Environmental Factors Governing Soil Water Repellency Dynamics in a Pinus Pinaster Plantation in NW Spain

Benito, E.; Rodríguez‐Alleres, M.; Teijeiro, María Eufemia Varela

doi:10.1002/ldr.2370

Cited by 24 publications

(11 citation statements)

References 40 publications

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“…The results of the grass-covered soil are consistent with the widespread assumption that water repellency is a transient phenomenon occurring more markedly in dry soils than in wet soils (Benito Rueda et al, 2015;Keizer et al, 2007;Rodríguez-Alleres and Benito, 2011).…”

Section: Discussionsupporting

confidence: 83%

Impacts of grass removal on wetting and actual water repellency in a sandy soil

Oostindie

Dekker

Wesseling

et al. 2016

Journal of Hydrology and Hydromechanics

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Soil water content and actual water repellency were assessed for soil profiles at two sites in a bare and grasscovered plot of a sand pasture, to investigate the impact of the grass removal on both properties. The soil of the plots was sampled six times in vertical transects to a depth of 33 cm between 23 May and 7 October 2002. On each sampling date the soil water contents were measured and the persistence of actual water repellency was determined of field-moist samples. Considerably higher soil water contents were found in the bare versus the grass-covered plots. These alterations are caused by differences between evaporation and transpiration rates across the plots. Noteworthy are the often excessive differences in soil water content at depths of 10 to 30 cm between the bare and grass-covered plots. These differences are a consequence of water uptake by the roots in the grass-covered plots. The water storage in the upper 19 cm of the bare soil was at least two times greater than in the grass-covered soil during dry periods. A major part of the soil profile in the grass-covered plots exhibited extreme water repellency to a depth of 19 cm on all sampling dates, while the soil profile of the bare plots was completely wettable on eight of the twelve sampling dates. Significant differences in persistence of actual water repellency were found between the grass-covered and bare plots.

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Section: Discussionsupporting

confidence: 83%

Impacts of grass removal on wetting and actual water repellency in a sandy soil

Oostindie

Dekker

Wesseling

et al. 2016

Journal of Hydrology and Hydromechanics

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“…Our results revealed a significant influence on the maximum dye infiltration depth from the initial SWC; this may have been the result of the interaction between the SWC spatial patterns and soil water repellency (Jordán et al, ). Soil water content is an essential component of soil water repellency dynamics (Benito Rueda et al, ; Hewelke et al, ). Soil water repellency is found to be eliminated during extremely wet weather and be most severe during dry periods because it can result in changes in the soil hydrological responses and the soil water content spatial patterns (Rodríguez‐Alleres & Benito, ; Rodríguez‐Alleres et al, ).…”

Section: Discussionmentioning

confidence: 99%

Interaction Between Plant Roots and Soil Water Flow in Response to Preferential Flow Paths in Northern China

et al. 2016

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Preferential flow is expected to provide preferential channels for plant root growth and variations in soil water flow, but few studies were conducted to imply the impacts of these changes, particularly for preferential flow in stony soils. This study aimed to characterize soil water flow and plant root distribution in response to preferential flow paths and quantitatively describe the relation between plant root distribution and soil water flow. Field dye‐tracing experiments centered on experimental plants were conducted to determine the root length density and soil water flow process. Laboratory analyses were performed to characterize changes in the relative concentration of the accumulated effluent and the degree of interaction between plant roots and soil water flow. The amount of fine plant roots with preferential flow paths decreased with increasing soil depth for all experimental plots. The largest plant roots were recorded in the upper soil layers to a depth of 20 cm. The relative concentration of the accumulated effluent increased with time and decreased with soil depth under saturated soil conditions, whereas a distinct early turning point for the relative concentration of the accumulated effluent was observed in the 0–20‐cm soil columns, and the relative concentration of the accumulated effluent initially decreased and then increased with time under unsaturated soil conditions. This study provides quantitative information with which to characterize the interaction between plant roots and soil water flow in response to preferential flow paths in soil–plant–water systems. Copyright © 2016 John Wiley & Sons, Ltd.

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“…Evapotranspiration, maximum temperature, and annual radiation were the key climatic variables related to the growth of declining trees from planted stands which confirms that the growth of these trees was constrained by low water availability and high water demand. This is likely a consequence of the presence of declining planted stands on less developed and steeper soils, such as south-facing slopes on limestone substrates with low water-holding capacity [62]. In contrast, high values of water retention capacity-related to aspect and slope-were correlated with the growth of non-declining trees from planted stands, which are located at sites with a higher soil water retention capacity where the negative impacts of drought on growth are buffered [63].…”

Section: Responses Of Growth and Climatic Indices To The Environment mentioning

confidence: 99%

Cumulative Drought Stress Leads to a Loss of Growth Resilience and Explains Higher Mortality in Planted than in Naturally Regenerated Pinus pinaster Stands

Navarro-Cerrillo

Rodriguez-Vallejo

Silveiro

et al. 2018

Forests

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Abstract:The assessment of the long-term impacts of drought on tree growth decline using tree-ring analyses may be used to test if plantations are more vulnerable to warming after successive droughts, leading to a "cumulative stress" effect. We selected 76 Pinus pinaster trees (declining and non-declining trees), and basal area increments over the last 20 years (BAI 20 ) were calculated to build the chronologies for the stand types and vigor classes. Resistance, recovery and resilience indices were calculated. Pearson correlations, analyses and Partial Least-Squares regression were used to analyze the relationships among the response and environmental variables. We found a negative and significant relationship between mean temperature for May and June of the current year and growth in the naturally regenerated stands. This negative effect on growth under warm spring conditions was more noticeable in plantations than in naturally regenerated stands. A negative trend along time was found for the resilience index in planted stands. Evapotranspiration, maximum temperature and annual radiation showed significant and negative correlations with the growth of declining trees from planted stands, indicating they are susceptible to drought stress. Declining trees in planted stands showed a loss of growth resilience, specifically a negative trend after successive droughts.

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Environmental Factors Governing Soil Water Repellency Dynamics in a Pinus Pinaster Plantation in NW Spain

Cited by 24 publications

References 40 publications

Impacts of grass removal on wetting and actual water repellency in a sandy soil

Impacts of grass removal on wetting and actual water repellency in a sandy soil

Interaction Between Plant Roots and Soil Water Flow in Response to Preferential Flow Paths in Northern China

Cumulative Drought Stress Leads to a Loss of Growth Resilience and Explains Higher Mortality in Planted than in Naturally Regenerated Pinus pinaster Stands

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