AI Article Synopsis
- Scientists are studying tiny magnetic particles that can move in two dimensions to see how they group together and change shape when things get hotter or more chaotic.
- They look at how many groups of particles form, how big these groups are, and what happens to the leftover particles that don’t group up.
- They discovered that when the particles get more disordered, it helps create a special state called the hexatic phase, where the particles have a mix of solid and liquid-like behaviors.
Article Abstract
Using both video microscopy of superparamagnetic colloidal particles confined in two dimensions and corresponding computer simulations of repulsive parallel dipoles, we study the formation of fluctuating orientational clusters and topological defects in the context of the KTHNY-like melting scenario under quenched disorder. We analyze cluster densities, average cluster sizes, and the population of noncluster particles, as well as the development of defects, as a function of the system temperature and disorder strength. In addition, the probability distribution of clustering and orientational order is presented. We find that the well-known disorder-induced widening of the hexatic phase can be traced back to the distinct development characteristics of clusters and defects along the melting transitions from the solid phase to the hexatic phase to the isotropic fluid.
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| http://dx.doi.org/10.1103/PhysRevE.88.062305 | DOI Listing |
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