PhD theses

All Wageningen University PhD theses

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    Wageningen PhD theses


    This database contains bibliographic descriptions of all Wageningen University PhD theses from 1920 onwards. It is updated on a daily basis by WUR Library.

    Author abstracts and/or summaries are added to all descriptions. A link to the full text dissertation is added to the bibliographic description. In a few cases, no electronic version is available, mostly because of copyright issues.

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    mail icon WUR Library, 9 july 2012

     

Record number 2240738
Title Driven granular media : mixing, friction & activity
show extra info.
Marcel Jan Workamp
Author(s) Workamp, Marcel Jan (dissertant)
Publisher Wageningen : Wageningen University
Publication year 2018
Description 136 pages figures, diagrams
Description 1 online resource (PDF, 136 pages) figures, diagrams
Notes Includes bibliographical references. - With summaries in English and Dutch
ISBN 9789463437479; 9463437479
Tutors Gucht, Prof. dr. J. van der ; Dijksman, Dr. J.A.
Graduation date 2018-05-15
Dissertation no. 6927
Author abstract show abstract

Sand, coffee beans and mud all belong to a class of materials that we call granular media. Despite their relevance in industry and agriculture, the flow behaviour of these materials remains poorly understood. In particular, it is unclear how specific properties of the particles, governing the interactions at the microscopic level, influence the macroscopic flow response. In practice, it is often difficult to vary particle properties, such as stiffness or friction coefficient, in a controlled way. In this thesis, we investigate flows of granular materials with well-defined particle properties, by synthesizing the particles using novel methods. In Part I of the thesis, we investigate the role of friction in shear flows of granular suspensions. We present a method to produce millimetre-sized hydrogel particles, and investigate how the chemistry of the hydrogels affects the material friction coefficient, and subsequently determine how this relates to macroscopic flow behaviour. In Part II of the thesis, we study granular materials in systems where they are not driven by the walls, but rather from within the material. We study how passive particles driven by a single magnet can aid mixing in a microfluidic mixing chip. We also take care that the pressure drop, which limits the simple use of microfluidic chips, is greatly reduced compared to commercially available solutions. Finally, we investigate the role of geometric friction in a granular material in which each particle is individually driven to rotate. The activity of these 3D-printed particles, combined with frictional coupling of rotational and translational degrees of freedom, leads to the emergence of a granular material that displays collective behaviour. The thesis is concluded with a general discussion.

Online Embargo on full text. Full text available from 2019-05-15
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Publication type PhD thesis
Language English
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