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Posted: Oct 16th, 2012
Researchers introduce new theory for determination of interactions between neutral surfaces
(Nanowerk News) Theoretical physicist Ali Naji from the Institute for Research in Fundamental Sciences (IPM) in Tehran and the University of Cambridge, UK, and his colleagues showed in a research how small random patches of disordered and frozen electric charges can make a difference when they are scattered on surfaces that are overall neutral ("Sample-to-sample torque fluctuations in a system of coaxial randomly charged surfaces").
These charges induce a twisting force that is strong enough to be felt as far as nanometers or even micrometers away. These results could help to understand the phenomena that occur on surfaces such as those of large biological molecules.
To measure the strength of the twist that acts on a randomly charged surface, the authors used a sphere which was mounted like a spinning top next to a randomly charged flat substrate. Because small amounts of positive and negative charges were spread in a disordered mosaic throughout both surfaces, they induced transient attractive or repulsive twisting forces. This was regardless of the surfaces' overall electrical neutrality, thus making the sphere spin. Using statistical averaging methods, the authors studied the fluctuations of these forces.
The authors found that the twisting force, created by virtue of the disorder of surface charges, is expected to be much stronger and far-reaching than the remnant forces. The latter are always present, even in the absence of charge disorder, and are due to fluctuations at the atomic and molecular levels.
This could have implications for large randomly charged surfaces such as biological macromolecules, which may be exposed to strong electrostatic forces, inducing attraction and/or repulsion, even if they carry no overall net charge.
For instance, this phenomenon could partly explain biological pattern recognition, such as lock and key phenomena. In that context, the twisting force could explain the attraction between biological macromolecules that lead to pre-alignment prior to their interaction.
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