Aggregate Stability of Soils in Central Spain and the Role of Land Management

Ternan, J. L.; Elmes, A.; Williams, Andy; Hartley, Richard

doi:10.1002/(sici)1096-9837(199602)21:2<181::aid-esp622>3.0.co;2-7

Cited by 49 publications

(15 citation statements)

References 23 publications

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“…Hydrophobic molecules cause water repellency in soil aggregates and decrease wettability, which may result in increased cohesiveness, decreased dispersivity and reduced SOC decomposition rates. Long-term aggregate stability can be enhanced by the addition of hydrophobic organic materials such as organic wastes containing hydrophobic materials and SOC from plant types such as Cistus rather than Pinus (Ternan et al, 1996). No-till (Hallett et al, 2001) and burning (Poulenard et al, 2001) affect soil hydrophobicity.…”

Section: Soil Watermentioning

confidence: 99%

“…Fungi, arbuscular mycorrhizal fungi (AMF) and glomalin. Fungal hyphae improve aggregate stability (Ternan et al, 1996) by reorientation of clay particles, binding particles with extracellular polysaccharides, and enmeshing particles. Hyphae also enmesh microaggregates to form macroaggregates, suggesting that aggregation increases with hyphal density (Haynes and Beare, 1997).…”

Section: Microorganismsmentioning

confidence: 99%

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Soil structure and management: a review

2005

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Section: Soil Watermentioning

confidence: 99%

Section: Microorganismsmentioning

confidence: 99%

Soil structure and management: a review

2005

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“…Twenty-five air-dried aggregates of 4.0-5.6 mm diameter were selected from pooled samples from each site burn severity and placed on a 2.8-mm sieve and equilibrated for 24 h at 50% relative humidity. Aggregate stability was assessed using a laboratory-based spray-type rainfall simulator following the standardized techniques described by Ternan et al (1996). Rainfall was simulated at approximately 45 mm h -1 with a mean drop size of 580 μm.…”

Section: Assessing Post-fire Hydrological Response and Soil Erodibilitymentioning

confidence: 99%

Wildfire impacts on hillslope sediment and phosphorus yields

et al. 2010

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Purpose The impact of wildfire on (a) slope hydrological processes, (b) soil erodibility, and (c) post-fire hillslope sediment and phosphorus (P; dissolved and particulate) yields are quantified for natural forest areas of the burned Evrotas River basin, Peloponnese, Greece. Further, the geochemical partitioning of P in burned and unburned sediment is evaluated by sequential extraction to assess potential bioavailability of particulate P (PP) in downstream aquatic ecosystems. Materials and methods A series of field-based rainfall simulation and infiltration experiments were undertaken in burned and unburned terrain of contrasting vegetation and soil type, after severe wildfires in summer 2007. Resulting water and sediment samples were analyzed for P concentration to permit calculation of hillslope yields for 20, 40, and 60 mm h -1 rainfall events. Samples of soil were collected from each site type for physical and geochemical analyses.Results and discussion Plot-scale rainfall simulation experiments and measurements demonstrate enhanced runoff and erosion rates in burned terrain. While dissolved P concentrations in runoff from burned terrain are elevated (0.21± 0.09 mg l -1 ) against background levels (0.01±0.01 mg l -1 ) and exceed European water quality guidelines, PP represents 99% of the severely burned hillslope P yield (2.32± 1.63 kg ha -1 for a 15-min rainfall event). Sequential extraction data demonstrate that up to 20% of total PP in burned sediment is potentially bioavailable and that bioavaliable PP yields are two orders of magnitude greater than dissolved P yields. Conclusions Release of P from eroded sediment stored in downslope/downstream sink zones may protract the postfire risk to downstream resources. Quantification of PP partitioning in eroded sediment is a key requirement when assessing the downstream impacts of wildfire.

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“…It was suggested that wetting by rapid immersion for the measurement of DAS had led to aggregate breakdown by slaking, while the slaking process may not occur in the measurement of WAS. As Ternan et al (1996) and Unger (1997) suggested, the slaking process played a major role in the breakdown of surface soil aggregates in a semiarid area including the study area where intermittent rainfall causes rapid wetting of the relatively dry soil surface (Shinjo et al 2000). Thus, the determination ofDAS was considered to be more suitable than that of WAS for the analysis of soil erodibility.…”

Section: Resultsmentioning

confidence: 99%