Global assessment of trends in wetting and drying over land

Greve, Peter; Orlowsky, Boris; Mueller, Brigitte; Sheffield, Justin; Reichstein, Markus; Seneviratne, Sonia I.

doi:10.1038/ngeo2247

Cited by 696 publications

(630 citation statements)

References 23 publications

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“…In the last decades, the severity of droughts in the IP has increased, together with an increased tendency for dryness and decrease of vegetation cover, due to the higher atmospheric evaporative demand [28,37]. These agree with the findings of Greve et al [38] that identified the Southwest of the IP as one hot spot of the pattern "dry gets drier." The need for a deeper knowledge of drought frequency, duration, and intensity over the IP during the last century is reinforced by the findings by Hoerling et al [39] using Sea Surface Temperature data that have shown that the period of 1970-2010 over the Mediterranean region was considered drier when compared with 1901-1970.…”

Section: Introductionsupporting

confidence: 82%

“…Several authors have discussed the role of including ET 0 in the trend analysis of droughts at global [25,31,32,38,56], continental [35,67], and national or regional scales [68,69]. Using distinct datasets and/or different drought indices for various regions of the Mediterranean basin and considering shorter periods, several authors identified colder/wetter and warmer/dryer periods over different regions [22,25,44,70,71].…”

Section: Discussionmentioning

confidence: 99%

“…Vicente-Serrano et al [28] also pointed to a rise of drought severity in the last 5 decades, together with an increased tendency for dryness and stressed that this increment is independent of the evapotranspiration approach used. Similarly, the global assessment of wetting/drying trends during the period 1948-2005 performed by Greve and coauthors [38] has identified the Southwest of the IP as one hot spot of the pattern "dry gets drier. "…”

Section: Discussionmentioning

confidence: 99%

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Drought Trends in the Iberian Peninsula over the Last 112 Years

Páscoa

Gouveia

Russo

et al. 2017

Advances in Meteorology

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The Iberian Peninsula (IP) is a drought-prone area located in the Mediterranean which presents a significant tendency towards dryness during the last decades, reinforcing the need for a continuous monitoring of drought. The long-term evolution of drought in the IP is analyzed, using the Standardized Precipitation Evaporation Index (SPEI) and the Standardized Precipitation Index (SPI), for the period of 1901-2012 and for three subperiods: 1901-1937, 1938-1974, and 1975-2012. SPI and SPEI were calculated with a 12-month time scale, using data from the Climatic Research Unit (CRU) database. Trends in the drought indices, precipitation, and reference evapotranspiration (ET 0 ) were analysed and series of drought duration, drought magnitude, time between drought events, and mean intensity of the events were computed. SPI and SPEI significant trends show areas with opposite signals in the period 1901-2012, mainly associated with precipitation trends, which are significant and positive in the northwestern region and significant and negative in the southern areas. Additionally, SPEI identified dryer conditions and an increase in the area affected by droughts, which agrees with the increase in ET 0 . The same spatial differences were identified in the drought duration, magnitude, mean intensity, and time between drought events.

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Section: Introductionsupporting

confidence: 82%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Drought Trends in the Iberian Peninsula over the Last 112 Years

Páscoa

Gouveia

Russo

et al. 2017

Advances in Meteorology

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“…Looking to the future, it will become even more important to separately resolve VPD and soil moisture effects on ecosystem functioning. VPD is highly sensitive to changes in air temperature and is thus expected to rise globally in the future 1,20 . On the other hand, projected changes in precipitation and soil moisture are less certain, more spatially variable, and smaller in relative magnitude 21 .…”

mentioning

confidence: 99%

The increasing importance of atmospheric demand for ecosystem water and carbon fluxes

et al. 2016

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Soil moisture supply and atmospheric demand for water independently limit-and profoundly a ect-vegetation productivity and water use during periods of hydrologic stress [1][2][3][4] . Disentangling the impact of these two drivers on ecosystem carbon and water cycling is di cult because they are often correlated, and experimental tools for manipulating atmospheric demand in the field are lacking. Consequently, the role of atmospheric demand is often not adequately factored into experiments or represented in models 5-7 . Here we show that atmospheric demand limits surface conductance and evapotranspiration to a greater extent than soil moisture in many biomes, including mesic forests that are of particular importance to the terrestrial carbon sink 8,9 . Further, using projections from ten general circulation models, we show that climate change will increase the importance of atmospheric constraints to carbon and water fluxes in all ecosystems. Consequently, atmospheric demand will become increasingly important for vegetation function, accounting for >70% of growing season limitation to surface conductance in mesic temperate forests. Our results suggest that failure to consider the limiting role of atmospheric demand in experimental designs, simulation models and land management strategies will lead to incorrect projections of ecosystem responses to future climate conditions. Ecosystem moisture stress is often characterized by changes in soil water availability 10,11 . Declining soil moisture impedes the movement of water to evaporating sites at the soil or leaf surface 12 , reducing the surface conductance to water vapour (G S )-a key determinant of carbon and water cycling-and thereby evapotranspiration (ET). However, atmospheric demand for water, which is directly related to the atmospheric vapour pressure deficit (VPD), also affects G S and ET. Plants close their stomata to prevent excessive water loss when VPD is high [13][14][15][16] and thus, increases in VPD during periods of hydrologic stress represent an independent constraint on plant carbon uptake and water use in ecosystems.While the plant physiological community has long recognized the critical role of VPD in determining plant functioning, VPD is often overlooked in many fields of hydrologic and climate science. For example, precipitation manipulation experiments are frequently used to draw conclusions about ecosystem response to drought stress, even though VPD is unaffected by precipitation manipulation 10 . Some terrestrial ecosystem and ecohydrological models do not permit stomatal conductance to vary with atmospheric demand 5,11 . Many models designed to capture these impacts rely on empirical parameterizations for soil moisture and VPD stress that promote compensating effects and model equifinality 5 , and/or use relative humidity instead of VPD as the primary driver, with significant consequences for projections of

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“…The canonical description of precipitation changes under increasing CO 2 has been that the "wet get wetter" and the "dry get drier" [19], however this is a poor characterization of the change in pattern of precipitation change over land observed in the historical period [20], or predicted for the future [21][22][23].…”

Section: Supply and Demandmentioning

confidence: 99%

Plants and Drought in a Changing Climate

Swann¹

2018

Preprint

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Purpose of review Climate is changing in response to rising concentrations of atmospheric CO 2 and it is commonly asserted that this will cause droughts to become more frequent and severe. However, different metrics of drought give diverging estimates of future impacts. I present a summary of the significant yet underappreciated influence that plant stomatal and growth responses to CO 2 have on drought, and highlight new insights into the impacts of drought on plants in a warmer world. Recent findings Plants influence the water availability on land, and thus reduce the duration and intensity of droughts under higher CO 2 conditions. Plants are concurrently more vulnerable to mortality when droughts occur under hotter conditions. Summary The frequency and severity of drought in the future depends on the response of plants to a changing climate-ignoring plant responses leads to over-prediction of drought. Nonetheless, the impact of current frequencies of drought on plants could lead to higher mortality rates in the future as plants must withstand drought stress simultaneously with hotter temperatures.

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Global assessment of trends in wetting and drying over land

Cited by 696 publications

References 23 publications

Drought Trends in the Iberian Peninsula over the Last 112 Years

Drought Trends in the Iberian Peninsula over the Last 112 Years

The increasing importance of atmospheric demand for ecosystem water and carbon fluxes

Plants and Drought in a Changing Climate

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