Dr. Maarten Biesheuvel is principal scientist at Wetsus, European Centre for Sustainable Water Technology, The Netherlands. He is the author of two textbooks on electrochemical processes and 160 scientific publications in the field of the theory of transport processes and physical chemistry, including theory for capacitive deionization, electrodialysis, and reverse osmosis. He is in editorial board member of the journals Desalination and J. Membrane Science Letters. He is regularly invited to give tutorial lectures on transport theory and chemical equilibrium, specifically on reverse osmosis and electrodialysis, as well as on the history of theory for activity coefficients of ions. Other highly acclaimed tutorial lectures provide students (BSc to PhD level) with useful insights in data analysis and graphical presentations of data.
Abstract
Fundamental aspects of the solution-friction model for ion and water transport in membranes
The solution-friction model is the state-of-the-art transport model for reverse osmosis, nanofiltration, and electrodialysis. To underpin and extend this broadly applicable theory in the most precise and effective manner, we discuss the latest developments in three fundamental topics of importance to mass transport modeling in solutions and membranes.
Firstly, we discuss activity coefficients in solution and membranes, related to the ion-ion Coulombic forces that underpin it which for a 1:1 salt leads to a cube-root dependence on salt concentration. We discuss how to implement these activity effect in a membrane model.
Secondly, we discuss the basics of the Soret effect which describes how ions move in a temperature gradient, which sometimes is to lower, and sometimes to higher temperatures. The existence of such a change in sign is one of the outstanding puzzles in the field of physical chemistry. Temperature effects are of great importance in membrane technology because we may attempt to use them for cheaper desalination.
Thirdly, we discuss how the simple Flory-Rehner theory for polymer expansion and compaction can be improved to include finite stretching of the polymer network (of which most membranes are made), charge efects, and how flow of water through a membrane leads to compaction, the more so at the low-pressure side.