This is the final version. Available from Wiley via the DOI in this record.The stability of consumer–resource systems can depend on the form of feeding interactions (i.e.functional responses). Size-based models predict interactions–and thus stability–based on con-sumer–resource size ratios. However, little is known about how interaction contexts (e.g. simpleor complex habitats) might alter scaling relationships. Addressing this, we experimentally mea-sured interactions between a large size range of aquatic predators (4–6400 mg over 1347 feedingtrials) and an invasive prey that transitions among habitats: from the water column (3D interac-tions) to simple and complex benthic substrates (2D interactions). Simple and complex substratesmediated successive reductions in capture rates–particularly around the unimodal optimum–and promoted prey population stability in model simulations. Many real consumer–resource sys-tems transition between 2D and 3D interactions, and along complexity gradients. Thus, Context-Dependent Scaling (CDS) of feeding interactions could represent an unrecognised aspect of foodwebs, and quantifying the extent of CDS might enhance predictive ecology
