Quantifying water fluxes from soil pores to catchment scale is limited by trade-offs between temporal resolution, spatial coverage, and measurement depth. Multi-scale hydrogeophysics can bridge these gaps, but requires coordinated acquisition of geophysical surveys and in-situ sensors. The Alento Critical Zone Observatory offers a unique experimental setting to integrate repeated EMI and time-lapse ERT with soil moisture networks and extensive soil characterization.
Fusing time-lapse geophysics and in-situ sensing to create a 4D model of hillslope hydrology in a Mediterranean catchment / Cassiani, G., Nasta, P., Mazzitelli, C., Censini, M., Romano, N.. - (2025). (American Geophysical Union Fall Meeting (AGU2025) New Orleans (USA) 15-19 December) [10.13140/RG.2.2.23829.18409].
Fusing time-lapse geophysics and in-situ sensing to create a 4D model of hillslope hydrology in a Mediterranean catchment.
Paolo NastaSecondo
;Caterina Mazzitelli;Matteo Censini;Nunzio Romano
Ultimo
2025
Abstract
Quantifying water fluxes from soil pores to catchment scale is limited by trade-offs between temporal resolution, spatial coverage, and measurement depth. Multi-scale hydrogeophysics can bridge these gaps, but requires coordinated acquisition of geophysical surveys and in-situ sensors. The Alento Critical Zone Observatory offers a unique experimental setting to integrate repeated EMI and time-lapse ERT with soil moisture networks and extensive soil characterization.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
