High resolution nanoscale chemical analysis of bitumen surface microstructures

High resolution nanoscale chemical analysis of bitumen surface microstructures

Abstract Surface microstructures of bitumen are key sites in atmospheric photo-oxidation leading to changes in the mechanical properties and finally resulting in cracking and rutting of the material. Investigations at the nanoscale remain challenging. Conventional combination of optical microscopy a...

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Main Authors: Ayse N. Koyun, Julia Zakel, Sven Kayser, Hartmut Stadler, Frank N. Keutsch, Hinrich Grothe
Format: Article
Language:English
Published: Nature Publishing Group 2021-06-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-021-92835-3
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spelling doaj-6c663787ca564760bb4bdec1ca6d79fa2021-07-04T11:26:44ZengNature Publishing GroupScientific Reports2045-23222021-06-011111910.1038/s41598-021-92835-3High resolution nanoscale chemical analysis of bitumen surface microstructuresAyse N. Koyun0Julia Zakel1Sven Kayser2Hartmut Stadler3Frank N. Keutsch4Hinrich Grothe5Christian Doppler Laboratory for Chemo-Mechanical Analysis of Bituminous Materials, Institute of Materials Chemistry, TU WienIONTOF GmbHIONTOF GmbHBruker Nano-Surfaces DivisionJohn A. Paulson School of Engineering and Applied Sciences, Harvard UniversityChristian Doppler Laboratory for Chemo-Mechanical Analysis of Bituminous Materials, Institute of Materials Chemistry, TU WienAbstract Surface microstructures of bitumen are key sites in atmospheric photo-oxidation leading to changes in the mechanical properties and finally resulting in cracking and rutting of the material. Investigations at the nanoscale remain challenging. Conventional combination of optical microscopy and spectroscopy cannot resolve the submicrostructures due to the Abbe restriction. For the first time, we report here respective surface domains, namely catana, peri and para phases, correlated to distinct molecules using combinations of atomic force microscopy with infrared spectroscopy and with correlative time of flight—secondary ion mass spectrometry. Chemical heterogeneities on the surface lead to selective oxidation due to their varying susceptibility to photo-oxidation. It was found, that highly oxidized compounds, are preferentially situated in the para phase, which are mainly asphaltenes, emphasising their high oxidizability. This is an impressive example how chemical visualization allows elucidation of the submicrostructures and explains their response to reactive oxygen species from the atmosphere.https://doi.org/10.1038/s41598-021-92835-3
collection DOAJ
language English
format Article
sources DOAJ
author Ayse N. Koyun
Julia Zakel
Sven Kayser
Hartmut Stadler
Frank N. Keutsch
Hinrich Grothe
spellingShingle Ayse N. Koyun
Julia Zakel
Sven Kayser
Hartmut Stadler
Frank N. Keutsch
Hinrich Grothe
High resolution nanoscale chemical analysis of bitumen surface microstructures
Scientific Reports
author_facet Ayse N. Koyun
Julia Zakel
Sven Kayser
Hartmut Stadler
Frank N. Keutsch
Hinrich Grothe
author_sort Ayse N. Koyun
title High resolution nanoscale chemical analysis of bitumen surface microstructures
title_short High resolution nanoscale chemical analysis of bitumen surface microstructures
title_full High resolution nanoscale chemical analysis of bitumen surface microstructures
title_fullStr High resolution nanoscale chemical analysis of bitumen surface microstructures
title_full_unstemmed High resolution nanoscale chemical analysis of bitumen surface microstructures
title_sort high resolution nanoscale chemical analysis of bitumen surface microstructures
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2021-06-01
description Abstract Surface microstructures of bitumen are key sites in atmospheric photo-oxidation leading to changes in the mechanical properties and finally resulting in cracking and rutting of the material. Investigations at the nanoscale remain challenging. Conventional combination of optical microscopy and spectroscopy cannot resolve the submicrostructures due to the Abbe restriction. For the first time, we report here respective surface domains, namely catana, peri and para phases, correlated to distinct molecules using combinations of atomic force microscopy with infrared spectroscopy and with correlative time of flight—secondary ion mass spectrometry. Chemical heterogeneities on the surface lead to selective oxidation due to their varying susceptibility to photo-oxidation. It was found, that highly oxidized compounds, are preferentially situated in the para phase, which are mainly asphaltenes, emphasising their high oxidizability. This is an impressive example how chemical visualization allows elucidation of the submicrostructures and explains their response to reactive oxygen species from the atmosphere.
url https://doi.org/10.1038/s41598-021-92835-3
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