Increased attention directed at frozen-soil hydrology has
been prompted by climate change. In spite of an increasing number of
field measurements and modeling studies, the impact of frozen-soil on
hydrological processes at the catchment scale is still unclear. However,
frozen
...
Increased attention directed at frozen-soil hydrology has
been prompted by climate change. In spite of an increasing number of
field measurements and modeling studies, the impact of frozen-soil on
hydrological processes at the catchment scale is still unclear. However,
frozen-soil hydrology models have mostly been developed based on a
“bottom-up” approach, i.e. by aggregating prior knowledge at pixel
scale, which is an approach notoriously suffering from equifinality and
data scarcity. Therefore, in this study, we explore the impact of
frozen-soil at catchment-scale, following a “top-down” approach,
implying: expert-driven data analysis → qualitative perceptual model → quantitative conceptual model →
testing of model realism. The complex mountainous Hulu catchment,
northeast of the Tibetan Plateau, was selected as the study site.
Firstly, we diagnosed the impact of frozen-soil on catchment hydrology,
based on multi-source field observations, model discrepancy, and our
expert knowledge. Two new typical hydrograph properties were identified:
the low runoff in the early thawing season (LRET) and the discontinuous
baseflow recession (DBR). Secondly, we developed a perceptual
frozen-soil hydrological model, to explain the LRET and DBR properties.
Thirdly, based on the perceptual model and a landscape-based modeling
framework (FLEX-Topo), a semi-distributed conceptual frozen-soil
hydrological model (FLEX-Topo-FS) was developed. The results demonstrate
that the FLEX-Topo-FS model can represent the effect of soil
freeze/thaw processes on hydrologic connectivity and groundwater
discharge and significantly improve hydrograph simulation, including the
LRET and DBR events. Furthermore, its realism was confirmed by
alternative multi-source and multi-scale observations, particularly the
freezing and thawing front in the soil, the lower limit of permafrost,
and the trends in groundwater level variation. To the best of our
knowledge, this study is the first report of LRET and DBR processes in a
mountainous frozen-soil catchment. The FLEX-Topo-FS model is a novel
conceptual frozen-soil hydrological model, which represents these
complex processes and has potential for wider use in the vast Tibetan
Plateau and other cold mountainous regions.@en