Microstructural evolution and thermal stability of AlCr(Si)N hard coatings revealed by in-situ high-temperature high-energy grazing incidence transmission X-ray diffraction
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In: Acta materialia, Vol. 186.2020, No. March, 18.01.2020, p. 545-554.
Research output: Contribution to journal › Article › Research › peer-review
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TY - JOUR
T1 - Microstructural evolution and thermal stability of AlCr(Si)N hard coatings revealed by in-situ high-temperature high-energy grazing incidence transmission X-ray diffraction
AU - Jäger, Nikolaus
AU - Meindlhumer, Michael
AU - Spor, S.
AU - Hruby, Hynek
AU - Julin, J.
AU - Stark, Andreas
AU - Nahif, F.
AU - Keckes, Julius
AU - Mitterer, Christian
AU - Daniel, Rostislav
N1 - Publisher Copyright: © 2020 Acta Materialia Inc.
PY - 2020/1/18
Y1 - 2020/1/18
N2 - An extensive understanding about the microstructural evolution and thermal stability of the metastable AlCr(Si)N coating system is of considerable importance for applications facing high temperatures, but it is also a challenging task since several superimposed processes simultaneously occur at elevated temperatures. In this work, three AlCr(Si)N coatings with 0 at%., 2.5 at% and 5 at% Si were investigated by in-situ high-temperature high-energy grazing incidence transmission X-ray diffraction (HT-HE-GIT-XRD) and complementary differential scanning calorimetry and thermogravimetric analysis measurements combined with conventional ex-situ X-ray diffraction. The results revealed (i) a change in the microstructure from columnar to a fine-grained nano-composite, (ii) a reduced decomposition rate of CrN to Cr 2N, also shifted to higher onset temperatures from ~ 1000 ∘C to above ~ 1100 ∘C and (iii) an increase of lattice defects and micro strains resulting in a significant increase of compressive residual strain with increasing Si content. While the Si-containing coatings in the as-deposited state show a lower hardness of 28 GPa compared to AlCrN with 32 GPa, vacuum annealing at ~ 1100 ∘C led to an increase in hardness to 29 GPa for the coatings containing Si and a decrease in hardness to 26 GPa for AlCrN. Furthermore, the in-situ HT-HE-GIT-XRD method allowed for simultaneously accessing temperature-dependent variations of the coating microstructure (defect density, grain size), residual strain state and phase stability up to ~ 1100 ∘C. Finally, the results established a deeper understanding about the relationships between the elemental composition of the materials, the resulting microstructure including crystallographic phases and residual strain state, and the coating properties from room temperature up to ~ 1100 ∘C.
AB - An extensive understanding about the microstructural evolution and thermal stability of the metastable AlCr(Si)N coating system is of considerable importance for applications facing high temperatures, but it is also a challenging task since several superimposed processes simultaneously occur at elevated temperatures. In this work, three AlCr(Si)N coatings with 0 at%., 2.5 at% and 5 at% Si were investigated by in-situ high-temperature high-energy grazing incidence transmission X-ray diffraction (HT-HE-GIT-XRD) and complementary differential scanning calorimetry and thermogravimetric analysis measurements combined with conventional ex-situ X-ray diffraction. The results revealed (i) a change in the microstructure from columnar to a fine-grained nano-composite, (ii) a reduced decomposition rate of CrN to Cr 2N, also shifted to higher onset temperatures from ~ 1000 ∘C to above ~ 1100 ∘C and (iii) an increase of lattice defects and micro strains resulting in a significant increase of compressive residual strain with increasing Si content. While the Si-containing coatings in the as-deposited state show a lower hardness of 28 GPa compared to AlCrN with 32 GPa, vacuum annealing at ~ 1100 ∘C led to an increase in hardness to 29 GPa for the coatings containing Si and a decrease in hardness to 26 GPa for AlCrN. Furthermore, the in-situ HT-HE-GIT-XRD method allowed for simultaneously accessing temperature-dependent variations of the coating microstructure (defect density, grain size), residual strain state and phase stability up to ~ 1100 ∘C. Finally, the results established a deeper understanding about the relationships between the elemental composition of the materials, the resulting microstructure including crystallographic phases and residual strain state, and the coating properties from room temperature up to ~ 1100 ∘C.
UR - http://www.scopus.com/inward/record.url?scp=85078436825&partnerID=8YFLogxK
U2 - 10.1016/j.actamat.2020.01.026
DO - 10.1016/j.actamat.2020.01.026
M3 - Article
VL - 186.2020
SP - 545
EP - 554
JO - Acta materialia
JF - Acta materialia
SN - 1359-6454
IS - March
ER -