Morphological characterization of semi-crystalline POM using nanoindentation

Petra Christöfl; Caterina Czibula; Tristan Seidlhofer; Michael Berer; Astrid Macher; Eric Helfer; Theresia Schrank; Gernot Oreski; Christian Teichert; Gerald Pinter

doi:10.1080/1023666x.2021.1968122

Morphological characterization of semi-crystalline POM using nanoindentation

Petra Christöfl^*, Caterina Czibula, Tristan Seidlhofer, Michael Berer, Astrid Macher, Eric Helfer, Theresia Schrank, Gernot Oreski, Christian Teichert, Gerald Pinter

^*Corresponding author for this work

Institute of Bioproducts and Paper Technology (6610)

Research output: Contribution to journal › Article › peer-review

Abstract

Nanoindentation (NI) is a contact method to investigate localized micromechanical properties of materials, whereby NI of semi-crystalline polymers is challenging. The influence of morphological structures such as spherulites or crystal-lamellae on localized NI depth-force behavior is discussed controversially in literature. Hence, the main objective of this study is to determine the influence of crystalline zones on NI results.

Polyoxymethylene (POM) exhibits high crystallinity with the spherulitic structure on the micrometer scale and was therefore chosen to proof the influence of spherulite distribution on NI results concerning modulus. Furthermore, the correspondence between the mean elastic modulus from different NI experiments and macroscopic compression tests will be demonstrated.

A POM tensile bar was investigated by NI with a large sphero-conical and a Berkovich indenter tip at different positions of its cross-section. Here, it was found that regions at the edge of the sample have a lower elastic modulus than regions in the middle of the cross-section. This agrees well with polarized light microscopy results, which reveal a skin layer with less crystallinity close to the sample edge. Therefore, the NI measurements in this edge zone result in a lower elastic modulus compared to the more crystalline middle of the cross-section.

In summary, semi-crystallinity influences the NI results obtained for POM and the mean of the elastic modulus distribution over the cross-section of the POM sample is in good agreement with macroscopic compression test results

Original language	English
Pages (from-to)	692-706
Number of pages	15
Journal	International Journal of Polymer Analysis and Characterization
Volume	26
Issue number	8
DOIs	https://doi.org/10.1080/1023666x.2021.1968122
Publication status	Published - 2 Sept 2021

Keywords

atomic force microscopy
creep
Nanoindentation
polyoxymethylene
semi-crystalline polymer

ASJC Scopus subject areas

Analytical Chemistry
Chemical Engineering(all)
Polymers and Plastics

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10.1080/1023666x.2021.1968122

Cite this

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title = "Morphological characterization of semi-crystalline POM using nanoindentation",

abstract = "Nanoindentation (NI) is a contact method to investigate localized micromechanical properties of materials, whereby NI of semi-crystalline polymers is challenging. The influence of morphological structures such as spherulites or crystal-lamellae on localized NI depth-force behavior is discussed controversially in literature. Hence, the main objective of this study is to determine the influence of crystalline zones on NI results.Polyoxymethylene (POM) exhibits high crystallinity with the spherulitic structure on the micrometer scale and was therefore chosen to proof the influence of spherulite distribution on NI results concerning modulus. Furthermore, the correspondence between the mean elastic modulus from different NI experiments and macroscopic compression tests will be demonstrated.A POM tensile bar was investigated by NI with a large sphero-conical and a Berkovich indenter tip at different positions of its cross-section. Here, it was found that regions at the edge of the sample have a lower elastic modulus than regions in the middle of the cross-section. This agrees well with polarized light microscopy results, which reveal a skin layer with less crystallinity close to the sample edge. Therefore, the NI measurements in this edge zone result in a lower elastic modulus compared to the more crystalline middle of the cross-section.In summary, semi-crystallinity influences the NI results obtained for POM and the mean of the elastic modulus distribution over the cross-section of the POM sample is in good agreement with macroscopic compression test results",

keywords = "atomic force microscopy, creep, Nanoindentation, polyoxymethylene, semi-crystalline polymer",

author = "Petra Christ{\"o}fl and Caterina Czibula and Tristan Seidlhofer and Michael Berer and Astrid Macher and Eric Helfer and Theresia Schrank and Gernot Oreski and Christian Teichert and Gerald Pinter",

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doi = "10.1080/1023666x.2021.1968122",

language = "English",

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T1 - Morphological characterization of semi-crystalline POM using nanoindentation

AU - Christöfl, Petra

AU - Czibula, Caterina

AU - Seidlhofer, Tristan

AU - Berer, Michael

AU - Macher, Astrid

AU - Helfer, Eric

AU - Schrank, Theresia

AU - Oreski, Gernot

AU - Teichert, Christian

AU - Pinter, Gerald

PY - 2021/9/2

Y1 - 2021/9/2

N2 - Nanoindentation (NI) is a contact method to investigate localized micromechanical properties of materials, whereby NI of semi-crystalline polymers is challenging. The influence of morphological structures such as spherulites or crystal-lamellae on localized NI depth-force behavior is discussed controversially in literature. Hence, the main objective of this study is to determine the influence of crystalline zones on NI results.Polyoxymethylene (POM) exhibits high crystallinity with the spherulitic structure on the micrometer scale and was therefore chosen to proof the influence of spherulite distribution on NI results concerning modulus. Furthermore, the correspondence between the mean elastic modulus from different NI experiments and macroscopic compression tests will be demonstrated.A POM tensile bar was investigated by NI with a large sphero-conical and a Berkovich indenter tip at different positions of its cross-section. Here, it was found that regions at the edge of the sample have a lower elastic modulus than regions in the middle of the cross-section. This agrees well with polarized light microscopy results, which reveal a skin layer with less crystallinity close to the sample edge. Therefore, the NI measurements in this edge zone result in a lower elastic modulus compared to the more crystalline middle of the cross-section.In summary, semi-crystallinity influences the NI results obtained for POM and the mean of the elastic modulus distribution over the cross-section of the POM sample is in good agreement with macroscopic compression test results

AB - Nanoindentation (NI) is a contact method to investigate localized micromechanical properties of materials, whereby NI of semi-crystalline polymers is challenging. The influence of morphological structures such as spherulites or crystal-lamellae on localized NI depth-force behavior is discussed controversially in literature. Hence, the main objective of this study is to determine the influence of crystalline zones on NI results.Polyoxymethylene (POM) exhibits high crystallinity with the spherulitic structure on the micrometer scale and was therefore chosen to proof the influence of spherulite distribution on NI results concerning modulus. Furthermore, the correspondence between the mean elastic modulus from different NI experiments and macroscopic compression tests will be demonstrated.A POM tensile bar was investigated by NI with a large sphero-conical and a Berkovich indenter tip at different positions of its cross-section. Here, it was found that regions at the edge of the sample have a lower elastic modulus than regions in the middle of the cross-section. This agrees well with polarized light microscopy results, which reveal a skin layer with less crystallinity close to the sample edge. Therefore, the NI measurements in this edge zone result in a lower elastic modulus compared to the more crystalline middle of the cross-section.In summary, semi-crystallinity influences the NI results obtained for POM and the mean of the elastic modulus distribution over the cross-section of the POM sample is in good agreement with macroscopic compression test results

KW - atomic force microscopy

KW - creep

KW - Nanoindentation

KW - polyoxymethylene

KW - semi-crystalline polymer

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JO - International Journal of Polymer Analysis and Characterization

JF - International Journal of Polymer Analysis and Characterization

IS - 8

ER -

Morphological characterization of semi-crystalline POM using nanoindentation

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Morphological characterization of semi-crystalline POM using nanoindentation

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ASJC Scopus subject areas

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