Spatio-temporal variability and temporal stability of water contents distributed within soil profiles at a hillslope scale

Gao, Lei; Shao, Mingan; Peng, Xinhua; She, Dongli

doi:10.1016/j.catena.2015.03.022

Cited by 37 publications

(19 citation statements)

References 36 publications

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“…In contrast, Gao et al () and Jia, Shao, Wei, and Wang () found that TS increased with depth in the 3‐m soil profile, and more time stable locations were identified in deeper layers. More recently, Gao, Shao, Peng, and She () separated a soil profile into “irregularly changing” (0–0.6 m), “regularly changing” (0.6–1.6 m), and “relatively constant” layers (1.6–3.0 m) according to different TS indices. Wang et al () partitioned a 21‐m soil profile into an active layer (0–2 m) and a relatively stable layer (2–21 m) based on the TS indicator.…”

Section: Introductionmentioning

confidence: 99%

Spatial and temporal variability of 0‐ to 5‐m soil–water storage at the watershed scale

Wang

et al. 2018

Hydrological Processes

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Dynamic relationships among rainfall patterns, soil water distribution, and plant growth are crucial for sustainable conservation of soil and water resources in water‐limited ecosystems. Spatial and temporal variation in deep soil water content at a watershed scale have not yet been characterized adequately due to the lack of deep soil water data. Deep soil–water storage (SWS) up to a depth of 5 m (n = 73) was measured at 19 sampling occasions at the LaoYeManQu watershed on the Chinese Loess Plateau (CLP). At a depth of 0–1.5 m, the annual mean SWS was highly correlated with rain intensity, and the correlation decreased with depth, but within the layers at 1.5–5.0 m, the changes in SWS indicated a lag between precipitation and the replenishment of soil water. Geostatistical parameters of SWS were also highly dependent on depth, and the mean SWS presented similar spatial structures in two adjacent layers. Temporal stability of SWS as indicated by mean relative difference, standard deviation of the relative difference (SDRD), and mean absolute bias error (MABE) was significantly weaker at the shallow than at deeper layers. Soil separates and organic carbon content controlled the spatial pattern of SWS at the watershed scale. One representative location (Site 57) was identified to estimate the mean SWS in the 1‐ to 5‐m layer of the watershed. Semivariograms of the SDRD and MABE were best fitted by an isotropic spherical model, and their spatial distributions were depth‐dependent. Both temporal stability and spatial variability of SWS increased over depth. This study is helpful for deep SWS estimation and sustainable management of soil and water on the CLP, and for other similar regions around the world.

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Section: Introductionmentioning

confidence: 99%

Spatial and temporal variability of 0‐ to 5‐m soil–water storage at the watershed scale

Wang

et al. 2018

Hydrological Processes

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“…A series of studies on the time stability of soil moisture in the northern Loess Plateau have been conducted for different purposes (Hu et al 2009(Hu et al , 2012Gao and Shao 2012;Jia and Shao 2013;Gao et al 2015). The earliest study was conducted by Hu et al (2009), who explored the effects of neutron probe calibration procedures on the identification of the most time stable location for mean soil moisture estimation.…”

Section: Introductionmentioning

confidence: 99%

“…Thereafter, they explored the impacts of soil depth, soil texture, and land use on the time stability of soil moisture (Hu et al 2010b) and compared the performance of seven time stability indices (Hu et al 2012). Recently, the time stability concept has been extended to an adjacent or distant area for the estimation of mean soil moisture, and has also been applied in diverse soil layers (Gao and Shao 2012;Jia and Shao 2013;Gao et al 2013Gao et al , 2015. However, nearly all these studies were concentrated in the transitional belt between loess and desert; studies conducted in typical hilly and gully areas of the Loess Plateau are rare.…”

Section: Introductionmentioning

confidence: 99%

Soil moisture temporal stability analysis for typical hilly and gully re-vegetated catchment in the Loess Plateau, China

Wang

2016

Environ Earth Sci

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In arid and semi-arid regions, soil moisture in particular is a key integrative state variable that is linked to a range of hydrological, ecological, climatic, and geological processes; however, it is usually highly variable in space and time. To overcome this issue, it is necessary to study the temporal stability of soil moisture. Here, we intend to take a soil moisture temporary stability analysis for the typical hilly and gully re-vegetated areas in the Loess Plateau. Using cumulative frequency distribution, the relative difference, and Spearman's rank correlation coefficient to conduct temporal stability analysis for the soil moisture at five slope transects of a typical hilly and gully re-vegetated loess catchment during the rainy season of 2012. We found the soil moisture spatial distribution pattern for the small, typical hilly and gully re-vegetated Loess Plateau catchment to be stable. However, it is not always easy to find sites representative of the catchment average moisture content under different conditions; but it is easier to find sites with extremely high water content in the slopes. A new method for identifying temporally stable locations in typical re-vegetated hilly and gully loess areas is needed. The relationships between soil moisture and other catchment conditions for the diagnosis of representative sites must also be determined. The pattern stability and type stability of soil moisture guarantees that sampling comparisons in this area can be conducted at different times to compare the differences between various land cover types, especially with regard to deep soil depth.

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“…We also calculate that, on average, around 9.5% (~34.5 mm) of the accumulated precipitation may contribute to the recharge of the aquifer at the hillslope sites. Information about θ in a mountain block is essential for describing the dynamics and movement of water into the thin soil profile and its relation to potential groundwater recharge.scales [10] with substantial variations observed with soil depth [11][12][13]. For instance, θ in different soil layers is influenced by the productivity of terrestrial plants with varying rooting depths [14][15][16].Precipitation pulses are a first-order control on the seasonal variation of θ during the hydrological year, in particular for semiarid regions characterized by long periods of no rainfall [9,17,18].…”

mentioning

confidence: 99%

“…scales [10] with substantial variations observed with soil depth [11][12][13]. For instance, θ in different soil layers is influenced by the productivity of terrestrial plants with varying rooting depths [14][15][16].…”

mentioning

confidence: 99%

Variations in Soil Water Content, Infiltration and Potential Recharge at Three Sites in a Mediterranean Mountainous Region of Baja California, Mexico

Toro-Guerrero

Vivoni

Kretzschmar

et al. 2018

Water

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In this research, we examined temporal variations in soil water content (θ), infiltration patterns, and potential recharge at three sites with different mountain block positions in a semiarid Mediterranean climate in Baja California, Mexico: two located on opposing aspects (south-(SFS) and north-facing slopes (NFS)) and one located in a flat valley. At each site, we measured daily θ between 0.1 and 1 m depths from May 2014 to September 2016 in four hydrological seasons: wet season (winter), dry season (summer) and two transition seasons. The temporal evolution of θ and soil water storage (SWS) shows a strong variability that is associated mainly with high precipitation (P) pulses and soil profile depth at hillslope sites. Results shows that during high-intensity P events sites with opposing aspects reveal an increase of θ at the soil-bedrock interface suggesting lateral subsurface fluxes, while vertical soil infiltration decreases noticeably, signifying the production of surface runoff. We found that the dry soil conditions are reset annually at hillslope sites, and water is not available until the next wet season. Potential recharge occurred only in the winter season with P events greater than 50 mm/month at the SFS site and greater than 120 mm/month at the NFS site, indicating that soil depth and lack of vegetation cover play a critical role in the transport water towards the soil-bedrock interface. We also calculate that, on average, around 9.5% (~34.5 mm) of the accumulated precipitation may contribute to the recharge of the aquifer at the hillslope sites. Information about θ in a mountain block is essential for describing the dynamics and movement of water into the thin soil profile and its relation to potential groundwater recharge.scales [10] with substantial variations observed with soil depth [11][12][13]. For instance, θ in different soil layers is influenced by the productivity of terrestrial plants with varying rooting depths [14][15][16].Precipitation pulses are a first-order control on the seasonal variation of θ during the hydrological year, in particular for semiarid regions characterized by long periods of no rainfall [9,17,18]. In semiarid Mediterranean climate systems, the seasonality of precipitation (P) leads to high water availability in the winter season when potential evapotranspiration is low [19]. Winter precipitation influences diffuse recharge processes through vertical infiltration occurring in the soil profile (e.g., [20][21][22][23]). In mountain systems within these settings, soil thickness is generally shallow leading to the potential for rapid flow into fractures that underlie the soil [24]. As a result, the shallow monitoring of θ and its spatiotemporal variability in response to P should yield inferences on potential recharge in mountain block systems.Mountain block systems often have spatial variations in vegetation mediated by topographic position. For instance, plant distributions in mid-latitude regions exhibit changes between pole-facing slopes and equator-facing slopes (i...

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Spatio-temporal variability and temporal stability of water contents distributed within soil profiles at a hillslope scale

Cited by 37 publications

References 36 publications

Spatial and temporal variability of 0‐ to 5‐m soil–water storage at the watershed scale

Spatial and temporal variability of 0‐ to 5‐m soil–water storage at the watershed scale

Soil moisture temporal stability analysis for typical hilly and gully re-vegetated catchment in the Loess Plateau, China

Variations in Soil Water Content, Infiltration and Potential Recharge at Three Sites in a Mediterranean Mountainous Region of Baja California, Mexico

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