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The rheology and mechanical properties of associating polymers (ionomers and hydrogen bonding polymers) is of particular interest in our research program. Due to the presence of reversible associations, these polymers exhibit many idiosyncrasies, rich chain dynamics and unique properties such as self-healing and adhesion. The main thrust of this program is to study their non-linear viscoelasticity and self-healing behaviour using novel rheo-mechanical techniques to explore their potentials in applications such as coatings, packaging, 3D printing, adhesion and blend compatibilization.
Non-Newtonian fluid mechanics is often distinguished from its Newtonian counterpart by the additional requirement that first a constitutive equation be specified as part of the problem statement and secondly a suitable wall boundary condition other than the no-slip be imposed as a necessary ingredient. The main thrust of this part of the research program is both a theoretical and an experimental study of diverse complex fluid-wall interfaces under flow.
The interplay between thermodynamics and rheology of polymer blends is of particular interest. During flow of polymer blends, there is a variety of phenomena that may take place such as shear induced mixing and de-mixing. These effects are dramatic as the homogeneous region in their (polymer blends) phase diagram may be shifted or enlarged by several degrees under flow. This part of the research program focuses on the rheological and thermodynamic behavior of polymer blends under flow (shear/extensional), the resulting morphology and its effects on the mechanical properties of final products.
The rheology and mechanical properties of associating polymers (ionomers and hydrogen bonding polymers) is of particular interest in our research program. Due to the presence of reversible associations, these polymers exhibit many idiosyncrasies, rich chain dynamics and unique properties such as self-healing and adhesion. The main thrust of this program is to study their non-linear viscoelasticity and self-healing behaviour using novel rheo-mechanical techniques to explore their potentials in applications such as coatings, packaging, 3D printing, adhesion and blend compatibilization.
Non-Newtonian fluid mechanics is often distinguished from its Newtonian counterpart by the additional requirement that first a constitutive equation be specified as part of the problem statement and secondly a suitable wall boundary condition other than the no-slip be imposed as a necessary ingredient. The main thrust of this part of the research program is both a theoretical and an experimental study of diverse complex fluid-wall interfaces under flow.
The interplay between thermodynamics and rheology of polymer blends is of particular interest. During flow of polymer blends, there is a variety of phenomena that may take place such as shear induced mixing and de-mixing. These effects are dramatic as the homogeneous region in their (polymer blends) phase diagram may be shifted or enlarged by several degrees under flow. This part of the research program focuses on the rheological and thermodynamic behavior of polymer blends under flow (shear/extensional), the resulting morphology and its effects on the mechanical properties of final products.
研究兴趣
论文共 333 篇作者统计合作学者相似作者
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Rheologica Actapp.1-14, (2024)
RSC Sustainabilityno. 5 (2024): 1543-1550
Michał Misiak,Paulina Latko-Durałek, Emilia Baldy,Paweł Durałek,Żaneta Górecka, Amir Malmir,Savvas G. Hatzikiriakos
Physics of Fluidsno. 3 (2024)
PHYSICS OF FLUIDSno. 11 (2023)
RHEOLOGICA ACTAno. 2-3 (2023): 145-156
JOURNAL OF NON-NEWTONIAN FLUID MECHANICS (2023)
COMPOSITES SCIENCE AND TECHNOLOGY (2023): 110010-110010
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#Papers: 335
#Citation: 11831
H-Index: 56
G-Index: 93
Sociability: 6
Diversity: 3
Activity: 97
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