Diurnal dynamics of streamflow in an upland forested micro‐watershed during short precipitation‐free periods is altered by tree sap flow

Deutscher, Jan; Kupec, Petr; Dundek, Peter; Holík, Ladislav; Machala, Martin; Urban, Josef

doi:10.1002/hyp.10771

Cited by 27 publications

(19 citation statements)

References 40 publications

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“…Reduced summer rainfall and increased evapotranspiration (ET) also affect streamflow generation (Déry and Wood, 2005;Deutscher et al, 2016) and soil water and groundwater storage (Barnett et al, 2005;McNamara et al, 2005;House et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Modelling the effects of land cover and climate change on soil water partitioning in a boreal headwater catchment

Wang

Tetzlaff

Soulsby

2018

Journal of Hydrology

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Section: Introductionmentioning

confidence: 99%

Modelling the effects of land cover and climate change on soil water partitioning in a boreal headwater catchment

Wang

Tetzlaff

Soulsby

2018

Journal of Hydrology

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“…The analysis of naturally occurring diurnal variations in stream or groundwater levels provides an opportunity for estimating aquifer hydraulic properties under transient conditions caused by cyclical loading. Diurnal signals in stream discharge and stage can be caused by a number of processes, including snowmelt [Caine, 1992;Loheide and Lundquist, 2009;Mutzner et al, 2015], glacier melt [Condom et al, 2013;Crossman et al, 2011], and evapotranspiration (ET) [Bond et al, 2002;Deutscher et al, 2016;Graham et al, 2013]. Several studies have analyzed the propagation of diurnal hydraulic pulses from a stream to a hillslope (or vice versa) to determine hydraulic conductivity using an analytical solution to a diffusion equation subject to a Fourier series boundary condition [e.g., Loheide and Lundquist, 2009;Magnusson et al, 2014].…”

Section: Introductionmentioning

confidence: 99%

Inferring hydraulic properties of alpine aquifers from the propagation of diurnal snowmelt signals

Kurylyk

2017

Water Resources Research

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Alpine watersheds source major rivers throughout the world and supply essential water for irrigation, human consumption, and hydroelectricity. Coarse depositional units in alpine watersheds can store and transmit significant volumes of groundwater and thus augment stream discharge during the dry season. These environments are typically data scarce, which has limited the application of physically based models to investigate hydrologic sensitivity to environmental change. This study focuses on a coarse alpine talus unit within the Lake O'Hara watershed in the Canadian Rockies. We investigate processes controlling the hydrologic functioning of the talus unit using field observations and a numerical groundwater flow model driven with a distributed snowmelt model. The model hydraulic parameters are adjusted to investigate how these properties influence the propagation of snowmelt‐induced diurnal signals. The model results expectedly demonstrate that diurnal signals at the talus outlet are progressively damped and lagged with lower hydraulic conductivity and higher specific yield. The simulations further indicate that the lag can be primarily controlled by a higher hydraulic conductivity upper layer, whereas the damping can be strongly influenced by a lower hydraulic conductivity layer along the base of the talus. The simulations specifically suggest that the talus slope can be represented as a two layer system with a high conductivity zone (0.02 m s−1) overlying a 10 cm thick lower conductivity zone (0.002 m s−1). This study demonstrates that diurnal signals can be used to elucidate the hydrologic functioning and hydraulic properties of shallow aquifers and thus aid in the parameterization of hydrological models.

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“…In these low-energy northern catchments, soil evaporation is limited, and transpiration contributes most of the total evapotranspiration (Sprenger et al, 2018;Wang et al, 2018). Increases in transpiration can result in a decline in streamflow (Deutscher et al, 2016;Kim et al, 2018). Although the response time of streams to ET losses is often unclear, here we simply looked at the growing season as first indicator in the study catchments.…”

Section: The Hydrologic Consequences Of Vegetation Phenology Changementioning

confidence: 99%

Climate-phenology-hydrology interactions in northern high latitudes: Assessing the value of remote sensing data in catchment ecohydrological studies

Wang

Tetzlaff

Buttle

et al. 2019

Science of The Total Environment

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We assessed the hydrological implications of climate effects on vegetation phenology in northern environments by fusion of data from remote-sensing and local catchment monitoring. Studies using satellite data have shown earlier and later dates for the start (SOS) and end of growing seasons (EOS), respectively, in the Northern Hemisphere over the last 3 decades. However, estimates of the change greatly depend on the satellite data utilized. Validation with experimental data on climate-vegetationhydrology interactions requires long-term observations of multiple variables which are rare and usually restricted to small catchments. In this study, we used two NDVI (normalized difference vegetation index) products (at ~25 & 0.5 km spatial resolutions) to infer SOS and EOS for six northern catchments, and then investigated the likely climate impacts on phenology change and consequent effects on catchment water yield, using both assimilated data (GLDAS: global land data assimilation system) and direct catchment observations. The major findings are: (1) The assimilated air temperature compared well with catchment observations (regression slopes and R 2 close to 1), whereas underestimations of summer rainstorms resulted in overall underestimations of precipitation (regression slopes of 0.3-0.7, R 2 ≥ 0.46). (2) The two NDVI products inferred different vegetation phenology characteristics. (3) Increased mean pre-season temperature significantly influenced the advance of SOS and delay of EOS. The precipitation influence was weaker, but delayed SOS corresponding to increased preseason precipitation at most sites can be related to later snow melting. (4) Decreased

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Diurnal dynamics of streamflow in an upland forested micro‐watershed during short precipitation‐free periods is altered by tree sap flow

Cited by 27 publications

References 40 publications

Modelling the effects of land cover and climate change on soil water partitioning in a boreal headwater catchment

Modelling the effects of land cover and climate change on soil water partitioning in a boreal headwater catchment

Inferring hydraulic properties of alpine aquifers from the propagation of diurnal snowmelt signals

Climate-phenology-hydrology interactions in northern high latitudes: Assessing the value of remote sensing data in catchment ecohydrological studies

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