The Platonic Ideal of Stalactite Growth Raymond Goldstein Physics Department University of Arizona As far back in recorded history as the writings of the Elder Pliny in the first century A.D. are found references to the fascinating structures found in limestone caves, particularly stalactites. Although the subject of continuing inquiry since that time, the chemical mechanisms responsible for growth have only been well-established since the 19th century, and there has been no quantitative understanding of the morphological evolution of these strange and beautiful forms. In this talk I will describe a synthesis of calcium carbonate chemistry, diffusion, thin-film fluid dynamics, and nonlinear dynamics which shows that stalactites evolve according to a novel local geometric growth law which exhibits extreme amplification at the tip. Studies of this model show that a broad class of initial conditions is attracted to an ideal parameter-free shape, not previously known in science, which is strikingly close to a statistical average of natural stalactites. These results highlight a larger set of important problems in physics, chemistry, and geophysics involving pattern formation by precipitation. As an example, I will present a laboratory experiment involving tubular precipitation around a fluid jet and discuss some interesting scaling laws that emerge.