<rdf:RDF xmlns:dc="http://purl.org/dc/elements/1.1/" xmlns:dct="http://purl.org/dc/terms/" xmlns:rdf="http://www.w3.org/1999/02/22-rdf-syntax-ns#">
  <rdf:Description rdf:about="https://doi.org/10.1007/s10021-010-9384-8">
    <dct:isReferencedBy>IMPACT4SOIL</dct:isReferencedBy>
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    <dct:isPartOf>Ecosystems</dct:isPartOf>
    <dct:license>Open Access</dct:license>
    <dct:created>2010-09-29</dct:created>
    <dc:description>In this study, we investigate changes in ecosystem structure that occur over a gradient of land-degradation in the southwestern USA, where shrubs are encroaching into native grassland. We evaluate a conceptual model which posits that the development of biotic and abiotic structural connectivity is due to ecogeomorphic feedbacks. Three hypotheses are evaluated: 1. Over the shrub-encroachment gradient, the difference in soil properties under each surface-cover type will change non-linearly, becoming increasingly different; 2. There will be a reduction in vegetation cover and an increase in vegetation-patch size that is concurrent with an increase in the spatial heterogeneity of soil properties over the shrub-encroachment gradient; and 3. Over the shrub-encroachment gradient, the range at which soil properties are autocorrelated will progressively exceed the range at which vegetation is autocorrelated. Field-based monitoring of vegetation and soil properties was carried out over a shrub-encroachment gradient at the Sevilleta National Wildlife Refuge in New Mexico, USA. Results of this study show that vegetation cover decreases over the shrub-encroachment gradient, but vegetation-patch size increases, with a concurrent increase in the spatial heterogeneity of soil properties. Typically, there are significant differences in soil properties between non-vegetated and vegetated surfaces, but for grass and shrub patches, there are only significant differences for the biotic soil properties. Results suggest that it is the development of larger, well-connected, non-vegetated patches that is most important in driving the overall behavior of shrub-dominated sites. Results of this study support the hypothesis that feedbacks of functional connectivity reinforce the development of structural connectivity, which increases the resilience of the shrub-dominated state, and thus makes it harder for grasses to re-establish and reverse the vegetation change.</dc:description>
    <dc:subject>2. Zero hunger</dc:subject>
    <dc:subject>0106 biological sciences</dc:subject>
    <dc:subject>570</dc:subject>
    <dc:subject>Ecohydrology</dc:subject>
    <dc:subject>Function - Land degradation.</dc:subject>
    <dc:subject>Structure</dc:subject>
    <dc:subject>910</dc:subject>
    <dc:subject>15. Life on land</dc:subject>
    <dc:subject>Grassland</dc:subject>
    <dc:subject>01 natural sciences</dc:subject>
    <dc:subject>Spatial autocorrelation</dc:subject>
    <dc:subject>Shrubland</dc:subject>
    <dc:subject>0105 earth and related environmental sciences</dc:subject>
    <dc:creator>Turnbull, Laura, Brazier, Richard E., Wainwright, John, Bol, Roland, </dc:creator>
    <dc:date>2010-09-30</dc:date>
    <dc:type>journalpaper</dc:type>
    <dct:abstract>In this study, we investigate changes in ecosystem structure that occur over a gradient of land-degradation in the southwestern USA, where shrubs are encroaching into native grassland. We evaluate a conceptual model which posits that the development of biotic and abiotic structural connectivity is due to ecogeomorphic feedbacks. Three hypotheses are evaluated: 1. Over the shrub-encroachment gradient, the difference in soil properties under each surface-cover type will change non-linearly, becoming increasingly different; 2. There will be a reduction in vegetation cover and an increase in vegetation-patch size that is concurrent with an increase in the spatial heterogeneity of soil properties over the shrub-encroachment gradient; and 3. Over the shrub-encroachment gradient, the range at which soil properties are autocorrelated will progressively exceed the range at which vegetation is autocorrelated. Field-based monitoring of vegetation and soil properties was carried out over a shrub-encroachment gradient at the Sevilleta National Wildlife Refuge in New Mexico, USA. Results of this study show that vegetation cover decreases over the shrub-encroachment gradient, but vegetation-patch size increases, with a concurrent increase in the spatial heterogeneity of soil properties. Typically, there are significant differences in soil properties between non-vegetated and vegetated surfaces, but for grass and shrub patches, there are only significant differences for the biotic soil properties. Results suggest that it is the development of larger, well-connected, non-vegetated patches that is most important in driving the overall behavior of shrub-dominated sites. Results of this study support the hypothesis that feedbacks of functional connectivity reinforce the development of structural connectivity, which increases the resilience of the shrub-dominated state, and thus makes it harder for grasses to re-establish and reverse the vegetation change.</dct:abstract>
    <dc:title>Biotic And Abiotic Changes In Ecosystem Structure Over A Shrub-Encroachment Gradient In The Southwestern Usa</dc:title>
    <dc:identifier>10.1007/s10021-010-9384-8</dc:identifier>
    <dct:references>https://doi.org/10.1007/s10021-010-9384-8</dct:references>
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