Climate extremes are on the rise. Impacts of extreme climate and weather events on ecosystem services and ultimately human well-being can be partially attenuated by the organismic, structural, and functional diversity of the affected land surface. However, the ongoing transformation of terrestrial ecosystems through intensified exploitation and management may put this buffering capacity at risk. Here, we summarise the evidence that reductions in biodiversity can destabilise the functioning of ecosystems facing climate extremes. We then explore if impaired ecosystem functioning could, in turn, exacerbate climate extremes. We argue that only a comprehensive approach, incorporating both ecological and hydrometeorological perspectives, enables to understand and predict the entire feedback system between altered biodiversity and climate extremes. This ambition, however, requires a reformulation of current research priorities to emphasise the bidirectional effects that link ecology and atmospheric processes.

PyroCb events are important sources of stratospheric aerosol. During the Australian forest fires in 2019/2020, such convective plumes transported quantities of smoke into the tropopause region comparable to those of a large volcanic eruption. In this study, we investigate the heat emission threshold at which forest-fire plumes transition into pyroCbs. We examine the sensitivity of the pyroCb to further changes in the total amount of heat released as well as to the latent to sensible heat flux ratio by performing idealized simulations with a regional high-resolution model. Our results show a pronounced bimodal behavior of the plumes with an abrupt onset of pyroCb formation when the sensible heat flux exceeds 50kW/m2. When a cloud is formed within the plume, the smoke injection height is mainly controlled by the sum of the sensible and latent heat flux, while the ratio between the two plays a subordinate role. Increasing either heat flux leads to an increase in the plume water content and temperature anomaly within the cloud. The strong differences below the cloud between plumes with equal total heat flux but different sensible heat-to-latent heat ratios are buffered by changes in the cloud base height. These results show the importance of accurate estimates of heat and moisture released by fires for predicting PyroCb development. Encouragingly, a reliable estimate of the total heat flux is sufficient to characterize the behavior of PyroCbs, reducing the need for detailed partitioning of sensible and latent heat.