite minerals were irradiated and analysed, one missing aspect is that only bulk analysis have been done, not minerals separately in their original embedded context. Some Earth based mineral references were also analysed; however, they might not necessarily behave similar to the same type of reference minerals and irradiation effect is poorly known for feldspar, troilite, and magnetite. Darkening should be also further analysed for separate minerals too, together with the record of peak shape and position changes. Infrared ATR analysis might still provide such data in the future using the recently emerged technology, as well as Raman analysis – however for flyby missions’ infrared is the useful method while Raman can be used only at in situ missions. The overview including the tables to support the identification of specific missing information related gaps in our current knowledge and directions for future research.

Published

2022

2. Terraforming on Early Mars

Author

M. Polgári, I. Gyollai, and Sz. Bérczi

Published

2021

3. CATHODOLUMINESCENCE MICROSCOPY AND SPECTROSCOPY OF FORSTERITE FROM THE TAGISH LAKE METEORITE: AN IMPLICATION FOR THE ASTEROIDAL PROCESSES

Author

A Gucsik, H Nishido, K Ninagawa, I Gyollai, M Izawa, C Jäger, U Ott, and M Kayama

Published

2015

4. PLANETARY SCIENCE SYNTHESIS EDUCATION USING STRUCTURAL HIERARCHY FOR MARTIAN MATERIALS

Author

Sz. Bérczi, S. Józsa, T. Varga, I. Gyollai, and Sz. Nagy

Published

2015

5. CLEAVAGE INDUCED AKIMOTOITE TRANSFORMATION IN SHOCKED CHONDRITES

Author

Sz. Nagy, I. Gyollai, A. Gucsik, and Sz. Bérczi

Published

2014

6. CATHODOLUMINESCENCE MICROSCOPY AND SPECTROSCOPY OF FORSTERITE FROM THE TAGISH LAKE METEORITE: AN IMPLICATION FOR THE LUMINESCENCE-BASED ASTROMINERALOGY

Author

A. Gucsik, H Nishido, K Ninagawa, I Gyollai, M Izawa, and A Kereszturi

Published

2014

7. CHEMISTRY EXPERIMENTS -FOR COMPARATIVE ANALYSES FOR DEMONSTRATING ENVIRONMENTAL DIFFERENCES ON VENUS, EARTH, MARS, AND TITAN -BUILT ON EDUCATIONAL SPACE PROBES HUNVEYOR AND HUSAR

Author

Bérczi, A Róka, Z Nyíri, T Varga, A Fabriczy, Cs Peták, Gy Hudoba, S Hegyi, A Lang, I Gyollai, and A Gucsik

Published

2014

8. INVESTIGATION OF RINGWOODITE AGGREGATE TEXTURES IN SHOCK VEINS

Author

Sz. Nagy, I. Gyollai, A. Gucsik, and Sz. Bérczi

Published

2014

9. Petrographic investigation of Yamato-791717 CO3 chondrite

Author

Fürj, I Gyollai, Bérczi, A Gucsik, and Sz Nagy

Published

2009

10. Raman Spectroscopy of Shocked Olivine in the Hungarian L-Chondrite, Mócs

Author

J. Fürj, I. Gyollai, Sz. Bérczi, A. Gucsik, Sz. Nagy, and M. Veres

Published

2009

11. Application of the differentiation modell of Takahashi for a chondritic asteroidal body in our studies comparing Mezomadaras, Yamato-74191 and Yamato-84151 meteorites

Author

I Gyollai, J Fürj, Sz Bérczi, A Gucsik, Sz Nagy, and M Veres

Published

2009

12. Petrographic and Micro-Raman Study of Thermal and Shock Metamorphism in Mezőmadaras, Knyahinya and Mócs L-Chondrites

Author

I. Gyollai, Sz. Nagy, J. Fürj, Sz. Bérczi, A. Gucsik, M. Veres, and Arnold Gucsik

Subjects

Petrography, Shock metamorphism, Olivine, Meteorite, Chondrite, Metamorphic rock, Planar deformation features, engineering, Mineralogy, Pyroxene, engineering.material, Geology

Abstract

We investigated three Hungarian L‐chondrites: Mezőmadaras, Knyahinya, and Mocs sample. In Knyahinya chondrite, two phenomena were observed as follows: the weak mosaicism (S4) and mechanical twins in pyroxene. The Mocs sample is characterized by strong shock metamorphic effects such as high density of fractures and abundant shock‐veins. Planar Deformation Features (PDFs) were identified in two olivine grains, and an olivine grain shows well‐developed Planar Fractures (PFs). In Mezőmadaras sample, there are irregular fractures (S1), and PFs (S3), and mechanical twins in pyroxene. We have reinvestigated of these meteorite samples using Raman spectroscopy for the identification of shock‐metamorphic effects, which occurred in the structure changes of olivine and pyroxene grains. The olivine doublet peak position is shifted to higher wavenumbers, due to partly disordered olivine structure. We observed that minerals with mechanical twins exhibit less interference color, compared to the non‐shocked minerals, especially pyroxene. It is important to note that, the mechanical twins were complicated to describe, only the direction of the deformation was determined. On the basis of the measured FWHM, the following structural disordering degree of the selected samples can be determined as a (growing rate): Castle Rock, Mezőmadaras, Shergotty and Mocs. The result reveals that amorphization rate is the highest in Mocs and Shergotty pyroxene grains.

Published

2009

13. Microbially Mediated Ore-Forming Processes and Cell Mineralization.

Author

Polgári M, Gyollai I, Fintor K, Horváth H, Pál-Molnár E, and Biondi JC

Abstract

Sedimentary black shale-hosted manganese carbonate and oxide ores were studied by high-resolution in situ detailed optical and cathodoluminescence microscopy, Raman spectroscopy, and FTIR spectroscopy to determine microbial contribution in metallogenesis. This study of the Urucum Mn deposit in Brazil is included as a case study for microbially mediated ore-forming processes. The results were compared and interpreted in a comparative way, and the data were elaborated by a complex, structural hierarchical method. The first syngenetic products of microbial enzymatic oxidation were ferrihydrite and lepidocrocite on the Fe side, and vernadite, todorokite, birnessite, and manganite on the Mn side, formed under obligatory oxic (Mn) and suboxic (Fe) conditions and close to neutral pH. Fe- and Mn-oxidizing bacteria played a basic role in metallogenesis based on microtextural features, bioindicator minerals, and embedded variable organic matter. Trace element content is determined by source of elements and microbial activity. The present Urucum (Brazil), Datangpo (China), and Úrkút (Hungary) deposits are the result of complex diagenetic processes, which include the decomposition and mineralization of cell and extracellular polymeric substance (EPS) of Fe and Mn bacteria and cyanobacteria. Heterotrophic cell colonies activated randomly in the microbialite sediment after burial in suboxic neutral/alkaline conditions, forming Mn carbonates and variable cation-bearing oxides side by side with lithification and stabilization of minerals. Deposits of variable geological ages and geographical occurrences show strong similarities and indicate two-step microbial metallogenesis: a primary chemolithoautotrophic, and a diagenetic heterotrophic microbial cycle, influenced strongly by mineralization of cells and EPSs. These processes perform a basic role in controlling major and trace element distribution in sedimentary environments on a global level and place biogeochemical constraints on the element content of natural waters, precipitation of minerals, and water contaminants., (Copyright © 2019 Polgári, Gyollai, Fintor, Horváth, Pál-Molnár and Biondi.)

Published

2019

14. Characterization and 10 Be content of iron carbonate concretions for genetic aspects - Weathering, desert varnish or burning: Rim effects in iron carbonate concretions.

Author

Polgári M, Bérczi S, Horiuchi K, Matsuzaki H, Kovács T, Józsa S, Bendő Z, Fintor K, Fekete J, Homonnay Z, Kuzmann E, Gucsik A, Gyollai I, Kovács J, and Dódony I

Subjects

Geologic Sediments chemistry, Hungary, Minerals chemistry, Paint, Weather, Beryllium analysis, Carbonates chemistry, Ferric Compounds chemistry, Radiation Monitoring

Abstract

The research investigated three iron carbonate (siderite) sedimentary concretions from Nagykovácsi, Úri and Délegyháza, Hungary. To identify possible source rocks and effects of the glaze-like exposed surface of the concretions, we carried on comparative petrological, mineralogical, geochemical and isotopic studies. The samples were microbially mediated siderite concretions with embedded metamorphous and igneous mineral clasts, and had specific rim belts characterized by semi-concentric outer Fe-oxide layers, fluffy pyrite-rich outer belts and siderite inner parts. We investigated the cross section of the Fe-carbonate concretions by independent methodologies in order to identify their rim effects. Their surficial oxide layers showed evidence of degassing of the exposed surface caused most probably by elevated temperatures. The inner rim pyrite belt in the concretions excluded the possibility of a prolonged wet surface environment. Microtextural and mineralogical features did not support desert varnish formation. 10 Be nuclide values of the Nagykovácsi and Uri concretions were far above the level of terrestrial in-situ cosmogenic nuclides, but they were consistent with the lowest levels for meteorites. Though the data were not conclusive to confirm any kind of known origin, they are contradictary, and open possibilities for a scenario of terrestrial meteorite origin., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2017

15. Analyzing Raman - Infrared spectral correlation in the recently found meteorite Csátalja.

Author

Kereszturi A, Gyollai I, Kereszty Z, Kiss K, Szabó M, Szalai Z, Ringer M, and Veres M

Abstract

Correlating the Raman and infrared spectra of shocked minerals in Csátalja ordinary chondrite (H4, S2, W2) with controlling the composition by EPMA measurements, we identified and improved various shock indicators, as infrared spectro-microscopic analysis has been poorly used for shock impact alteration studies of meteorites to date. We also provide reference spectra as SOM for the community with local mineralogical and shock alteration related context to support further standardization of the IR ATR based measurements. Raman band positions shifted in conjunction with the increase in full width half maximum (FWHM) with shock stage in olivine minerals while in the infrared spectra when comparing the IR band positions and IR maximal absorbance, increasing correlation was found as a function of increasing shock effects. This is the first observational confirmation with the ATR method of the already expected shock related disordering. In the case of shocked pyroxenes the well-known peak broadening and peak shift was confirmed by Raman method, beyond the level that could have been produced by only chemical changes. With increasing shock level the 852-864cm -1 and 1055-1071cm -1 FTIR bands finally disappeared. From the shock effect occasionally mixed mineral structures formed, especially feldspars together with pyroxene. Feldspars were only present in the shock melted volumes, thus produced by the shock effect itself. Based on the above mentioned observations in Csátalja meteorite the less shocked (only fractured) part witnessed 2-6GPa shock pressure with temperature below 100°C. The moderately shocked parts (minerals with mosaicism and mechanical twins) witnessed 5-10GPa pressure and 900°C temperature. The strongly shocked area (many olivine and pyroxene grains) was subject to 10-15GPa and 1000°C. The existence of broad peak near 510cm -1 and disappearance of other peaks of feldspar at 480 and 570cm -1 indicate the presence of maskelynite, which proposes that the peak shock pressure could reach 20GPa at certain locations. We identified higher shock levels than earlier works in this meteorite and provided examples how heterogeneous the shock effect and level could be at small spatial scale. The provided reference spectra support the future improvement for the standardization of infrared ATR based methods and the understanding of shock-related mineral alterations beyond the optical appearance., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2017