HIGH-RESOLUTION STUDIES OF RAINFALL ON NORFOLK ISLAND, PART III - A MODEL FOR RAINFALL REDISTRIBUTION

A dense network of high resolution rain gauges has provided data on sp atial scales of about 1.5 km and time scales of 15 sec on Norfolk Isla nd, where the topography is dominated by a 300 m hill that is found to modify the spatial distribution of rainfall depending on wind directi on. A correlation method is used to track coherent storm motion so as to identify the dominant wind direction and speed. Transects are selec ted across the island in the wind direction and the rainfall interpola ted along each transect. It is found that there is often a decrease in rainfall upwind of the hill, followed by an increase downwind of the peak. The ratio of downwind to upwind catches increases linearly with wind speed. These observations do not accord with the often accepted e xplanation using a seeder-feeder mechanism. A simple wind drift model is proposed, in which raindrops follow trajectories modified by the pe rturbed wind flow over the hill. The transects are approximated by bel l-shaped hill profiles. Analytic solutions for potential flow over a c ylinder are then used to find a streamline with a bell shape similar t o a topography transect through the hill and aligned with the wind dir ection. This streamline is used as the solid surface boundary, thereby giving a direct analytic flow field for the bell-shaped hill. A strea mfunction is found for drop motion, allowing rainfall variations to be predicted. A parameterisation is developed that explains the shape an d magnitude of the observed rainfall variations along a transect. Agre ement between the rudimentary model and observations is found possible to within a few percent This indicates that the wind drift process is viable as the dominating mechanism for determining rainfall distribut ion in the presence of low hills when low level moisture is absent. (C ) 1998 Elsevier Science B.V. All rights reserved.