Among animals, insects represent the largest taxon in terms of biomass and biodiversity. They are involved in many important ecosystem processes including pollination and decomposition, both of which have great economic importance for humans8. Nevertheless, reports and studies on species loss largely focus on vertebrates9. In the last two decades, however, the number of studies reporting declines in insect populations and diversity has increased7, spurring an intense public debate4. Because many factors can influence insects and monocausal effects could seldom be identified, insect declines are often described as a ‘death by a thousand cuts’10.

A pivotal study, which received wide media coverage and triggered much of the continuing public and political debate about ‘insect declines’, reported that insect biomass in protected areas in Germany declined by more than 75% between 1989 and 2016 (ref. 1). Subsequent studies using systematic monitoring3 and national to global meta-analyses on insect biomass, abundances and diversity indicate a more complex pattern across realms, regions and taxa2,11. Most severe declines in terrestrial insect abundance were reported, for example, in Central Europe and the US Midwest, supporting the view that land use intensification is a main driver2. However, in a well-replicated study in Central Europe, no difference in insect biomass between intensive agricultural and seminatural environments could be found, despite reduced species richness, particularly for threatened species in agricultural environments12. Proposed drivers of insect declines in descending order of perceived importance are: (1) habitat loss and conversion to intensive agriculture and urbanization; (2) pollution, especially from synthetic pesticides and fertilizers; (3) biological factors, including pathogens and introduced species; and (4) climate change13. More recently climate change and its interaction with habitat loss has received more attention5,7.

Climate change is assumed to be especially important for changes in biodiversity in tropical and Mediterranean as well as in arctic and alpine regions5,6,7. Several new studies point to climate change as a potentially important driver of insect declines. In wet tropical forests, wet and dry extremes related to climate change have been shown to reduce arthropod biomass14. Similarly, declines in arthropod biomass in lowland rainforests of Puerto Rico between the 1970s and the 2010s have been proposed to be a result of climate change, with synchronous declines at higher trophic levels, including lizards, birds and frogs15. Yet further other explanations, especially habitat change due to disturbance or insufficient focus on temperature related aspects of weather16 may suggest our evidence for climate change effects on insects is incomplete. In the Arctic region, long-term data show that weather conditions during different periods of the year cause complex and nonlinear responses of arthropod abundance and biodiversity17. In their recent review, leading scientists expressed their concerns by summarizing the many reasons why climate change might be critical for insect populations7.

Most studies have analysed potential climate effects on insects only at a coarse scale, such as mean temperatures during the flight season of insects or during the winter season1,3,5. Insect populations, however, are influenced by temperature and precipitation at various stages during their life cycle and by means of different mechanisms7,18. For example, the number of eggs laid varies on the conditions experienced by females in the previous season, the survival of individuals depends on winter conditions and last weather conditions during spring and summer determine final insect densities. To understand the role of weather and climate change in insect population trends, more comprehensive studies are needed that include data on weather conditions relevant for different life stages of insects together with experiments disentangling confounding drivers to address the question of how climate is influencing insect biomass in the long term...

Boxplots depict the annual distribution of insect biomass in the individual samples in grams per day. The samples in the validation data (n = 761) were corrected for trap type (Methods). Note the log scale of the y axis and the overlap of training (2016t) and validation (2016v) data in 2016. Grey colours represent the data of the training dataset (n = 1,503); the different years of the validation data are depicted in colour. Horizontal dashed lines indicate the median in 1989 and the maximum value in the training data in 1994. The boxplots show the median, and the 25th and 75th percentiles; the whiskers show the minimum and maximum values not exceeding a distance of 1.5× the interquartile range; and the values beyond are plotted as single points.

Each dot represents one of 761 samples from 104 Malaise traps in the years 2016 to 2022. The x axis is based on the combination of model terms of sampling weather and weather anomaly variables in model 5 predicted for the new validation data (see Methods for details). This correlation is also robust if model 5 was used with year as random effect.