Abstract
Following our previous investigations on the electrofreezing mechanism of supercooled water on pyroelectric crystal surfaces, we discovered that electrofreezing is a process involving the attraction and arrangement of specific ionic charges by an electric field. We found two classes of ions: the trigonal planar ions that raise the icing temperature, or “ice-makers”, and ions of different structures that reduce the icing temperature, or “ice-breakers”. In the search for more efficient promoters for electrofreezing, we anticipated that molecules that have the propensity to self-assemble with water to form hexagonal clusters might be better ice nucleators. Through icing experiments performed directly on the hemihedral faces of pyroelectric crystals of LiTaO3, we found that ions of biguanide elevate the icing temperature of supercooled water when concentrated near the negatively charged crystal’s interfacial water layer, either upon cooling or upon heating. On the other hand, the analogous guanylurea ions, which presumably assume configurations with deviations from planarity, operate as “ice-breakers”.
Highlights
Following our previous investigations on the electrofreezing mechanism of supercooled water on pyroelectric crystal surfaces, we discovered that electrofreezing is a process involving the attraction and arrangement of specific ionic charges by an electric field
In 1861, Dufour reported that the icing temperature of supercooled water (SCW) could be influenced by the application of an electric field.[2]
Some reports deny the existence of the effect,[3,4] whereas others maintain that electric fields can either reduce or elevate the icing temperature of SCW.[5−10] In order to gain additional insight into the electrofreezing mechanism, in particular, to disentangle electric and geometric effects, we capitalized on the unique properties of polar crystals.[11−16] Such crystals exhibit pyroelectricity, the derivative of the spontaneous polarization with temperature, and develop positive and negative charges at opposite hemihedral surfaces during a temperature change
Summary
Following our previous investigations on the electrofreezing mechanism of supercooled water on pyroelectric crystal surfaces, we discovered that electrofreezing is a process involving the attraction and arrangement of specific ionic charges by an electric field. These results suggested that other ions, when attracted at the corresponding charged hemihedral faces upon cooling, should either elevate or reduce the icing temperature of SCW.
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