A model is presented that describes the coevolution of surface turbulent fluxes and new ice growth during the freezing of leads. The model includes a sophisticated parameterization of the surface sensible and latent heat fluxes. The new ice growth model distinguishes between the congelation and frazil regimes. During frazil growth, heat loss from the open water part of the lead results in formation of new ice which is advected to the downwind edge. With time, the ice edge extends to the upwind lead edge, and the lead is gradually covered with ice. Over the ice-covered portions, the turbulent heat loss results in ice consolidation, and thereafter ice growth occurs. The turbulent heat flux depends on the surface characteristics which vary across the lead surface during frazil growth. Therefore in the frazil regime, ice concentration, ice thickness, surface temperature, and the surface turbulent flux vary across the lead surface. Even after consolidation, frazil ice has a different surface roughness length from congelation ice for the same ice thickness up to an ice thickness of 10 cm. We have used this model to determine the evolution of surface turbulent heat fluxes under various atmospheric conditions and for different lead widths. In the frazil regime, there is a considerable fetch dependence of the surface characteristics, as the ice is advected to the downwind edge and slowly covers the entire lead. This fetch dependence is greatest for the higher wind speeds and larger lead widths. There is significantly higher ice production under conditions when frazil formation occurs because the ice transport to the downwind edge leaves the surface of the lead open, allowing the warmer sea surface to exchange heat with the atmosphere. The rapid growth rates result in large salt release to the ocean, with implications for ocean dynamics. We have done a sensitivity study to investigate the effect of oceanic heat flux at the underside of the ice, which results from the salt rejection upon ice formation in freezing leads, on the evolution of new ice and turbulent fluxes. ¿ 1998 American Geophysical Union