Direct force measurements between negatively charged silica microparticles are carried out in suspensions of like-charged nanoparticles with the atomic force microscope (AFM). In agreement with previous studies, oscillatory force profiles are observed at larger separation distances. At smaller distances, however, soft and strongly repulsive forces are present. These forces are caused by double layer repulsion between the like-charged surfaces and can be quantitatively interpreted with the Poisson-Boltzmann (PB) model. However, the PB model must be adapted to a strongly asymmetric electrolyte to capture the non-exponential nature of these forces. Thereby, the nanoparticles are modeled as highly charged co-ions, while the counter ions are monovalent. This model permits to extract the effective charge of the nanoparticles, which is well comparable to the one obtained from electrophoresis. The PB model also explains the presence of a particle-free layer close to the interface.This dependence originates from the double layer repulsion between the nanoparticles, which forces them into a liquid-like structure. Equation ( 1) follows from geometrical considerations by identifying the wavelength with the spacing between nearest neighbors in a close-packed structure. The same scaling dependence was observed with X-rays or neutrons, in particular, with small angle scattering through the position of the structural peak in bulk suspensions 12,18 or with reflectivity near an isolated interface. 19,20 Similar oscillatory forces were also observed in concentrated polyelectrolyte [21][22][23][24] and micellar solutions. 25,26 While this similarity is not surprising for spherical micelles, an analogous structuring also occurs in polyelectrolyte solutions. In the latter case, the wavelength follows the scaling law given in eq.(1) only at lower concentrations. A similar scaling law remains applicable at higher concentrations, albeit with a different exponent. 23,27,28 Less information is available on double layer forces acting in these systems. In the standard experiments the nanoparticles and the planar (or quasi-planar) surfaces are negatively charged. Therefore, the presence of strongly repulsive double layer forces is expected too. Additional exponential repulsive forces were found recently in such systems, but these forces seem relatively weak. 29 In solutions of polyelectrolytes, strongly repulsive double layer forces were recently reported by some of us. 28 In the latter case, these forces were non-exponential, but compatible with predictions of Poisson-Boltzmann (PB) theory.Structuring and forces in colloidal suspensions of charged particles have also attracted much attention in the theoretical community. [30][31][32][33] Thereby, a more rigorous description beyond the PB theory was pursued, typically with computer simulations or integral equation theories. Some researchers have considered the so-called primitive model, where the macroions and counter ions are treated on equal footing. Another approach is to only treat the na...
