Citation

Stucki P, Bandhauer M, Heikkilä U, Rössler O, Zappa M, Pfister L, Salvisberg M, Froidevaux P, Martius O, Panziera L, Brönnimann S. Nat. Hazards Earth Syst. Sci. Discuss. 2018; 2018: 1-28.

Copyright

(Copyright © 2018, European Geosciences Union, Publisher Copernicus Publications)

DOI

10.5194/nhess-2018-134

PMID

unavailable

Abstract

Heavy precipitation on the south side of the central Alps produced a catastrophic flood in October 1868. We assess the damage and societal impacts, as well as the atmospheric and hydrological drivers using documentary evidence, observations, and novel numerical weather and runoff simulations. The greatest damage was concentrated close to the Alpine divide and Lago Maggiore. An atmospheric reanalysis emphasizes the repeated occurrence of streamers of high potential vorticity as precursors of heavy precipitation. Dynamical downscaling indicates high freezing levels (4000 m a.s.l.), extreme precipitation rates (max. 270 mm/24 h), and weather dynamics that agree well with observed precipitation and damage, and with existing concepts of forced low-level convergence, mid-level uplift and iterative northeastward propagation of convective cells. Simulated and observed peak levels of Lago Maggiore differ by 2 m, possibly because the exact cross-section of the lake outflow is unknown. The extreme response of Lago Maggiore cannot be attributed to low forest cover. Nevertheless, such a paradigm was adopted by policy makers following the 1868 flood, and used to implement nationwide afforestation policies and hydraulic structures. These findings illustrate the potential of high-resolution, hydro-meteorological models - strongly supported by historical methods - to shed new light on weather events and their socio-economic implications in the 19th century.

Language: en