The Effect of 30 to >100 GPa Shock on the Magnetic Properties of Chinga Iron Meteorite › Научные исследования в СПбГУ

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The Effect of 30 to >100 GPa Shock on the Magnetic Properties of Chinga Iron Meteorite. / Bezaeva, N. S.; Badyukov, D. D.; Feinberg, J. M.; Kars, M.; Kosterov, A.

Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences: 75th Anniversary of the Vernadsky Institute of the Russian Academy of Sciences. ред. / Vladimir P. Kolotov; Natalia S. Bezaeva. Springer Nature, 2023. стр. 335-350 (Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences).

Результаты исследований: Публикации в книгах, отчётах, сборниках, трудах конференций › глава/раздел › Рецензирование

Harvard

Bezaeva, NS, Badyukov, DD, Feinberg, JM, Kars, M & Kosterov, A 2023, The Effect of 30 to >100 GPa Shock on the Magnetic Properties of Chinga Iron Meteorite. в VP Kolotov & NS Bezaeva (ред.), Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences: 75th Anniversary of the Vernadsky Institute of the Russian Academy of Sciences. Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences, Springer Nature, стр. 335-350. https://doi.org/10.1007/978-3-031-09883-3_18

APA

Bezaeva, N. S., Badyukov, D. D., Feinberg, J. M., Kars, M., & Kosterov, A. (2023). The Effect of 30 to >100 GPa Shock on the Magnetic Properties of Chinga Iron Meteorite. в V. P. Kolotov, & N. S. Bezaeva (Ред.), Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences: 75th Anniversary of the Vernadsky Institute of the Russian Academy of Sciences (стр. 335-350). (Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences). Springer Nature. https://doi.org/10.1007/978-3-031-09883-3_18

Vancouver

Bezaeva NS, Badyukov DD, Feinberg JM, Kars M, Kosterov A. The Effect of 30 to >100 GPa Shock on the Magnetic Properties of Chinga Iron Meteorite. в Kolotov VP, Bezaeva NS, Редакторы, Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences: 75th Anniversary of the Vernadsky Institute of the Russian Academy of Sciences. Springer Nature. 2023. стр. 335-350. (Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences). https://doi.org/10.1007/978-3-031-09883-3_18

Author

Bezaeva, N. S. ; Badyukov, D. D. ; Feinberg, J. M. ; Kars, M. ; Kosterov, A. / The Effect of 30 to >100 GPa Shock on the Magnetic Properties of Chinga Iron Meteorite. Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences: 75th Anniversary of the Vernadsky Institute of the Russian Academy of Sciences. Редактор / Vladimir P. Kolotov ; Natalia S. Bezaeva. Springer Nature, 2023. стр. 335-350 (Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences).

BibTeX

@inbook{64824c308db84ea4bda9ad3f9ea9e63e,

title = "The Effect of 30 to >100 GPa Shock on the Magnetic Properties of Chinga Iron Meteorite",

abstract = "We conducted a spherical shock-recovery experiment on the Chinga meteorite (Iron, ungrouped; ataxite). Explosively generated spherical shock wave traveled through the sample and created a range of pressures up to >100 GPa and temperatures, from ~250 °C at periphery up to >1000 °C in the center, along the radius of spherical sample. Shock wave propagation resulted in the formation of a central cavity and of three concentric zones of varying intensity of shock metamorphism and formation of shear bands, which were documented in iron meteorites for the first time as a result of artificial shock. The sample was then cut along the equatorial plane, and individual cubic specimens were extracted along the radius of the sphere and subjected to magnetic measurements. High and low-temperature magnetometry and thermomagnetic analyses revealed that the main magnetic carriers in Chinga ataxite are kamacite and tetrataenite. All specimens are magnetically soft and thus dominated by a typical multidomain behavior. The magnetic hardness of shocked samples (Bcr) varies within a dispersion range for unshocked samples; however, in the central zone, Bcr drops dramatically once the temperature of tetrataenite-to-taenite mineralogical transformation is reached. Hydrostatic pressure demagnetization experiments up to 1.8 GPa revealed that specimens from zone III (periphery, lower P–T) have much lower pressure sensitivity than specimens from zones I/II (more central, higher P–T). Pressure demagnetization degree is 6% for zone III and 57–74% for zones I/II. Investigation of natural remanent magnetization of the specimens revealed that the initial sample was most likely remagnetized after shock loading.",

keywords = "Chinga, Iron meteorites, Shock metamorphism, Magnetic properties",

author = "Bezaeva, {N. S.} and Badyukov, {D. D.} and Feinberg, {J. M.} and M. Kars and A. Kosterov",

year = "2023",

month = mar,

day = "1",

doi = "10.1007/978-3-031-09883-3_18",

language = "English",

isbn = "978-3-031-09882-6",

series = "Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences",

publisher = "Springer Nature",

pages = "335--350",

editor = "Kolotov, {Vladimir P.} and Bezaeva, {Natalia S.}",

booktitle = "Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences",

address = "Germany",

}

RIS

TY - CHAP

T1 - The Effect of 30 to >100 GPa Shock on the Magnetic Properties of Chinga Iron Meteorite

AU - Bezaeva, N. S.

AU - Badyukov, D. D.

AU - Feinberg, J. M.

AU - Kars, M.

AU - Kosterov, A.

PY - 2023/3/1

Y1 - 2023/3/1

N2 - We conducted a spherical shock-recovery experiment on the Chinga meteorite (Iron, ungrouped; ataxite). Explosively generated spherical shock wave traveled through the sample and created a range of pressures up to >100 GPa and temperatures, from ~250 °C at periphery up to >1000 °C in the center, along the radius of spherical sample. Shock wave propagation resulted in the formation of a central cavity and of three concentric zones of varying intensity of shock metamorphism and formation of shear bands, which were documented in iron meteorites for the first time as a result of artificial shock. The sample was then cut along the equatorial plane, and individual cubic specimens were extracted along the radius of the sphere and subjected to magnetic measurements. High and low-temperature magnetometry and thermomagnetic analyses revealed that the main magnetic carriers in Chinga ataxite are kamacite and tetrataenite. All specimens are magnetically soft and thus dominated by a typical multidomain behavior. The magnetic hardness of shocked samples (Bcr) varies within a dispersion range for unshocked samples; however, in the central zone, Bcr drops dramatically once the temperature of tetrataenite-to-taenite mineralogical transformation is reached. Hydrostatic pressure demagnetization experiments up to 1.8 GPa revealed that specimens from zone III (periphery, lower P–T) have much lower pressure sensitivity than specimens from zones I/II (more central, higher P–T). Pressure demagnetization degree is 6% for zone III and 57–74% for zones I/II. Investigation of natural remanent magnetization of the specimens revealed that the initial sample was most likely remagnetized after shock loading.

AB - We conducted a spherical shock-recovery experiment on the Chinga meteorite (Iron, ungrouped; ataxite). Explosively generated spherical shock wave traveled through the sample and created a range of pressures up to >100 GPa and temperatures, from ~250 °C at periphery up to >1000 °C in the center, along the radius of spherical sample. Shock wave propagation resulted in the formation of a central cavity and of three concentric zones of varying intensity of shock metamorphism and formation of shear bands, which were documented in iron meteorites for the first time as a result of artificial shock. The sample was then cut along the equatorial plane, and individual cubic specimens were extracted along the radius of the sphere and subjected to magnetic measurements. High and low-temperature magnetometry and thermomagnetic analyses revealed that the main magnetic carriers in Chinga ataxite are kamacite and tetrataenite. All specimens are magnetically soft and thus dominated by a typical multidomain behavior. The magnetic hardness of shocked samples (Bcr) varies within a dispersion range for unshocked samples; however, in the central zone, Bcr drops dramatically once the temperature of tetrataenite-to-taenite mineralogical transformation is reached. Hydrostatic pressure demagnetization experiments up to 1.8 GPa revealed that specimens from zone III (periphery, lower P–T) have much lower pressure sensitivity than specimens from zones I/II (more central, higher P–T). Pressure demagnetization degree is 6% for zone III and 57–74% for zones I/II. Investigation of natural remanent magnetization of the specimens revealed that the initial sample was most likely remagnetized after shock loading.

KW - Chinga

KW - Iron meteorites

KW - Shock metamorphism

KW - Magnetic properties

UR - https://www.mendeley.com/catalogue/3c62aec3-2115-319f-bd15-59b5b39e90a1/

U2 - 10.1007/978-3-031-09883-3_18

DO - 10.1007/978-3-031-09883-3_18

M3 - Chapter

SN - 978-3-031-09882-6

T3 - Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences

SP - 335

EP - 350

BT - Advances in Geochemistry, Analytical Chemistry, and Planetary Sciences

A2 - Kolotov, Vladimir P.

A2 - Bezaeva, Natalia S.

PB - Springer Nature

ER -

ID: 103320178