Title: A computational fluid dynamics study of 'clap and fling' in the smallest flying insects. Abstract: Tiny flying insects augment the lift forces generated during flapping flight by clapping their wings together at the beginning of each downstroke. This behavior has been termed 'clap and fling' or 'clap and peel.' The fluid dynamic process through which additional lift is generated has been termed the Weis-Fogh mechanism. At the beginning of the downstroke, the wings initially fling apart by rotating about the common trailing edge. During this rotation, large attached leading edge vortices form on each wing, and the leading edge vortex of one wing acts as the starting vortex of the other wing. Since these vortices are mirror images of each other, the circulation about the pair of wings remains zero. As a result, trailing edge vortices are not needed to conserve circulation, and indeed they are not initially formed. This is significant because both leading and trailing edge vortices are formed by a single wing in pure translation, resulting in smaller lift forces. In this study, the immersed boundary method was used to solve the two-dimensional Navier-Stokes equations with two immersed wings performing an idealized clap and fling stroke. Lift coefficients were calculated as functions of time per wing for a range of Reynolds numbers (8 - 128). These results show that lift generation per wing during the clap and fling of two wings when compared to the average lift produced by one wing with the same motion falls into two distinct patterns. For Reynolds numbers of 64 and higher, lift is initially enhanced during the rotation of two wings when lift coefficients are compared to the case of one wing. Lift coefficients after fling and during the translational part of the stroke oscillate as the leading and trailing edge vortices are alternately shed, and are not substantially greater than the one-winged case. For Reynolds numbers of 32 and lower, lift coefficients per wing are also enhanced during wing rotation when compared to the case of one wing rotating with the same motion. Remarkably, lift coefficients following two-winged fling during the translational phase are also enhanced when compared to the one-winged case. Indeed, they begin about 70% higher than the one-winged case during pure translation. Lift enhancement also increases with decreasing Reynolds number, suggesting that the Weis-Fogh mechanism of lift generation has greater benefit to insects flying at lower Reynolds numbers. Indeed, it appears that all insects that fly at very low Reynolds numbers use clap and fling, while the majority of flying insects do not.