Integrated approach of RUSLE, GIS and ESA Sentinel-2 satellite data for post-fire soil erosion assessment in Basilicata region (Southern Italy)

Lanorte, Antonio; Cillis, Giuseppe; Calamita, Giuseppe; Nolè, Gabriele; Pilogallo, Angela; Tucci, Biagio; Santis, Fortunato De

doi:10.1080/19475705.2019.1578271

Cited by 40 publications

(35 citation statements)

References 90 publications

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“…Besides, burn severity is increasingly being recognised as a decisive factor controlling post‐wildfire hydrological responses and erosion rates (Benavides‐Solorio & MacDonald, 2005; Larsen & MacDonald, 2007; Shakesby & Doerr, 2006; Vieira, Fernández, Vega, & Keizer, 2015); in this context, burn severity describes the degree to which a burnt area has been changed by a fire (Jain & Graham, 2007; Jain, Graham, & Pilliod, 2004; Keeley, 2009; UNOOSA, 2019). Consequently, quantitative empirical relations between burn severity and soil hydraulic properties (Moody et al, 2016), as well as between burn severity and soil erosion rates (Fernández & Vega, 2016b; Lanorte et al, 2019; Vieira et al, 2014) have been established in recent years.…”

Section: Introductionmentioning

confidence: 99%

Comparing the impacts of wildfire and meteorological variability on hydrological and erosion responses in a Mediterranean catchment

Nunes

2020

Land Degrad Dev

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Land degradation and water resources pollution caused by catastrophic wildfires is of growing concern in fire‐prone regions. Studies on the effects of wildfire on hydrology and erosion have mostly been conducted at plot or hillslope scale, while relatively few studies investigated post‐wildfire hydrological responses and erosion at the meso‐catchment scale (~ > 10 km2) in the Mediterranean. This study used measured discharge and suspended sediment at the outlet of a burnt catchment in southern Portugal, before and after a wildfire, to investigate post‐wildfire changes in hydrological and erosion responses to rainfall. Hydrological and sediment connectivity patterns were derived to investigate changing dynamics induced by the fire within the catchment. The main findings were: (a) although a large part of the catchment experienced moderate to high severity burning, post‐wildfire hydro‐sedimentary response was considerably limited; (b) meteorological variability determined hydrological responses and erosion more strongly than wildfire effects; and (c) during the post‐wildfire vegetation recovery period, only rainfall events with a high return period (~ 2 years) enhanced the hydrological and erosion responses. This can be explained by the spatial scale dependency of these processes and limited fine sediment supply, or relatively low connectivity in the study catchment. While connectivity is only an indicator, this implies that, at the meso‐catchment scale, pollution of downstream water bodies by contaminated soil and ash may not occur immediately. Rather, because sediments and associated ashes and contaminants are first being transported to the areas around the stream networks, they only reach the outlet during heavy events which do connect the entire catchment. Thus, dynamic indices of connectivity that take rainfall event characteristics into consideration need to be further tested to assess and manage post‐wildfire soil and water contamination risk.

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Section: Introductionmentioning

confidence: 99%

Comparing the impacts of wildfire and meteorological variability on hydrological and erosion responses in a Mediterranean catchment

Nunes

2020

Land Degrad Dev

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“…Being representative of the susceptibility to soil erosion, the K-factor is a complex synthesis of a combination of phenomena such as the splash during rainfall and intensive events, runoff along the upper soil layer - including transportability of sediments - and seepage into the soil [ 56 ]. For these reason, factor is a function of the soil structure [ 57 ], the permeability [ 58 ], the total amount of organic matter [ 59 ], the granulometry [ 60 ], the water contents in topsoil [ 61 ], and a number of quantities that vary over time even in response to major upheavals such as fires [ 62 – 64 ]. An accurate estimation thus requires intensive and time-consuming field measurements [ 65 ] that have resulted in a continuous investigation and testing of experimental methods and estimation procedures based on a limited number of soil features [ 66 ].…”

Section: Methodsmentioning

confidence: 99%

Soil Ecosystem Services and Sediment Production: The Basilicata Region Case Study

Pilogallo

Saganeiti

Scorza

et al. 2020

Computational Science and Its Applications – ICCSA 2020

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The conservation of soil and multiple ecosystem services it provides, is crucial for human well-being, for pursuing many of the Sustainable Development Goals and for addressing some of the most important challenges of our society. However several factors contribute to soil degradation, including climatic characteristics, lithological and morphological features and transformation processes. Only the last ones can be governed and that is the reason why spatial planning needs tools and analyses to interpret the role of land use changes in complex dynamics such as the erosive phenomena. This work presents the results obtained from the implementation of the InVEST SDR module on the territory of Basilicata Region and considering the evolution occurred between 1990 and 2018. Our outcomes show an intensification of erosion phenomena mainly along the Apennine chain and the coastal area of the Tyrrhenian Sea. Although this area corresponds to the higher average rainfall erosivity over the entire period, the most significant soil loss occurs in correspondence with unfavorable land use changes. The negative connotation typically associated with deforestation, conversion of agricultural soils to arable lands and thinning or total loss of vegetation becomes a measurable quantity, at least from one of several points of view.

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“…Generally, C ranges between 1 and 0; higher values (≤1) are used for less vegetation, thus considering the land as barren whereas lower values (near to zero) indicate very strong cover and well-protected soil. Lanorte et al [39] have reported that many authors have adopted simplified approaches to estimate C, e.g., by using land cover maps and assigning a C value to each class [40] or by applying remote-sensing techniques such as image classification [41,42] and vegetation indices [43]. Various studies [44][45][46] report mathematical functions to calculate C using the normalized difference vegetation index (NDVI), which is positively correlated with the amount of green biomass and indicates differences in green vegetation coverage [45].…”

Section: Topographic Factor (Ls)mentioning

confidence: 99%

Soil Erosion and Sediment Load Management Strategies for Sustainable Irrigation in Arid Regions

Bhatti¹,

Ashraf

Anwar³

2021

Sustainability

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Soil erosion is a serious environmental issue in the Gomal River catchment shared by Pakistan and Afghanistan. The river segment between the Gomal Zam dam and a diversion barrage (~40 km) brings a huge load of sediments that negatively affects the downstream irrigation system, but the sediment sources have not been explored in detail in this sub-catchment. The analysis of flow and sediment data shows that the significant sediment yield is still contributing to the diversion barrage despite the Gomal Zam dam construction. However, the sediment share at the diversion barrage from the sub-catchment is much larger than its relative size. A spatial assessment of erosion rates in the sub-catchment with the revised universal soil loss equation (RUSLE) shows that most of the sub-catchment falls into very severe and catastrophic erosion rate categories (>100 t h−1y−1). The sediment entry into the irrigation system can be managed both by limiting erosion in the catchment and trapping sediments into a hydraulic structure. The authors tested a scenario by improving the crop management factor in RUSLE as a catchment management option. The results show that improving the crop management factor makes little difference in reducing the erosion rates in the sub-catchment, suggesting other RUSLE factors, and perhaps slope is a more obvious reason for high erosion rates. This research also explores the efficiency of a proposed settling reservoir as a sediment load management option for the flows diverted from the barrage. The proposed settling reservoir is simulated using a computer-based sediment transport model. The modeling results suggest that a settling reservoir can reduce sediment entry into the irrigation network by trapping 95% and 25% for sand and silt particles, respectively. The findings of the study suggest that managing the sub-catchment characterizing an arid region and having steep slopes and barren mountains is a less compelling option to reduce sediment entry into the irrigation system compared to the settling reservoir at the diversion barrage. Managing the entire catchment (including upstream of Gomal Zam dam) can be a potential solution, but it would require cooperative planning due to the transboundary nature of the Gomal river catchment. The output of this research can aid policy and decision-makers to sustainably manage sedimentation issues in the irrigation network.

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Integrated approach of RUSLE, GIS and ESA Sentinel-2 satellite data for post-fire soil erosion assessment in Basilicata region (Southern Italy)

Cited by 40 publications

References 90 publications

Comparing the impacts of wildfire and meteorological variability on hydrological and erosion responses in a Mediterranean catchment

Comparing the impacts of wildfire and meteorological variability on hydrological and erosion responses in a Mediterranean catchment

Soil Ecosystem Services and Sediment Production: The Basilicata Region Case Study

Soil Erosion and Sediment Load Management Strategies for Sustainable Irrigation in Arid Regions

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