Structural Changes of Desertified and Managed Shrubland Landscapes in Response to Drought: Spectral, Spatial and Temporal Analyses

Paz‐Kagan, Tarin; Panov, Natalya; Shachak, Moshe; Zaady, Eli; Karnieli, Arnon

doi:10.3390/rs6098134

Cited by 19 publications

(15 citation statements)

References 88 publications

(105 reference statements)

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“…Implementation of remote sensing for the identification of structural changes in shrublands in response to droughts was presented by Paz-Kagan [5]. A study of damages to Mediterranean forests in Israel has been reported by, among others, Volcani et al [48] and Dorman et al [49], the latter using a normalized-difference water index to represent water content in trees.…”

Section: Discussionmentioning

confidence: 99%

“…However, there is no information where such reduced rainfall had taken place, and what impact it had on natural ecosystems. According to existing studies, decreasing water availability is expected to reduce productivity in desert-fringe ecosystems in general and in semi-arid shrublands in particular [5][6][7][8]. This article aims at assessing trends of biomass change in the shrublands of the climatic gradient between sub-humid and arid zones in Central Israel as indicators of rainfall variations.…”

Section: Introductionmentioning

confidence: 99%

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Remote Sensing of Shrubland Drying in the South-East Mediterranean, 1995–2010: Water-Use-Efficiency-Based Mapping of Biomass Change

Shoshany

Karnibad

2015

Remote Sensing

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Recent climate studies of the South-Eastern Mediterranean indicate an increase in drought frequencies and decreasing water resources since the turn of the century. A four-phase methodology was developed for assessing above-ground biomass changes in shrublands caused by these recent trends. Firstly, we generalized the function SB = 0.008MAP 1.54 describing the shrublands above-ground biomass (SB) dependence on mean annual precipitation (MAP) for areas of full shrub cover. Secondly, relationships between MAP and NDVI were formalized, allowing an estimation of precipitation levels from observed NDVI values (MAPNDVI). Thirdly, relative water-use efficiency (RWUE) was defined as the ratio between MAPNDVI and MAP. Finally, the function SBRWUE = 0.008MAP 0.54 + RWUE was formalized, utilizing RWUE in estimating shrublands biomass. This methodology was implemented using Landsat TM images (1994 to 2011) for an area between the Judean Mountains and the deserts bordering them to the east and south. More than 50% of the study area revealed low biomass change (±0.2 kg/m

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Remote Sensing of Shrubland Drying in the South-East Mediterranean, 1995–2010: Water-Use-Efficiency-Based Mapping of Biomass Change

Shoshany

Karnibad

2015

Remote Sensing

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“…The availability of longer satellite time series, covering the entire globe, such as the GIMMS dataset, has allowed the analysis of the relationships between climate variability on vegetation dynamics and crop yields both at global or continental scales (Lobell and Field, 2007, Gouveia et al, 2008, Zeng et al, 2013. Different studies for the Mediterranean analyzed the impact of droughts on the natural vegetation and crops using remote sensing data, Lloret et al (2007) and Vicente-Serrano (2007) in Northeast Spain, Lobo and Maisongrande (2006) in France, Gouveia (2009 and in Portugal, Dorman et al (2013), Trigo et al (2010) in the eastern Mediteranean area, Paz-Kagan et al, (2014) GlobCover classification over Mediterranean region was resampled for the GIMMS-NDVI spatial resolution (8 km) based on the mode rule for degradation of thematic maps (Figure 1). …”

Section: Accepted Manuscriptmentioning

confidence: 99%

Drought impacts on vegetation activity in the Mediterranean region: An assessment using remote sensing data and multi-scale drought indicators

Gouveia

Trigo

Beguerı́a

et al. 2017

Global and Planetary Change

196

110

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The present work analyzes the drought impacts on vegetation over the entire Mediterranean basin, with the purpose of determining the vegetation communities, regions and seasons at which vegetation is driven by drought. Our approach is based on the use of remote sensing data and a multi-scalar drought index. Correlation maps between fields of monthly Normalized Difference Vegetation Index (NDVI) and the Standardized PrecipitationEvapotranspiration Index (SPEI) at different time scales (1-24 months) were computed for

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“…In this study, one standard deviation (STD) was determined as a threshold based on previous experience with change detection analysis [53,56,57]. The direction of the change is computed by the angle (θ) of the change vector from the pixel value at these two dates:…”

Section: Cvamentioning

confidence: 99%

Spatio-Temporal Dynamics of Land-Use and Land-Cover in the Mu Us Sandy Land, China, Using the Change Vector Analysis Technique

Karnieli

Qin

et al. 2014

Remote Sensing

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Abstract:The spatial extent of desertified vs. rehabilitated areas in the Mu Us Sandy Land, China, was explored. The area is characterized by complex landscape changes that were caused by different drivers, either natural or anthropogenic, interacting with each other, and resulting in multiple consequences. Two biophysical variables, NDVI, positively correlated with vegetation cover, and albedo, positively correlated with cover of exposed sands, were computed from a time series of merged NOAA-AVHRR and MODIS images (1981 to 2010). Generally, throughout the study period, NDVI increased and albedo decreased. Improved understanding of spatial and temporal dynamics of these environmental processes was achieved by using the Change Vector Analysis (CVA) technique applied to NDVI and albedo data extracted from four sets of consecutive Landsat images, several years apart. Changes were detected for each time step, as well as over the entire period (1978 to 2007). Four categories of land cover were created-vegetation, exposed sands, water bodies and wetlands. The CVA's direction and magnitude enable detecting and quantifying finer changes compared to separate NDVI or albedo difference/ratio images OPEN ACCESS Remote Sens. 2014, 6 9317 and result in pixel-based maps of the change. Each of the four categories has a biophysical meaning that was validated in selected hot-spots, employing very high spatial resolution images (e.g., Ikonos). Selection of images, taking into account inter and intra annual variability of rainfall, enables differentiating between short-term conservancies (e.g., drought) and long-term alterations. NDVI and albedo, although comparable to tasseled cap's brightness and greenness indices, have the advantage of being computed using reflectance values extracted from various Landsat platforms since the early 1970s. It is shown that, over the entire study period, the majority of the Mu Us Sandy Land area remained unchanged. Part of the area (6%), mainly in the east, was under human-induced rehabilitation processes, in terms of increasing vegetation cover. In other areas (5.1%), bare sands were found to expand to the central-north and the southwest of the area.

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Structural Changes of Desertified and Managed Shrubland Landscapes in Response to Drought: Spectral, Spatial and Temporal Analyses

Cited by 19 publications

References 88 publications

Remote Sensing of Shrubland Drying in the South-East Mediterranean, 1995–2010: Water-Use-Efficiency-Based Mapping of Biomass Change

Remote Sensing of Shrubland Drying in the South-East Mediterranean, 1995–2010: Water-Use-Efficiency-Based Mapping of Biomass Change

Drought impacts on vegetation activity in the Mediterranean region: An assessment using remote sensing data and multi-scale drought indicators

Spatio-Temporal Dynamics of Land-Use and Land-Cover in the Mu Us Sandy Land, China, Using the Change Vector Analysis Technique

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