Spatial environmental heterogeneity is widely assumed to enhance ecological stability by promoting refugia, biodiversity, and asynchrony. Yet, we lack field experiments testing this fundamental relationship and its underlying mechanisms in naturally-assembled multitrophic systems. To address this gap, we monitored experimental substrates replicating topographic heterogeneity on a rocky shore over three years. Contrary to theory, heterogeneity showed no net effect on community stability due to four counteracting pathways. Heterogeneity increased stability by i) providing refugia that enhanced population stability and ii) boosting species richness, which promoted asynchrony. At the same time, it decreased stability by iii) reducing a dominant non-native species and iv) suppressing consumers, both of which otherwise stabilised community composition. These opposing processes cancelled out the heterogeneity-stability relationship, highlighting the complex and multi-causal nature of this relationship. We caution against the assumption that increasing heterogeneity universally enhances stability, particularly in systems with strong consumer interactions and dominant species.

Topographic heterogeneity sets the stage for community assembly, but its effects on ecosystem functioning remain poorly understood. Here we test the hypothesis that heterogeneity underpins multiple cascading pathways that indirectly control multifunctionality. To do so, we combined experimental manipulation of topographic heterogeneity on rocky shores with comprehensive assessment of naturally assembled communities and multifunctionality. Structural equation modelling revealed that heterogeneity: i) enhanced biodiversity by supporting filter feeder richness; ii) triggered a facilitation cascade via reef-forming (polycheate) and biomass-dominant (macroalga) foundation species, which in turn broadly supported functionally diverse epibiotic and understory assemblages; and iii) inhibited a key consumer (limpet). These mechanisms exerted complementary positive effects on individual functions (e.g., water filtration, ecosystem metabolism, nutrient uptake) and, in turn, collectively enhanced multifunctionality. Topographic heterogeneity may therefore serve as a cornerstone physical attribute by initiating multiple cascades that propagate through ecological communities via foundation species, ultimately manifesting disproportionate effects on ecosystem multifunctionality.