Bulk metallic glass composites fabricated via high pressure torsion

Publikationen: Thesis / Studienabschlussarbeiten und HabilitationsschriftenDissertation

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Bulk metallic glass composites fabricated via high pressure torsion. / Krämer, Lisa.
2018.

Publikationen: Thesis / Studienabschlussarbeiten und HabilitationsschriftenDissertation

Harvard

Krämer, L 2018, 'Bulk metallic glass composites fabricated via high pressure torsion', Dr.mont., Montanuniversität Leoben (000).

APA

Krämer, L. (2018). Bulk metallic glass composites fabricated via high pressure torsion. [Dissertation, Montanuniversität Leoben (000)].

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@phdthesis{a506d73bc60848398b7e6b49b1306bae,
title = "Bulk metallic glass composites fabricated via high pressure torsion",
abstract = "For this thesis high pressure torsion (HPT) was used to fabricate bulk metallic glasses (BMGs) and bulk metallic glass composites (BMGCs) starting from powders. The powders (amorphous and crystalline) were mixed by hand and the subsequent HPT-process leads to consolidation of the particles and refinement of the microstructure. Using this technique gives a high flexibility regarding combination of different materials and their ratios. The evolution of the microstructures was investigated by means of scanning electron microscopy (SEM), X-ray diffraction (XRD), hardness measurements and transmission electron microscopy (TEM). BMGs generated from powders via HPT require a certain amount of applied shear strain to enforce welding of the particles, and a dense and homogenous microstructure can be obtained. This required strain depends on the used amorphous powder. The obtained microstructure of the BMGCs is lamellar and the phase spacing can be varied from micrometers to nanometers by increasing the applied shear strain. Very high deformation led to the formation of a saturation microstructure, which contained for most compositions only one amorphous phase generated by mixing of the initial materials. For one composite containing 80 wt% of Cu, a nanocrystalline supersaturated solid solution of Cu with elongated MG-nanolamellae was formed instead. Mechanical properties were investigated by means of nanoindentation, micropillar compression tests and tensile tests. To determine the onset of plastic deformation, a new method of analysis for strain rate jump tests was developed. Thereby, activation energy and volume can be calculated. The main parameter controlling the onset of shear bands is the testing temperature, while composition, energy state, fabrication method and even the second phase in composites have a minor effect. However, the second phase has a great influence on the propagation of the shear bands, which is shown by micropillar compression tests. The shear bands are affected by the material of the second phase (crystalline or amorphous), by the structural size of the phases and also by the orientation of the lamellar structure regarding the loading direction. In conclusion, BMGs and BMGCs were fabricated via HPT and the microstructural evolution was investigated. Changes in deformation behavior were studied and it was shown that the nucleation of shear bands depends mainly on the homologous temperature of the MG, while their propagation can be influenced by adding a second phase.",
keywords = "metallisches Glas, Komposit, Hochdrucktorsion, Nanoindentation, Mikropillardruckversuch, mikrostrukturelle Entwicklung, bulk metallic glass, bulk metallic glass composite, high pressure torsion, nanoindentation, micropillar compression test, microstructural evolution",
author = "Lisa Kr{\"a}mer",
note = "no embargo",
year = "2018",
language = "English",
school = "Montanuniversitaet Leoben (000)",

}

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TY - BOOK

T1 - Bulk metallic glass composites fabricated via high pressure torsion

AU - Krämer, Lisa

N1 - no embargo

PY - 2018

Y1 - 2018

N2 - For this thesis high pressure torsion (HPT) was used to fabricate bulk metallic glasses (BMGs) and bulk metallic glass composites (BMGCs) starting from powders. The powders (amorphous and crystalline) were mixed by hand and the subsequent HPT-process leads to consolidation of the particles and refinement of the microstructure. Using this technique gives a high flexibility regarding combination of different materials and their ratios. The evolution of the microstructures was investigated by means of scanning electron microscopy (SEM), X-ray diffraction (XRD), hardness measurements and transmission electron microscopy (TEM). BMGs generated from powders via HPT require a certain amount of applied shear strain to enforce welding of the particles, and a dense and homogenous microstructure can be obtained. This required strain depends on the used amorphous powder. The obtained microstructure of the BMGCs is lamellar and the phase spacing can be varied from micrometers to nanometers by increasing the applied shear strain. Very high deformation led to the formation of a saturation microstructure, which contained for most compositions only one amorphous phase generated by mixing of the initial materials. For one composite containing 80 wt% of Cu, a nanocrystalline supersaturated solid solution of Cu with elongated MG-nanolamellae was formed instead. Mechanical properties were investigated by means of nanoindentation, micropillar compression tests and tensile tests. To determine the onset of plastic deformation, a new method of analysis for strain rate jump tests was developed. Thereby, activation energy and volume can be calculated. The main parameter controlling the onset of shear bands is the testing temperature, while composition, energy state, fabrication method and even the second phase in composites have a minor effect. However, the second phase has a great influence on the propagation of the shear bands, which is shown by micropillar compression tests. The shear bands are affected by the material of the second phase (crystalline or amorphous), by the structural size of the phases and also by the orientation of the lamellar structure regarding the loading direction. In conclusion, BMGs and BMGCs were fabricated via HPT and the microstructural evolution was investigated. Changes in deformation behavior were studied and it was shown that the nucleation of shear bands depends mainly on the homologous temperature of the MG, while their propagation can be influenced by adding a second phase.

AB - For this thesis high pressure torsion (HPT) was used to fabricate bulk metallic glasses (BMGs) and bulk metallic glass composites (BMGCs) starting from powders. The powders (amorphous and crystalline) were mixed by hand and the subsequent HPT-process leads to consolidation of the particles and refinement of the microstructure. Using this technique gives a high flexibility regarding combination of different materials and their ratios. The evolution of the microstructures was investigated by means of scanning electron microscopy (SEM), X-ray diffraction (XRD), hardness measurements and transmission electron microscopy (TEM). BMGs generated from powders via HPT require a certain amount of applied shear strain to enforce welding of the particles, and a dense and homogenous microstructure can be obtained. This required strain depends on the used amorphous powder. The obtained microstructure of the BMGCs is lamellar and the phase spacing can be varied from micrometers to nanometers by increasing the applied shear strain. Very high deformation led to the formation of a saturation microstructure, which contained for most compositions only one amorphous phase generated by mixing of the initial materials. For one composite containing 80 wt% of Cu, a nanocrystalline supersaturated solid solution of Cu with elongated MG-nanolamellae was formed instead. Mechanical properties were investigated by means of nanoindentation, micropillar compression tests and tensile tests. To determine the onset of plastic deformation, a new method of analysis for strain rate jump tests was developed. Thereby, activation energy and volume can be calculated. The main parameter controlling the onset of shear bands is the testing temperature, while composition, energy state, fabrication method and even the second phase in composites have a minor effect. However, the second phase has a great influence on the propagation of the shear bands, which is shown by micropillar compression tests. The shear bands are affected by the material of the second phase (crystalline or amorphous), by the structural size of the phases and also by the orientation of the lamellar structure regarding the loading direction. In conclusion, BMGs and BMGCs were fabricated via HPT and the microstructural evolution was investigated. Changes in deformation behavior were studied and it was shown that the nucleation of shear bands depends mainly on the homologous temperature of the MG, while their propagation can be influenced by adding a second phase.

KW - metallisches Glas

KW - Komposit

KW - Hochdrucktorsion

KW - Nanoindentation

KW - Mikropillardruckversuch

KW - mikrostrukturelle Entwicklung

KW - bulk metallic glass

KW - bulk metallic glass composite

KW - high pressure torsion

KW - nanoindentation

KW - micropillar compression test

KW - microstructural evolution

M3 - Doctoral Thesis

ER -