Brüning, Karsten.
In-situ Structure Characterization of Elastomers during Deformation and Fracture [electronic resource] / by Karsten Brüning. - XIV, 124 p. 82 illus., 51 illus. in color. online resource. - Springer Theses, Recognizing Outstanding Ph.D. Research, 2190-5053 . - Springer Theses, Recognizing Outstanding Ph.D. Research, .
Introduction -- Motivation and Objectives -- Experimental -- Results -- Conclusion and Outlook -- Appendix.
This thesis offers novel insights into the time-dependent structural evolution of polymers under deformation. In-situ tensile experiments at high-brilliance synchrotron sources allowed to characterize the material with unrivaled resolution in time and space. The strain-induced crystallization in natural rubber was studied by wide-angle X-ray diffraction. Special emphasis was put on the establishment of new structure-property relationships to give a more in-depth understanding of the mechanical performance of rubber parts, e.g. in tear fatigue loading. To this end, the kinetics of strain-induced crystallization were investigated, subjecting the material to high strain rates. The local structure around a crack tip was observed by scanning wide-angle X-ray diffraction. Ultra-small angle X-ray scattering served to study filled elastomers under deformation, from specially prepared model filler systems to industrially relevant carbon black filled rubbers. Other methods include electron microscopy coupled with in-situ tensile testing and optical dilatometry to examine cavitation in rubbers. The underlying theory as well as a literature review are covered by an extensive introductory chapter, followed by a description of the experimental techniques. The results are presented in more detail than in the original journal publications. .
9783319069074
10.1007/978-3-319-06907-4 doi
Chemistry.
Polymers.
Condensed matter.
Materials science.
Chemistry.
Polymer Sciences.
Condensed Matter Physics.
Characterization and Evaluation of Materials.
Ceramics, Glass, Composites, Natural Methods.
QD380-388
541.2254
In-situ Structure Characterization of Elastomers during Deformation and Fracture [electronic resource] / by Karsten Brüning. - XIV, 124 p. 82 illus., 51 illus. in color. online resource. - Springer Theses, Recognizing Outstanding Ph.D. Research, 2190-5053 . - Springer Theses, Recognizing Outstanding Ph.D. Research, .
Introduction -- Motivation and Objectives -- Experimental -- Results -- Conclusion and Outlook -- Appendix.
This thesis offers novel insights into the time-dependent structural evolution of polymers under deformation. In-situ tensile experiments at high-brilliance synchrotron sources allowed to characterize the material with unrivaled resolution in time and space. The strain-induced crystallization in natural rubber was studied by wide-angle X-ray diffraction. Special emphasis was put on the establishment of new structure-property relationships to give a more in-depth understanding of the mechanical performance of rubber parts, e.g. in tear fatigue loading. To this end, the kinetics of strain-induced crystallization were investigated, subjecting the material to high strain rates. The local structure around a crack tip was observed by scanning wide-angle X-ray diffraction. Ultra-small angle X-ray scattering served to study filled elastomers under deformation, from specially prepared model filler systems to industrially relevant carbon black filled rubbers. Other methods include electron microscopy coupled with in-situ tensile testing and optical dilatometry to examine cavitation in rubbers. The underlying theory as well as a literature review are covered by an extensive introductory chapter, followed by a description of the experimental techniques. The results are presented in more detail than in the original journal publications. .
9783319069074
10.1007/978-3-319-06907-4 doi
Chemistry.
Polymers.
Condensed matter.
Materials science.
Chemistry.
Polymer Sciences.
Condensed Matter Physics.
Characterization and Evaluation of Materials.
Ceramics, Glass, Composites, Natural Methods.
QD380-388
541.2254