The volatile organic compound isoprene is produced by many plant species, and provides protection against biotic and abiotic stresses¹. Globally, isoprene emissions from plants are estimated to far exceed anthropogenic emissions of volatile organic compounds². Once in the atmosphere, isoprene reacts rapidly with hydroxyl radicals³ to form peroxy radicals, which can react with nitrogen oxides to form ground-level ozone⁴. Here, we use canopy-scale measurements of isoprene fluxes from two tropical ecosystems in Malaysia-a rainforest and an oil palm plantation-and three models of atmospheric chemistry to explore the effects of isoprene fluxes on ground-level ozone. We show that isoprene emissions in these ecosystems are under circadian control on the canopy scale, particularly in the oil palm plantation. As a result, these ecosystems emit less isoprene than present emissions models predict. Using local-, regional- and global-scale models of atmospheric chemistry and transport, we show that accounting for circadian control of isoprene emissions brings model predictions of ground-level ozone into better agreement with measurements, especially in isoprene-sensitive regions of the world.