Microstructural and Mechanical Properties of Si-alloyed AlCrN Hard Coatings: Grain Boundary Segregation Engineering by CrN Precipitation

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@mastersthesis{5ee6cd2c08fc47a7be463e581f4ee1a6,
title = "Microstructural and Mechanical Properties of Si-alloyed AlCrN Hard Coatings: Grain Boundary Segregation Engineering by CrN Precipitation",
abstract = "In the race for hard and simultaneously tough hard coatings, for applications in the metal cutting industry, this thesis takes aim to propose grain boundary segregation engineering as a viable tool to improve mechanical properties of well-established Transition Metal Nitrides, such as AlCrN. Therefore, in a first step a gradient coating with increasing Si content was deposited by cathodic arc evaporation. This coating was annealed at different temperatures of up to 1100 °C and characterized by cross sectional X-ray nanodiffraction (CSnanoXRD) at the synchrotron source PETRA III at the German Synchrotron (DESY). Measured intensity plots of wide-angle X-ray scattering (WAXS) revealed the formation of a wurtzite (w-) AlN phase with cubic (c-) CrN precipitates and the formation of a nanocomposite structure after alloying with Si. Additionally, small-angle X-ray scattering (SAXS) data indicated the formation of 12 nm thick nanolayers in the Si-free zone of the coating, which abruptly changes to a periodicity of 25 nm after the introduction of Si. This data collected from the gradient coating was further used for the design of two reference coatings with a composition of Al0,8Cr0,2N and (Al0,7Cr0,3)0,9Si0,1N and two additional multilayered coatings of alternating composition of the two reference ones. These four coatings were tested for their mechanical properties by in situ cantilever bending experiments and displayed fracture stresses of up to 4.8 GPa and fracture toughness values of up to 2.8 MPam1/2. Through this effort we provide information on the importance of precise annealing parameters when dealing with grain boundary segregation engineering as well as limits that are inherent to this method.",
keywords = "Hard Coating, AlCrN, Cathodic Arc Evaporation, Grain Boundary Segregation, Cross sectional X-ray nanodiffraction, in situ cantilever bending, Kathodische Lichtbogenverdampfung, in situ Biegebalken Charakterisierung, R{\"o}ntgen-Nanodiffraktion, AlCrN",
author = "Tobias Ziegelwanger",
note = "embargoed until null",
year = "2021",
language = "English",
school = "Montanuniversitaet Leoben (000)",

}

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TY - THES

T1 - Microstructural and Mechanical Properties of Si-alloyed AlCrN Hard Coatings

T2 - Grain Boundary Segregation Engineering by CrN Precipitation

AU - Ziegelwanger, Tobias

N1 - embargoed until null

PY - 2021

Y1 - 2021

N2 - In the race for hard and simultaneously tough hard coatings, for applications in the metal cutting industry, this thesis takes aim to propose grain boundary segregation engineering as a viable tool to improve mechanical properties of well-established Transition Metal Nitrides, such as AlCrN. Therefore, in a first step a gradient coating with increasing Si content was deposited by cathodic arc evaporation. This coating was annealed at different temperatures of up to 1100 °C and characterized by cross sectional X-ray nanodiffraction (CSnanoXRD) at the synchrotron source PETRA III at the German Synchrotron (DESY). Measured intensity plots of wide-angle X-ray scattering (WAXS) revealed the formation of a wurtzite (w-) AlN phase with cubic (c-) CrN precipitates and the formation of a nanocomposite structure after alloying with Si. Additionally, small-angle X-ray scattering (SAXS) data indicated the formation of 12 nm thick nanolayers in the Si-free zone of the coating, which abruptly changes to a periodicity of 25 nm after the introduction of Si. This data collected from the gradient coating was further used for the design of two reference coatings with a composition of Al0,8Cr0,2N and (Al0,7Cr0,3)0,9Si0,1N and two additional multilayered coatings of alternating composition of the two reference ones. These four coatings were tested for their mechanical properties by in situ cantilever bending experiments and displayed fracture stresses of up to 4.8 GPa and fracture toughness values of up to 2.8 MPam1/2. Through this effort we provide information on the importance of precise annealing parameters when dealing with grain boundary segregation engineering as well as limits that are inherent to this method.

AB - In the race for hard and simultaneously tough hard coatings, for applications in the metal cutting industry, this thesis takes aim to propose grain boundary segregation engineering as a viable tool to improve mechanical properties of well-established Transition Metal Nitrides, such as AlCrN. Therefore, in a first step a gradient coating with increasing Si content was deposited by cathodic arc evaporation. This coating was annealed at different temperatures of up to 1100 °C and characterized by cross sectional X-ray nanodiffraction (CSnanoXRD) at the synchrotron source PETRA III at the German Synchrotron (DESY). Measured intensity plots of wide-angle X-ray scattering (WAXS) revealed the formation of a wurtzite (w-) AlN phase with cubic (c-) CrN precipitates and the formation of a nanocomposite structure after alloying with Si. Additionally, small-angle X-ray scattering (SAXS) data indicated the formation of 12 nm thick nanolayers in the Si-free zone of the coating, which abruptly changes to a periodicity of 25 nm after the introduction of Si. This data collected from the gradient coating was further used for the design of two reference coatings with a composition of Al0,8Cr0,2N and (Al0,7Cr0,3)0,9Si0,1N and two additional multilayered coatings of alternating composition of the two reference ones. These four coatings were tested for their mechanical properties by in situ cantilever bending experiments and displayed fracture stresses of up to 4.8 GPa and fracture toughness values of up to 2.8 MPam1/2. Through this effort we provide information on the importance of precise annealing parameters when dealing with grain boundary segregation engineering as well as limits that are inherent to this method.

KW - Hard Coating

KW - AlCrN

KW - Cathodic Arc Evaporation

KW - Grain Boundary Segregation

KW - Cross sectional X-ray nanodiffraction

KW - in situ cantilever bending

KW - Kathodische Lichtbogenverdampfung

KW - in situ Biegebalken Charakterisierung

KW - Röntgen-Nanodiffraktion

KW - AlCrN

M3 - Master's Thesis

ER -