Institute of Physical Chemistry
Polish Academy of Sciences
address: Kasprzaka 44/52
01-224 Warsaw, Poland
tel.: +48 22 3432000
fax/tel.: +48 22 3433333, 6325276
Warsaw, 11 January 2012
Give support to repulsion, and you'll see attraction. We know why.
When two objects repel each other under the action of one force, we usually
expect that addition of another force, also repulsive one, will accelerate separation.
This intuitive view is, however, not always true. Researchers at the Institute
of Physical Chemistry of the Polish Academy of Sciences in Warsaw have managed
to explain surprising results of experiments with mixtures, where two repulsive
interactions have lead to a strong attraction.
The results of last year's experiments with mixtures carried out at the University of Stuttgart, Germany, were surprising for many researchers. In one of the systems studied, a repulsive force was acting between the system components. When a second repulsive force was introduced, an unexpected effect was observed: a strong attraction. This unusual result aroused interest of the theoreticians from the Institute of Physical Chemistry of the Polish Academy of Sciences (IPC PAS) in Warsaw. "Starting from the basics, we have developed a theoretical model of the system studied in Germany and successfully verified its predictions with experimental evidence. That's why we are able to explain, how superposition of two repulsive interactions transforms into attraction", says Prof. Alina Ciach from the IPC PAS.
The system modelled at the IPC PAS was a mixture of water and an oily organic liquid - lutidine. The mixture included also salt ions. The fluid was placed between two electrically charged walls, one hydrophilic, and another one hydrophobic.
Water is miscible with lutidine only in a certain temperature range. An interesting situation arises close to the critical temperature, where the system cannot "make a decision" if the components should mix or separate. "Under these conditions, the water layer at the hydrophilic wall becomes relatively thick, similarly as the oil layer at the hydrophobic wall. And as water and oil ‘dislike' each other, a force emerges to push the walls apart", explains Faezeh Pousaneh from Iran, a PhD student working at the IPC PAS under the International PhD Projects Programme of the Foundation for Polish Science.
The unusual behaviour of the modelled system was revealed after electric charge of the same sign was applied to both walls. A second, electrostatic, repulsion was acting then between the walls, and even so the walls were becoming attractive! "Paper and pencils were set in motion. Using purely analytical calculations, together with Faezeh, we derived specific formulae to describe the course of the phenomenon", says Prof. Ciach.
It turned out that the key element of the model was the assumption that the ions in solution move exclusively in water, while avoiding lutidine. The walls of the system under study were electrically charged, so they attracted ions. "But there is lutidine layer at the hydrophobic wall!", notices Pousaneh. "So an ion faces a dilemma: it wants to get to the wall, but the access is protected by lutidine. And the hurdle can be taken in one way only: by pulling water". As a result of the process described above, the wall surface, earlier hydrophobic, starts to behave like a hydrophilic one, becoming similar in that respect to the other wall. And two hydrophilic walls attract each other.
The team from the IPC PAS intends to continue the research on variants of the modelled systems. "Interactions similar to those described by us occur between charged colloidal particles with selective surfaces. Depending on temperature, the interactions are sometimes repulsive, sometimes attractive", says Prof. Ciach. It turns out that in a narrow temperature range, the potential has a minimum for certain distance between the particles, so it is similar to that one being responsible for arrangement of atoms in nodes of the crystal lattice. "Thus, by controlling temperature we will be able to force a colloid to develop a specific structure. Then it can be preserved and used, for instance in material engineering", stresses Prof. Ciach.
The research has been completed under the International PhD Projects Programme of the Foundation for Polish Science and co-funded from the Innovative Economy Operational Programme of the European Union.
This press release was prepared thanks to the NOBLESSE grant under the activity "Research potential" of the 7th Framework Programme of the European Union.
The Institute of Physical Chemistry of the Polish Academy of Sciences (http://www.ichf.edu.pl/) was established in 1955 as one of the first chemical institutes of the PAS. The Institute's scientific profile is strongly related to the newest global trends in the development of physical chemistry and chemical physics. Scientific research is conducted in nine scientific departments. CHEMIPAN R&D Laboratories, operating as part of the Institute, implement, produce and commercialise specialist chemicals to be used, in particular, in agriculture and pharmaceutical industry. The Institute publishes approximately 200 original research papers annually.
Prof. Alina Ciach
Institute of Physical Chemistry of the Polish Academy of Sciences
tel. +48 22 3433247
Website of the Institute of Physical Chemistry of the Polish Academy of Sciences.
Press releases of the Institute of Physical Chemistry of the PAS.
IChF120111b_fot01s.jpg HR: http://ichf.edu.pl/press/2012/01/IChF120111b_fot01.jpg
Faezeh Pousaneh, a PhD student from the Institute of Physical Chemistry of the PAS in Warsaw with a "kitchen-like" version of the mixture under study. The fruits symbolize colloid particles, white grains - water, dark - lutidine, red - water-preferring ions. (Source: IPC PAS, Grzegorz Krzyżewski)