Structure and Mechanical Properties of Carbon- and Silica-based Nanomaterials

Publikationen: Thesis / Studienabschlussarbeiten und HabilitationsschriftenDissertation

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Structure and Mechanical Properties of Carbon- and Silica-based Nanomaterials. / Zickler, Gerald.
2006. 160 S.

Publikationen: Thesis / Studienabschlussarbeiten und HabilitationsschriftenDissertation

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@phdthesis{741fde00e2224cef9defdb91bed4fb74,
title = "Structure and Mechanical Properties of Carbon- and Silica-based Nanomaterials",
abstract = "Highly porous nanostructured materials face applications for separation techniques and catalysis. Their nanostructure substantially influences their mechanical properties and thus their potential as functional materials. The present thesis deals with the characterisation of porous carbon- and silica-based materials with complex structure at several levels of hierarchy. The aim is to contribute to a better understanding of porous nanomaterials produced by templating processes, and the correlation between structure and functions, especially their mechanical properties. In the first part, X-ray scattering techniques using synchrotron radiation as well as Raman spectroscopy and nanoindentation were used to study carbon-based materials made of pyrolysed wood. The results provided a general kinetics law for the thermal degradation of cellulose, and it was shown that the orientation of native cellulose and the developing graphene sheets of carbon were parallel to the axial direction of the wood cells. The changes of mechanical properties were correlated with the structural transformations due to thermal treatment. In the second part, in-situ synchrotron radiation investigations of sorption phenomena in mesoporous silica-based materials provided quantitative information of pore structure, liquid film formation and growth in confined geometry. Furthermore, it was shown that the pore walls deform reversibly due to capillary condensation.",
keywords = "Holz, Holzkohle, por{\"o}se Materialien, Pyrolyse, Mikrostruktur, R{\"o}ntgenstreuung, Raman Spektroskopie, Adsorption, Nanoh{\"a}rtemessung, wood, charcoal, porous materials, pyrolysis, microstructure, X-ray scattering, Raman spectroscopy, adsorption, nanoindentation",
author = "Gerald Zickler",
note = "no embargo",
year = "2006",
language = "English",

}

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TY - BOOK

T1 - Structure and Mechanical Properties of Carbon- and Silica-based Nanomaterials

AU - Zickler, Gerald

N1 - no embargo

PY - 2006

Y1 - 2006

N2 - Highly porous nanostructured materials face applications for separation techniques and catalysis. Their nanostructure substantially influences their mechanical properties and thus their potential as functional materials. The present thesis deals with the characterisation of porous carbon- and silica-based materials with complex structure at several levels of hierarchy. The aim is to contribute to a better understanding of porous nanomaterials produced by templating processes, and the correlation between structure and functions, especially their mechanical properties. In the first part, X-ray scattering techniques using synchrotron radiation as well as Raman spectroscopy and nanoindentation were used to study carbon-based materials made of pyrolysed wood. The results provided a general kinetics law for the thermal degradation of cellulose, and it was shown that the orientation of native cellulose and the developing graphene sheets of carbon were parallel to the axial direction of the wood cells. The changes of mechanical properties were correlated with the structural transformations due to thermal treatment. In the second part, in-situ synchrotron radiation investigations of sorption phenomena in mesoporous silica-based materials provided quantitative information of pore structure, liquid film formation and growth in confined geometry. Furthermore, it was shown that the pore walls deform reversibly due to capillary condensation.

AB - Highly porous nanostructured materials face applications for separation techniques and catalysis. Their nanostructure substantially influences their mechanical properties and thus their potential as functional materials. The present thesis deals with the characterisation of porous carbon- and silica-based materials with complex structure at several levels of hierarchy. The aim is to contribute to a better understanding of porous nanomaterials produced by templating processes, and the correlation between structure and functions, especially their mechanical properties. In the first part, X-ray scattering techniques using synchrotron radiation as well as Raman spectroscopy and nanoindentation were used to study carbon-based materials made of pyrolysed wood. The results provided a general kinetics law for the thermal degradation of cellulose, and it was shown that the orientation of native cellulose and the developing graphene sheets of carbon were parallel to the axial direction of the wood cells. The changes of mechanical properties were correlated with the structural transformations due to thermal treatment. In the second part, in-situ synchrotron radiation investigations of sorption phenomena in mesoporous silica-based materials provided quantitative information of pore structure, liquid film formation and growth in confined geometry. Furthermore, it was shown that the pore walls deform reversibly due to capillary condensation.

KW - Holz

KW - Holzkohle

KW - poröse Materialien

KW - Pyrolyse

KW - Mikrostruktur

KW - Röntgenstreuung

KW - Raman Spektroskopie

KW - Adsorption

KW - Nanohärtemessung

KW - wood

KW - charcoal

KW - porous materials

KW - pyrolysis

KW - microstructure

KW - X-ray scattering

KW - Raman spectroscopy

KW - adsorption

KW - nanoindentation

M3 - Doctoral Thesis

ER -