Vegetation as the Bioindicator of Human-induced Degradation in Karst Landscape: Case Study of Waste-filled Dolines

Valjavec, Mateja Breg; Ribeiro, Daniela; Čarni, Andraž

doi:10.3986/ac.v46i1.4712

Cited by 10 publications

(6 citation statements)

References 49 publications

(67 reference statements)

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“…Approximately 91.7% of the cultivated land, 88.3% of the rural population, 94% of the grain output, and 95.7% of the gross national product have originated from counties with some rocky desertification (Auler & Smart, 2003; Nie, Chen, Wang, & Ding, 2014). At the core of these human activities is the constant process of various land uses and settlement establishment to satisfy social and economic development needs, which ultimately leads to the comprehensive development of land resources and human settlements (Bátori et al, 2014; Breg Valjavec, Ribeiro, & Čarni, 2017). Recently, China has undergone a period of rapid urbanisation and sustained economic transformation, which is associated with extensive and intensive land uses (Chen, Yang, Fu, He, & Wang, 2012).…”

Section: Introductionmentioning

confidence: 99%

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Factors influencing the evolution of human‐driven rocky desertification in karst areas

2020

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Karst rocky desertification has become one of the most important e‐environmental problems in China. The mechanisms of rocky desertification caused by land resources use, settlement expansion, population growth, and corresponding ecological responses are unclear. High‐resolution images of a typical karst plateau (Houzhai River Basin) acquired in 1978, 2005, and 2010 and data samples collected in the field in 2015 were used to quantitatively study the factors governing the evolution of rocky desertification driven by human activities. They comprehensively reveal its causes and influencing factors. Results suggest that the rocky desertification in the eastern and southern parts was, generally, more severe than in the western and northern parts of the study region. In the period from 1978 to 2015, no significant changes in the degree of (moderate) rocky desertification were observed. However, decreasing trends were observed for the no‐rocky areas, and slight decrease in rocky areas. The comprehensive indices of rocky desertification in 1978, 2005, 2010, and 2015 were 1.33, 1.24, 1.22, and 1.24, respectively. The rock outcrops in the no‐rocky desertification and potential rocky desertification areas were closely associated with the gravel content, slope gradient, and soil thickness, whereas those in the slight, moderate, and severe rocky desertification areas were primarily associated with the land use, gravel content, and slope gradient. The results suggest that the land use and human settlement were important factors determining the rocky desertification. The rocky desertification in the study area has improved during the period from 1978 to 2015. The main contribution to this improvement originated from the change in land use patterns. Therefore, reasonable management of land use and human settlement distribution can effectively reduce the rocky desertification in a karst area.

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Section: Introductionmentioning

confidence: 99%

“…At the core of these human activities is the constant process of various land uses and settlement establishment to satisfy social and economic development needs, which ultimately leads to the comprehensive development of land resources and human settlements (Bátori et al, 2014;Breg Valjavec, Ribeiro, & Čarni, 2017).…”

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confidence: 99%

Factors influencing the evolution of human‐driven rocky desertification in karst areas

2020

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“…We estimated the abundance of plant species on a 7‐point scale (Braun‐Blanquet, ). This method has already been used in the region for the study of dry grasslands and human‐induced land degradation (Breg Valjavec et al, ; Pipenbaher, Kaligarič, Mason, & Škornik, ).…”

Section: Methodsmentioning

confidence: 99%

“…No studies have so far been carried out from the ecological point of view connected to historical land degradation, nor has the role of cultural dolines in maintaining the biodiversity of the dry and rocky karst landscape been evaluated. Monitoring biodiversity changes can be used to evaluate human-induced degradation (Breg Valjavec, Ribeiro, & Čarni, 2017), to determine the causes of these changes and to develop effective conservation strategies.…”

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confidence: 99%

Human‐induced land degradation and biodiversity of Classical Karst landscape: On the example of enclosed karst depressions (dolines)

2018

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In the karst landscape of the Kras Plateau (south‐west Slovenia), we studied the impact of historical human‐induced land degradation on biodiversity by studying the characteristics and changes in vegetation of degraded and nondegraded karst depressions (dolines). Intensive human‐induced land degradation began as a consequence of the abandonment of traditional land use; thus, many dolines have disappeared by being completely filled with waste material and overgrowth. The study is based on a chronosequence approach and assesses whether vegetation (e.g., community succession stages) can be used as a (bio)indicator of land degradation to estimate approximately the duration of degradation on the basis of the stage of succession. The locations and duration of degradation of dolines were identified in advance by analysing a time series of historical aerial photographs, topographical maps, and digital elevation models. Ecological evaluation was based on sampling the floristic composition and the topsoil. In this study, three vegetation measures were established as indicative of degradation: (a) the appearance of ruderal species, (b) hemeroby, and (c) alien and invasive species. A succession model of degraded karst landscape was produced on the basis of identified chronosequences to assess the long‐term spatial impact of doline degradation on karst biodiversity. The model is showing the tendency towards the vegetation homogenization of karst landscape.

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“…Vegetation cover serves as an indicator of ecosystem state because it responds quickly the changes in environmental conditions (Burger, 2006;Parmar et al, 2016;Lykholat et al, 2018a); it gives the opportunity to make an environmental assessment of a certain territory using phytoindication scales (LaPaix et al, 2009;Ivanova & Zolotova, 2015) and to conduct phytomonitoring of the territory (Klimo et al, 2011;Lykholat et al, 2018b;Jetz et al, 2019;Lashchinskiy et al, 2019). Bioindication properties of biological communities are also used in assessment of level of anthropogenic pollution on aquatic (Ceschin et al, 2010) and terrestrial (Rowe et al, 2015;Baranovski et al, 2016;Faly et al, 2017;Valjavec et al, 2017;Hedwall et al, 2019) ecosystems. Synphytoindication analysis of plant communities involves phytosociological surveys of vegetation and allows the ecosystem state to be defined using the indexes of their biotic components (Didukh, 2012;Bagrikova, 2018).…”

Section: Introductionmentioning

confidence: 99%

Features of ecological differentiation of halophytic, steppe and petrophytic vegetation in the valley of the Liman Kuyalnik (Odesa Oblast)

et al. 2019

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Assessment of key environmental factors that influence vegetation distribution and formation of plant communities is one of the most important challenges in modern phytocenology. Nowadays, several bioindication systems are applied to determine ecological specificity of plant communities and to establish the leading factors for their environmental differentiation. The system most widely used in Europe, that of H. Ellenberg, contains a numerical score on 6 ecological factors. On the example of vegetation of the valley of the Liman Kuyalnik, Y. Didukh developed the synphytoindication method based on evaluation of phytocenoses with respect to 12 ecological factors: 7 edaphic factors and 5 climatic factors; the method determines a more accurate and complete presentation of the analysis. In the valley of the Liman Kuyalnik (Odesa Oblast) the largest area is covered with halophytic and steppe vegetation. Halophytic vegetation (Therosalicornietea, Festuco-Puccinellietea classes, Juncetea maritimi, Bolboschoenetea maritimi) predominated in the shoreline areas of the valley, whereas steppe (Festuco-Brometea) and petrophytic (Sedo-Scleranthetea) vegetation dominated on the slope sites. With the application of DCA-ordination and synphytoindication methods it was established that distribution of plant communities in the hyper-space of the environmental conditions was most strongly correlated with edaphic factors, whereas microclimatic (light intensity) and climatic (thermo-regime) conditions had somewhat less influence on their differentiation. Water regime and level of soil salinity served as key factors for syntaxa of halophytic vegetation; moisture variability and salt regime, as well as soil moisture and carbonate content were key factors for the steppe vegetation, and thermo-regime was the main factor for petrophytic-steppe and petrophytic vegetation. The "eco-spaces" of these groups largely overlap. Halophytic cenoses are characterized by quite wide ecological ranges by most ecological factors. Steppe communities show much less ecological diversity. In the valley of the liman, all the steppe communities were characterized by stenotopicity in relation to most ecological factors; these factors complexly determine the specificity and diversity of biotopes within the valley, which are unique and require protection and the taking of appropriate measures, depending on the changes in activity of one or another limiting factor. Nowadays, the valley of the Liman Kuyalnik is in a state of environmental disaster. The established relationships in ecological differentiation of plant communities will be applied to further monitoring of biodiversity state, preservation and possible restoration of vegetation types that were native for this unique territory.

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Vegetation as the Bioindicator of Human-induced Degradation in Karst Landscape: Case Study of Waste-filled Dolines

Cited by 10 publications

References 49 publications

Factors influencing the evolution of human‐driven rocky desertification in karst areas

Factors influencing the evolution of human‐driven rocky desertification in karst areas

Human‐induced land degradation and biodiversity of Classical Karst landscape: On the example of enclosed karst depressions (dolines)

Features of ecological differentiation of halophytic, steppe and petrophytic vegetation in the valley of the Liman Kuyalnik (Odesa Oblast)

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