Catchment-Scale Changes in Runoff Dynamics Following Natural Flood Management Interventions

Julia L. A. Knapp, Anthony Jones, Sim M. Reaney, Ian Pattison, and Andrew Black

Natural Flood Management (NFM) interventions and nature-based solutions are increasingly advocated as sustainable flood-mitigation strategies, yet empirical evidence of their hydrological impact at the catchment scale remains limited. This study uses an ensemble approach to characterise runoff-response distributions, drawing on long-term observed data (2011–2023) from the Eddleston catchment in Scotland. Unlike event-focused approaches, this method synthesises system behaviour across diverse hydrometeorological conditions to identify “typical” responses under pre- and post-intervention states.

Results from a small headwater catchment (2.3 km²) reveal statistically significant changes in runoff dynamics, including a delay in peak timing and a reduction in peak height after the installation of a series of leaky barriers. Comparable patterns in a larger catchment (34 km²), within which this smaller headwater catchment is nested, indicate that NFM effects extend beyond headwater sub-catchments. Ensemble-based summaries further highlight the dominant role of antecedent wetness in runoff generation, while also indicating increased infiltration and reduced runoff coefficients under high-flow conditions post-NFM installation.

By integrating ensemble hydrograph separation and impulse-response analysis, this framework provides a transferable tool for assessing NFM effectiveness across multiple scales. Findings strengthen the evidence base for NFM design optimisation and policy integration, supporting long-term strategies for flood resilience.

How to cite: Knapp, J. L. A., Jones, A., Reaney, S. M., Pattison, I., and Black, A.: Catchment-Scale Changes in Runoff Dynamics Following Natural Flood Management Interventions, EGU General Assembly 2026, Vienna, Austria, 3–8 May 2026, EGU26-19814, https://doi.org/10.5194/egusphere-egu26-19814, 2026.