Mineralogical and textural influence on rock strength

Publikationen: Thesis / Studienabschlussarbeiten und HabilitationsschriftenMasterarbeit

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Mineralogical and textural influence on rock strength. / Böhm, Elisabeth.
2022.

Publikationen: Thesis / Studienabschlussarbeiten und HabilitationsschriftenMasterarbeit

Harvard

Böhm, E 2022, 'Mineralogical and textural influence on rock strength', Dipl.-Ing., Montanuniversität Leoben (000).

APA

Böhm, E. (2022). Mineralogical and textural influence on rock strength. [Masterarbeit, Montanuniversität Leoben (000)].

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@mastersthesis{c60df605fee4473791314695117a6225,
title = "Mineralogical and textural influence on rock strength",
abstract = "The influence of mineralogical composition as well as textural characteristics on strength and deformation behaviour of rocks have been investigated in recent years. The results of these studies are based on rocks with simple mineral paragenesis consisting of quartz, feldspar and phyllosilicates. To further investigate the applicability of mineralogical and strength correlations on rocks with more complex mineral paragenesis, gneiss specimens from two locations within the Eastern alps are tested. Those two sample groups have experienced different grades of metamorphism with one developing a complex high-grade metamorphic paragenesis with high garnet and sillimanite contents. Thin section analysis is used to determine the mineralogical composition, texture and grain size. The characterization of strength behaviour is investigated by conducting uniaxial and triaxial compressive tests with ultrasonic wave velocities providing additional information. High-grade metamorphic rocks develop a higher rock strength than low-grade metamorphic rocks. In complex mineral paragenesis, garnet content is found to be the most dominant influencing factor of rock strength. Higher garnet content leads to higher strength in samples with the same phyllosilicate content. Quartz also contributes to higher rock strength, while feldspar and phyllosilicate content do not show a significant correlation with strength. The equivalent quartz content is determined as a simple approach to summarize the mineralogical composition and increases with increasing strength. Textural differences, especially in the formation of phyllosilicate layers, are important for the failure modes and fracture formation. Consistent phyllosilicate layers, as found in high-grade metamorphic rocks, promote shear fractures parallel to the foliation. Even a small deviation from a foliation angle of 90° leads to significant cleavage-fracture formation. Medium-grained augen, which are surrounded by phyllosilicates, are not penetrated by tension cracks. Phyllosilicates are bent around the augen and, therefore, also orientated parallel to the direction of the loading axis. Planar schistosity, as observed in low-grade metamorphic rocks promotes splitting along the foliation whereas deformed garnet porphyroclasts within phyllosilicate layers in high-grade metamorphic rocks prevent this behaviour.",
keywords = "Rock Mechanics, Uniaxial Compression Test, Triaxial Compression Test, Modal Anaylsis, Gneiss, Anisotropic Rock, Schistosity, Rock Strength, Mineralogical Composition, Fracture Propagation, Felsmechanik, Einaxialer Druckversuch, Triaxialer Druckversuch, Modalanalyse, Gneis, Anisotropes Gestein, Schieferung, Gesteinsfestigkeit, Mineralogische Zusammensetzung, Rissausbreitung",
author = "Elisabeth B{\"o}hm",
note = "no embargo",
year = "2022",
language = "English",
school = "Montanuniversitaet Leoben (000)",

}

RIS (suitable for import to EndNote) - Download

TY - THES

T1 - Mineralogical and textural influence on rock strength

AU - Böhm, Elisabeth

N1 - no embargo

PY - 2022

Y1 - 2022

N2 - The influence of mineralogical composition as well as textural characteristics on strength and deformation behaviour of rocks have been investigated in recent years. The results of these studies are based on rocks with simple mineral paragenesis consisting of quartz, feldspar and phyllosilicates. To further investigate the applicability of mineralogical and strength correlations on rocks with more complex mineral paragenesis, gneiss specimens from two locations within the Eastern alps are tested. Those two sample groups have experienced different grades of metamorphism with one developing a complex high-grade metamorphic paragenesis with high garnet and sillimanite contents. Thin section analysis is used to determine the mineralogical composition, texture and grain size. The characterization of strength behaviour is investigated by conducting uniaxial and triaxial compressive tests with ultrasonic wave velocities providing additional information. High-grade metamorphic rocks develop a higher rock strength than low-grade metamorphic rocks. In complex mineral paragenesis, garnet content is found to be the most dominant influencing factor of rock strength. Higher garnet content leads to higher strength in samples with the same phyllosilicate content. Quartz also contributes to higher rock strength, while feldspar and phyllosilicate content do not show a significant correlation with strength. The equivalent quartz content is determined as a simple approach to summarize the mineralogical composition and increases with increasing strength. Textural differences, especially in the formation of phyllosilicate layers, are important for the failure modes and fracture formation. Consistent phyllosilicate layers, as found in high-grade metamorphic rocks, promote shear fractures parallel to the foliation. Even a small deviation from a foliation angle of 90° leads to significant cleavage-fracture formation. Medium-grained augen, which are surrounded by phyllosilicates, are not penetrated by tension cracks. Phyllosilicates are bent around the augen and, therefore, also orientated parallel to the direction of the loading axis. Planar schistosity, as observed in low-grade metamorphic rocks promotes splitting along the foliation whereas deformed garnet porphyroclasts within phyllosilicate layers in high-grade metamorphic rocks prevent this behaviour.

AB - The influence of mineralogical composition as well as textural characteristics on strength and deformation behaviour of rocks have been investigated in recent years. The results of these studies are based on rocks with simple mineral paragenesis consisting of quartz, feldspar and phyllosilicates. To further investigate the applicability of mineralogical and strength correlations on rocks with more complex mineral paragenesis, gneiss specimens from two locations within the Eastern alps are tested. Those two sample groups have experienced different grades of metamorphism with one developing a complex high-grade metamorphic paragenesis with high garnet and sillimanite contents. Thin section analysis is used to determine the mineralogical composition, texture and grain size. The characterization of strength behaviour is investigated by conducting uniaxial and triaxial compressive tests with ultrasonic wave velocities providing additional information. High-grade metamorphic rocks develop a higher rock strength than low-grade metamorphic rocks. In complex mineral paragenesis, garnet content is found to be the most dominant influencing factor of rock strength. Higher garnet content leads to higher strength in samples with the same phyllosilicate content. Quartz also contributes to higher rock strength, while feldspar and phyllosilicate content do not show a significant correlation with strength. The equivalent quartz content is determined as a simple approach to summarize the mineralogical composition and increases with increasing strength. Textural differences, especially in the formation of phyllosilicate layers, are important for the failure modes and fracture formation. Consistent phyllosilicate layers, as found in high-grade metamorphic rocks, promote shear fractures parallel to the foliation. Even a small deviation from a foliation angle of 90° leads to significant cleavage-fracture formation. Medium-grained augen, which are surrounded by phyllosilicates, are not penetrated by tension cracks. Phyllosilicates are bent around the augen and, therefore, also orientated parallel to the direction of the loading axis. Planar schistosity, as observed in low-grade metamorphic rocks promotes splitting along the foliation whereas deformed garnet porphyroclasts within phyllosilicate layers in high-grade metamorphic rocks prevent this behaviour.

KW - Rock Mechanics

KW - Uniaxial Compression Test

KW - Triaxial Compression Test

KW - Modal Anaylsis

KW - Gneiss

KW - Anisotropic Rock

KW - Schistosity

KW - Rock Strength

KW - Mineralogical Composition

KW - Fracture Propagation

KW - Felsmechanik

KW - Einaxialer Druckversuch

KW - Triaxialer Druckversuch

KW - Modalanalyse

KW - Gneis

KW - Anisotropes Gestein

KW - Schieferung

KW - Gesteinsfestigkeit

KW - Mineralogische Zusammensetzung

KW - Rissausbreitung

M3 - Master's Thesis

ER -