Quantifying and modeling water availability in temperate forests: a review of drought and aridity indices

Speich, Matthias

doi:10.3832/ifor2934-011

Cited by 31 publications

(15 citation statements)

References 91 publications

(185 reference statements)

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“…Cumulative droughts and extreme drought events severely affected forest functioning in Central Europe over 2018 and 2019 (Buras et al, 2019;Trotsiuk et al, 2020), and the intensity of such drought events is expected to increase in the coming decades (Teuling, 2018). SVAT and similar models in particular allow for the quantification of cumulative droughts that cannot be determined from bare soil and climatic data, such as the site water balance (Speich, 2019). In order to develop mitigation and adaptation strategies, we therefore need to be able to upscale these models for assessing the impacts of climate change on forest functions at a larger scale, for which the presented LWFBrook90R package provides convenient solutions.…”

Section: Discussionmentioning

confidence: 99%

“…At the national to regional scale, SVAT models have been connected to climate projections, soil grids and forest inventory data, to determine recent and future trends of water availability and drought stress in climate impact assessment studies (De Cáceres et al, 2015;Ruffault et al, 2014Ruffault et al, , 2013Schmidt-Walter et al, 2019;Schwärzel et al, 2009;Thiele et al, 2017), providing information on future ecosystem services, forest growth conditions, and species suitability to design and implement mitigation and adaptation strategies (Lindner et al, 2010). At the local scale, SVAT models are applied to derive drought indicators (for an overview see Speich, 2019) to understand vitality patterns and growth depressions of forests (Granier et al, 2007;Lebourgeois et al, 2005;Manrique-Alba et al, 2017;Michelot et al, 2012), tree mortality (Allen et al, 2010;Seidl et al, 2017), to estimate crop water requirements (Fischer et al, 2018), and to explain secondary droughtrelated impacts on forests, such as insect infestations (Netherer et al, 2019). Apart from such explanatory applications, SVAT models also offer estimates of water balance components that are difficult to obtain from field measurements (e.g.…”

Section: Introductionmentioning

confidence: 99%

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Advancing simulations of water fluxes, soil moisture and drought stress by using the LWF-Brook90 hydrological model in R

Schmidt-Walter

Trotsiuk

Meusburger

et al. 2020

Agricultural and Forest Meteorology

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Advancing simulations of water fluxes, soil moisture and drought stress by using the LWF-Brook90 hydrological model in R

Schmidt-Walter

Trotsiuk

Meusburger

et al. 2020

Agricultural and Forest Meteorology

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“…To characterize the occurrence of water stress, we used the ratio between ET a and ET crop as the water stress index (WSI) (Eden, 2012; Speich, 2019). Water stress index values <1 reflect conditions when the plant can no longer transpire optimally and reduces its transpiration rate.…”

Section: Methodsmentioning

confidence: 99%

On the impact of increasing drought on the relationship between soil water content and evapotranspiration of a grassland

Rahmati

Groh

Graf

et al. 2020

Vadose Zone Journal

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Weighable lysimeters were used to study the relation between soil water content (SWC) and the actual evapotranspiration (ET a) of grassland under two different climate regimes of Rollesbroich and Selhausen but for an identical soil from Rollesbroich. All components of the water balance were determined from 2012 until 2018. Budyko analysis was used to characterize the hydrological status of the studied sites. Wavelet analysis was also applied to study the power spectrum of ET a , vegetationheight-adjusted reference evapotranspiration (ET crop), and water stress index (WSI) defined as ET a /ET crop , as well as SWC at three different depths and the coherence between SWC and ET a and WSI. The Budyko analysis showed that 2018 resulted in a shift of both locations towards more water-limited conditions, although Rollesbroich remained an energy-limited system. Based on the power spectrum analysis, the annual timescale is the dominant scale for the temporal variability of ET a , ET crop , and SWC. The results also showed that increasing dryness at the energy-limited site led to more temporal variability of SWC at all depths at the annual timescale. Wavelet coherence analysis showed a reduction of the phase shift between SWC and ET a at an annual scale caused by the increase in dryness during the measurement period. We found that phase shifts between SWC and ET a and SWC and WSI were stronger at the water-limited site than at the energy-limited site. The wavelet coherence analysis also showed that from 2014 to 2018, the control of ET a and WSI on SWC increased due to higher dryness of soil.

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“…Under current global climate change trends, extensive semi-arid and desert fringe ecosystems experience declining water resources and increasing atmospheric temperatures (e.g., Tuel and Eltahir, 2020;Pugnaire, et al, 2019;Polade et al, 2017;Maestre et al, 2012;Blondel et al, 2010;Giorgi and Lionello, 2008;Mariotti, 2008;Aussenac, 2002). Since its introduced by De Martonne (1926), the Aridity Index (AI) with its Thornthwaite (Huschke,1959) , Budyko (1974) and UNEP (Barrow, 1992;Greve et al, 2019) versions is widely used to monitor the spread of aridity across these ecosystems (e.g., Pellicone, 2019;Speich, 2019;Traore et al, 2020;Derdous et al, 2021;;and Zomer, 2022). Other aridity and dryness indicators were calculated based on the difference between precipitation and potential evapotranspiration with Bussay et al, (2012) and Vincente-Serrano et al, (2012) relating to it as Water Deficit (WD) while Stephenson (1990), Saha et al, (2020), Kuang-Yu et al (2018), Abatzoglou et al, (2018),…”

Section: Introductionmentioning

confidence: 99%

Climate and Aridity Measures Relationships with Spectral Vegetation Indices across Desert Fringe Shrublands in the South-Eastern Mediterranean Basin

Shoshany

Mozhaeva

2022

Preprint

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Mediterranean regions are hot spots of climate change, where the expected decrease in water resources threatens the sustainability of shrublands at their arid margins. Studying spectral vegetation indices relationships with rainfall and Potential Evapotranspiration (PET) changes across Mediterranean to arid transition zones is instrumental for developing methods for mapping and monitoring the effects of climate change on desert fringe shrublands. Here we examined relationships between 17 spectral vegetation indices (VIs) and four climate and aridity measures: rainfall, PET, Aridity Index (AI) and Water Deficit (WD) calculated at accumulation lags between 1 and 6 months. For this purpose, VIs for 38 sites (100x100 meters each) representing less disturbed areas were extracted from Sentinel 2A images for 3 years with high (2016), low (2017), and average (2018) annual rainfall. Most of the VIs had shown the highest correlation with the four climate and aridity measures at 2 months accumulation interval. While NDVI relationships with climate measures gained the widest use, our data suggest that indices combining NIR and SWIR bands better correlate climate parameters. AI is one of the leading annual measures of dryness worldwide, when calculating it monthly, WD was found to better represent the balance between precipitation and PET across the climate transition zone, and to be better correlated with VI’s. Relationships between NIR and SWIR VIs and Water Deficit may thus facilitate improvements in monitoring and mapping desert fringe shrublands responses to climate change if supported by similar results from wider areas.

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Quantifying and modeling water availability in temperate forests: a review of drought and aridity indices

Cited by 31 publications

References 91 publications

Advancing simulations of water fluxes, soil moisture and drought stress by using the LWF-Brook90 hydrological model in R

Advancing simulations of water fluxes, soil moisture and drought stress by using the LWF-Brook90 hydrological model in R

On the impact of increasing drought on the relationship between soil water content and evapotranspiration of a grassland

Climate and Aridity Measures Relationships with Spectral Vegetation Indices across Desert Fringe Shrublands in the South-Eastern Mediterranean Basin

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