FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2015201731> ?p ?o ?g. }

• W2015201731 endingPage "2000" @default.
• W2015201731 startingPage "1982" @default.
• W2015201731 abstract "Many Mediterranean drylands are characterized by strong erosion in headwater catchments, where connectivity processes play an important role in the redistribution of water and sediments. Sediment connectivity describes the ease with which sediment can move through a catchment. The spatial and temporal characterization of connectivity patterns in a catchment enables the estimation of sediment contribution and transfer paths. Apart from topography, vegetation cover is one of the main factors driving sediment connectivity. This is particularly true for the patchy vegetation cover typical of many dryland environments. Several connectivity measures have been developed in the last few years. At the same time, advances in remote sensing have enabled an improved catchment-wide estimation of ground cover at the subpixel level using hyperspectral imagery. The objective of this study was to assess the sediment connectivity for two adjacent subcatchments (~70 km2) of the Isábena River in the Spanish Pyrenees in contrasting seasons using a quantitative connectivity index based on fractional vegetation cover and topography data. The fractional cover of green vegetation, non-photosynthetic vegetation, bare soil and rock were derived by applying a multiple endmember spectral mixture analysis approach to the hyperspectral image data. Sediment connectivity was mapped using the index of connectivity, in which the effect of land cover on runoff and sediment fluxes is expressed by a spatially distributed weighting factor. In this study, the cover and management factor (C factor) of the Revised Universal Soil Loss Equation (RUSLE) was used as a weighting factor. Bi-temporal C factor maps were derived by linking the spatially explicit fractional ground cover and vegetation height obtained from the airborne data to the variables of the RUSLE subfactors. The resulting connectivity maps show that areas behave very differently with regard to connectivity, depending on the land cover and on the spatial distribution of vegetation abundances and topographic barriers. Most parts of the catchment show higher connectivity values in August as compared to April. The two subcatchments show a slightly different connectivity behaviour that reflects the different land cover proportions and their spatial configuration. The connectivity estimation can support a better understanding of processes controlling the redistribution of water and sediments from the hillslopes to the channel network at a scale appropriate for land management. It allows hot spot areas of erosion to be identified and the effects of erosion control measures, as well as different land management scenarios, to be studied." @default.
• W2015201731 created "2016-06-24" @default.
• W2015201731 creator A5023560610 @default.
• W2015201731 creator A5028893195 @default.
• W2015201731 creator A5033345623 @default.
• W2015201731 creator A5058065959 @default.
• W2015201731 date "2014-10-16" @default.
• W2015201731 modified "2023-10-18" @default.
• W2015201731 title "Assessment of sediment connectivity from vegetation cover and topography using remotely sensed data in a dryland catchment in the Spanish Pyrenees" @default.
• W2015201731 cites W1513215005 @default.
• W2015201731 cites W1531683302 @default.
• W2015201731 cites W1537844550 @default.
• W2015201731 cites W1964881980 @default.
• W2015201731 cites W1966580355 @default.
• W2015201731 cites W1973824991 @default.
• W2015201731 cites W1977066218 @default.
• W2015201731 cites W1984005693 @default.
• W2015201731 cites W1987899762 @default.
• W2015201731 cites W1988567653 @default.
• W2015201731 cites W1994221424 @default.
• W2015201731 cites W1999766969 @default.
• W2015201731 cites W2003234527 @default.
• W2015201731 cites W2003648891 @default.
• W2015201731 cites W2004817400 @default.
• W2015201731 cites W2019038438 @default.
• W2015201731 cites W2020528985 @default.
• W2015201731 cites W2021053166 @default.
• W2015201731 cites W2030496502 @default.
• W2015201731 cites W2037179245 @default.
• W2015201731 cites W2043359577 @default.
• W2015201731 cites W2043384302 @default.
• W2015201731 cites W2043387595 @default.
• W2015201731 cites W2044111667 @default.
• W2015201731 cites W2048469029 @default.
• W2015201731 cites W2051564354 @default.
• W2015201731 cites W2067215661 @default.
• W2015201731 cites W2068431757 @default.
• W2015201731 cites W2069275635 @default.
• W2015201731 cites W2069921544 @default.
• W2015201731 cites W2071190035 @default.
• W2015201731 cites W2074522965 @default.
• W2015201731 cites W2077281443 @default.
• W2015201731 cites W2086106563 @default.
• W2015201731 cites W2087556827 @default.
• W2015201731 cites W2087966651 @default.
• W2015201731 cites W2108883551 @default.
• W2015201731 cites W2109606373 @default.
• W2015201731 cites W2109917507 @default.
• W2015201731 cites W2112732795 @default.
• W2015201731 cites W2119534769 @default.
• W2015201731 cites W2127441956 @default.
• W2015201731 cites W2131356725 @default.
• W2015201731 cites W2131697388 @default.
• W2015201731 cites W2134213291 @default.
• W2015201731 cites W2136635809 @default.
• W2015201731 cites W2139775511 @default.
• W2015201731 cites W2144881411 @default.
• W2015201731 cites W2147712562 @default.
• W2015201731 cites W2147723763 @default.
• W2015201731 cites W2153004016 @default.
• W2015201731 cites W2154649468 @default.
• W2015201731 cites W2159530395 @default.
• W2015201731 cites W2162065449 @default.
• W2015201731 cites W4214564766 @default.
• W2015201731 cites W4248190725 @default.
• W2015201731 doi "https://doi.org/10.1007/s11368-014-0992-3" @default.
• W2015201731 hasPublicationYear "2014" @default.
• W2015201731 type Work @default.
• W2015201731 sameAs 2015201731 @default.
• W2015201731 citedByCount "73" @default.
• W2015201731 countsByYear W20152017312014 @default.
• W2015201731 countsByYear W20152017312015 @default.
• W2015201731 countsByYear W20152017312016 @default.
• W2015201731 countsByYear W20152017312017 @default.
• W2015201731 countsByYear W20152017312018 @default.
• W2015201731 countsByYear W20152017312019 @default.
• W2015201731 countsByYear W20152017312020 @default.
• W2015201731 countsByYear W20152017312021 @default.
• W2015201731 countsByYear W20152017312022 @default.
• W2015201731 countsByYear W20152017312023 @default.
• W2015201731 crossrefType "journal-article" @default.
• W2015201731 hasAuthorship W2015201731A5023560610 @default.
• W2015201731 hasAuthorship W2015201731A5028893195 @default.
• W2015201731 hasAuthorship W2015201731A5033345623 @default.
• W2015201731 hasAuthorship W2015201731A5058065959 @default.
• W2015201731 hasBestOaLocation W20152017312 @default.
• W2015201731 hasConcept C100970517 @default.
• W2015201731 hasConcept C114793014 @default.
• W2015201731 hasConcept C126645576 @default.
• W2015201731 hasConcept C127313418 @default.
• W2015201731 hasConcept C142724271 @default.
• W2015201731 hasConcept C159078339 @default.
• W2015201731 hasConcept C187320778 @default.
• W2015201731 hasConcept C18903297 @default.
• W2015201731 hasConcept C205649164 @default.
• W2015201731 hasConcept C2776133958 @default.
• W2015201731 hasConcept C2780648208 @default.
• W2015201731 hasConcept C2816523 @default.

• next