AERODYNAMICS OF EPHEDRA TRIFURCA: I. POLLEN GRAIN VELOCITY FIELDS AROUND STEMS BEARING OVULES

The behavior of pollen grains within the airspace around Ephedra trifurca is described. Vectoral analyses of pollen grains moving around stems and ovules indicate a complex pattern of directional and magnitudinal changes in trajectories that can be related to the geometries of surfaces that obstruct airflow. Pollen grains, passing around cylindrical stems oriented normal to the direction of ambient airflow, are deflected in circumrotating non-laminar flow-patterns. Stems tilted downwind deflect pollen grains into trajectories along leeward surfaces of stems. These trajectories travel acropetally in a spiraling pattern and may intersect airflow patterns created around and by ovules. Computer analyses of pollen motion in the vicinity of ovules indicate that pollen vector-direction is highly canalized and directed toward micropyles. Within the immediate vicinity of micropyles, which produce pollination droplets, analyses indicate that the magnitudinal variance of pollen grain vectors is high (spanning three orders of magnitude). This variance coincides with dramatic changes in the local Reynolds numbers, resulting in a localized region around the micropyle in which neither viscous nor inertial forces predominate. Based on additional aerodynamics parameters (vector curl, vector-divergence, and vector curl-differential) it is shown that the region around the pollination-droplet is characteristically a “pollen sink” (pollen grains collect in this airspace) in which abrupt changes can occur in the angular momenta of airborne pollen grains. These aerodynamic analyses suggest that the morphology of ovules and the stems to which they are attached facilitates pollen capture by creating an aerodynamic “singularity” (= a unique region) around the pollination-droplet.