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Spatial Variability in Soil Moisture Content under Preferential Flow in Hydrophobic Organic Soil
Języki publikacji
Abstrakty
Wettability is one of the most important peculiarities of soil and it directly influences their physical, mechanical, chemical, properties biological and their fertility. Soil water repellency can lead to the development of unstable wetting and preferential flow paths. Water flow and solute transport patterns are complex under such conditions. The existence of the water repellent layer can have negative influence on soil moisture content because it reduces the amount of water supplied from ground water level by capillary rise, infiltration from the soil surface and also for retention and therefore acts as a constraint in the restoration of drained peatlands by rewetting. That means that repellency can have significant influence on restoration, conservation and management of the peat resources. The paper presents the result of the spatial variability of soil moisture in a small area in a hydrophobic peat-muck profile located within Kuwasy drainage-subirrigation system at the Biebrza River Valley. Soil moisture variability study was carried out on an area of 1 m2 and 0.5 depth in the two measurement periods. The measurements were made in two versions: the first after artificial irrigation (60 mm) and the second after an intense rain. In both of measuring periods the study area was divided into a regular grid of squares. Spatial variability of the investigated traits was evaluated using parameters of the theoretical variogram and cross variogram models. The variability of soilmoisture in the profile after intense rainfall was higher than after irrigation. Themaximum range of the spatial correlation (189 cm) soil moisture was observedin the alder peat layer for measurements made after irrigation. The observedvariability is associated with high hydrophobicity of studied soil. The observedvariability may be important in the assessment of current water resources of thesoil profile. The relationship between water content and the surface of the samplingindicates that, following the increase of the sampling surface the dispersionof results gets smaller, and the distributions are symmetric. The relationshipbetween the coefficient of variation CV and the surface sampling showsthat most of the variability occurred in the top moorsh layer of soil tested (CV =40%). To check the stationary conditions for soil moisture measurements, theanalysis of the trend were made. Elimination of the trend also provided a normaldistribution of residual moisture values. Semivariance and cross variance forresidual moisture values were calculated, and then were leveled with spherical or linear model. From the presented data results that after irrigation as well as heavy rain falls there exists the relationship between the distribution of moisture muck individual layers (up to 30 cm) and can be described using a spherical model. The results show large spatial variability of the total variance of soil moisture and poor soil moisture spatial correlation between the different layers of the soil profile.
Wydawca
Czasopismo
Rocznik
Tom
Strony
580--607
Opis fizyczny
Bibliogr 28 poz., tab., rys.
Twórcy
autor
- Szkoła Główna Gospodarstwa Wiejskiego, Warszawa
autor
- Szkoła Główna Gospodarstwa Wiejskiego, Warszawa
autor
- Szkoła Główna Gospodarstwa Wiejskiego, Warszawa
autor
- Szkoła Główna Gospodarstwa Wiejskiego, Warszawa
Bibliografia
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- 17. Oleszczuk R.; Gnatowski, T.; Brandyk, T., Szatylowicz, J.: Calibration of TDR for moisture content monitoring in moorsh layers. In “Wetlands: Modeling, Monitoring, Management” (ed. by T. Okruszko, E. Maltby, J. Szatyłowicz, D. Świątek, W. Kotowski, pp. 121–124. Taylor & Francis Group. London 2007.
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- Modeling, Monitoring, Management” (ed. by T. Okruszko, E. Maltby, J. Szatyłowicz, D. Świątek, W. Kotowski, 113–120. Taylor & Francis Group. London 2007.
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Typ dokumentu
Bibliografia
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