Abstract
Fine-tuning the interactions between particles can allow one to steer their collective behaviour and structure. A convenient way to achieve this is to use solvent criticality to control attraction, via critical Casimir forces, and to control repulsion via the Debye screening of electrostatic interactions. Herein, we develop a multiscale simulation framework and a method for controlled deposition of quantum dots to investigate how these interactions affect the structure of charged nanoparticles deposited on a substrate, altogether immersed in a binary liquid mixture intermixed with salt. We consider nanoparticles and substrates favouring the same component of the mixture and find that the critical Casimir interactions between the nanoparticles become drastically reduced at the substrate. In particular, the interactions can become a few kBT weaker and their decay length a few orders of magnitude smaller than in the bulk. At off-critical compositions, the decay length increases upon approaching criticality, as expected, but the interaction strength decreases. With molecular dynamics simulations and experiments, we reveal that the nanoparticles can self-assemble into crystalline clusters which form superstructures resembling cluster fluids and spinodal morphology. The simulations additionally predict the formation of fractal-like nanoparticle gels and bicontinuous phases. Our results demonstrate that charged nanoparticles in a salty binary liquid mixture provide exciting opportunities to study the formation of complex structures experimentally and theoretically, which may lead to applications in optoelectronics and photonics.
Highlights
The ability to tune the interactions between particles provides a means to control their collective behaviour and structure
Critical Casimir forces are attractive for identical particles, and their range and strength can be tuned by changing the composition of the fluid or by varying temperature.[13]
We have developed an experimental method and a multiscale simulation framework to study the behaviour of charged hydrophilic nanoparticles deposited on hydrophilic substrates, immersed in a near-critical binary liquid mixture intermixed with salt
Summary
Another way to control interactions among particles is through immersion in a near-critical fluid. With increasing λD, i.e., with reducing the salt concentration, a small energy barrier develops in the interaction potential, which impedes the nanoparticles from coming close to each other This breaks the hexagonal order and we observe the growth of spinodal-like structures, characterized by smaller cluster sizes and lower values of the hexatic order parameter (Fig. 4d and e). This is again in agreement with the simulations (Fig. 4), confirming experimentally the coarsening of the spinodal structures and demonstrating the control offered by the critical Casimir interactions over the deposited nanoparticle structures. For nanoparticles with magnetic cores, the repulsion can be controlled with an external magnetic field,[63,64] which may provide a convenient way to steer the structural transformations without the need to change an experimental setup
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