Until now, the microscopic details of this process have remained unclear. Using high-resolution microscopy and computer simulations, researchers at TU Wien have investigated how silver iodide interacts with water at the atomic scale. Their findings reveal that silver iodide exposes two fundamentally different surfaces, but only one of them promotes ice nucleation. The discovery deepens our understanding of how clouds form rain and snow and may guide the design of improved materials for inducing precipitation.
"The distances between atoms also closely match those in ice crystals. For a long time, the structural similarity was believed to explain why silver iodide is such an effective nucleus for ice formation. A closer examination, however, reveals a more complex mechanism."
The atomic structure of the surface where ice nucleation occurs differs from that inside the crystal. When a silver iodide crystal is cleaved, silver atoms terminate one side and iodine atoms the other.
"We found that the silver-terminated and iodine-terminated surfaces both reconstruct, but in completely different ways," says Johanna Hutner, who performed the experiments. The silver-terminated surface retains a hexagonal arrangement that provides an ideal template for the growth of an ice layer, whereas the iodine-terminated surface reconstructs into a rectangular pattern that no longer matches the sixfold symmetry of ice crystals.
"Only the silver-terminated surface contributes to the nucleation effect," explains Balajka. "The ability of silver iodide to trigger ice formation in clouds cannot be explained solely by its bulk crystal structure. The decisive factor is the atomic-scale rearrangement at the surface, an effect that had been completely overlooked until now."
"One of the challenges was that all experiments had to be performed in complete darkness," explains Johanna Hutner. "Silver iodide is highly light-sensitive, a property that once made it useful in photographic plates and films. We only used red light occasionally when handling the samples inside the vacuum chamber."
In parallel, the team simulated the surfaces and the water structures covering them using density functional theory, an advanced computational method for quantum mechanical modeling of atomic-scale interactions.
"These simulations allowed us to determine which atomic arrangements are energetically most stable," explains Andrea Conti, who performed the calculations. "By accurately modeling the silver iodide-water interface, we could observe how the very first water molecules organize on the surface to form an ice layer."
"It is remarkable that for so long, we relied on a rather vague, phenomenological explanation of silver iodide's nucleation behavior," says Ulrike Diebold, head of the Surface Physics Group at TU Wien, where the study was conducted. "Ice nucleation is a phenomenon of central importance for atmospheric physics, and the atomic-scale understanding provides a foundation for evaluating whether other materials could serve as effective nucleation agents."
Research Report:Surface reconstructions govern ice nucleation on silver iodide
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