EGU2020-157, updated on 12 Jun 2020
https://doi.org/10.5194/egusphere-egu2020-157
EGU General Assembly 2020
© Author(s) 2020. This work is distributed under
the Creative Commons Attribution 4.0 License.

Soil moisture dynamics in winter under heavy snowfall conditions in Shonai (Japan)

Alexander Brandt1,2, Qiqin Zhang1,2, Maximo Larry Lopez Caceres1, and Hideki Murayama1
Alexander Brandt et al.
  • 1Yamagata, Faculty of Agriculture, Japan (alexmakoto27@gmail.com)
  • 2UGAS (United Graduate School of Agricultural Sciences, Iwate University), Morioka, Japan

Yamagata prefecture, facing the Japan Sea, is one of the heavy snow fall regions of the world. Around half of the annual precipitation of around 3000 mm falls in winter as snow, producing snow covers of more than three meters depth.  However, air temperature is around 0°C in winter and therefore relatively warm. Hence, snow density becomes 0.5 g/cm³ already early in the snow accumulation phase. To qualify and quantify interactions, three spots on a slope, forested with Japanese cedar (Cryptomeria japonica), have been selected to compare relationships on top, at the middle and at the bottom of snow covered slopes. The site represents the majority of mountain forests in north-eastern Japan. Monitoring soil and air temperature as well as precipitation and soil moisture we found strong interactions between the three hydrological regimes (precipitation, snow cover and soil) in winter. Soil did not freeze and hence volumetric soil moisture content changed during the winter season. Several sharp significant increases of soil moisture have been measured before the snow melt period even started. High rates of soil moisture increase together with an increase of Snow Water Equivalent (SWE) have been found to be caused by rain-on-snow events. In contrast, smaller rates of soil moisture increase in peaks were correlated with a decrease in SWE and therefore a snowmelt process. The interactions of snow cover and soil have been found to be different in the three different spots at the slope. Soil at the bottom of a slope reacts significantly to the highest number of events; soil on the slope reacts only to some events, but more intensively. Thus, most of the water is moving within the snowpack down the slope, increasing the SWE. Thereafter water reaches the soil surface and infiltrates it. This has been found to be also one reason for the formation of depth hoars and therefore the risk of avalanches.

To conclude, hydrological regimes in north-eastern Japan interact during the whole year due to winter air temperatures around 0°C and soil which does not freeze. The shape of peaks in soil moisture can be used to distinguish between rain and snowmelt causing the soil moisture increase. Various preferential flow patterns at different spots on a slope are an excellent basis for further studies and a basis for further monitoring and modelling.

How to cite: Brandt, A., Zhang, Q., Lopez Caceres, M. L., and Murayama, H.: Soil moisture dynamics in winter under heavy snowfall conditions in Shonai (Japan), EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-157, https://doi.org/10.5194/egusphere-egu2020-157, 2019

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