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2. Projected Changes to Hydroclimate Seasonality in the Continental United States

Author

Marvel, Kate, Cook, Benjamin I, Bonfils, Céline, Smerdon, Jason E, Williams, A Park, and Liu, Haibo

Subjects
Climate Action, drought, hydroclimate, CMIP6, future, seasonality, projections, Atmospheric Sciences, Physical Geography and Environmental Geoscience, Environmental Science and Management
Published
2021

3. Disentangling the Regional Climate Impacts of Competing Vegetation Responses to Elevated Atmospheric CO2

Author

McDermid, Sonali Shukla, Cook, Benjamin I, De Kauwe, Martin G, Mankin, Justin, Smerdon, Jason E, Williams, A Park, Seager, Richard, Puma, Michael J, Aleinov, Igor, Kelley, Maxwell, and Nazarenko, Larissa

Subjects
Climate Action, Clean Water and Sanitation, Atmospheric Sciences, Physical Geography and Environmental Geoscience
Abstract

Biophysical vegetation responses to elevated atmospheric carbon dioxide (CO2) affect regional hydroclimate through two competing mechanisms. Higher CO2 increases leaf area (LAI), thereby increasing transpiration and water losses. Simultaneously, elevated CO2 reduces stomatal conductance and transpiration, thereby increasing rootzone soil moisture. Which mechanism dominates in the future is highly uncertain, partly because these two processes are difficult to explicitly separate within dynamic vegetation models. We address this challenge by using the GISS ModelE global climate model to conduct a novel set of idealized 2×CO2 sensitivity experiments to: evaluate the total vegetation biophysical contribution to regional climate change under high CO2; and quantify the separate contributions of enhanced LAI and reduced stomatal conductance to regional hydroclimate responses. We find that increased LAI exacerbates soil moisture deficits across the sub-tropics and more water-limited regions, but also attenuates warming by ∼0.5-1°C in the US Southwest, Central Asia, Southeast Asia, and northern South America. Reduced stomatal conductance effects contribute ∼1°C of summertime warming. For some regions, enhanced LAI and reduced stomatal conductance produce nonlinear and either competing or mutually amplifying hydroclimate responses. In northeastern Australia, these effects combine to exacerbate radiation-forced warming and contribute to year-round water limitation. Conversely, at higher latitudes these combined effects result in less warming than would otherwise be predicted due to nonlinear responses. These results highlight substantial regional variation in CO2-driven vegetation responses and the importance of improving model representations of these processes to better quantify regional hydroclimate impacts.

Published
2021

4. U.S. Pacific Coastal Droughts Are Predominantly Driven by Internal Atmospheric Variability

Author

Baek, Seung H, Smerdon, Jason E, Cook, Benjamin I, and Williams, A Park

Subjects
Climate Action, Life Below Water, Drought, Atmosphere-ocean interaction, Hydrology, Atmospheric Sciences, Oceanography, Geomatic Engineering, Meteorology & Atmospheric Sciences
Abstract

AbstractDroughts that span the states of Washington, Oregon, and California are rare but devastating due to their large spatial coverage and potential loss of redundancies in water, agricultural, and fire-fighting resources. Such pan-coastal droughts [which we define using boreal summer volumetric soil moisture along the U.S. Pacific coast (32°–50°N, 115°–127°W)] require a more precise understanding of the roles played by the Pacific Ocean and internal atmospheric variability. We employ 16-member ensembles of the Community Atmosphere Model version 5 and Community Climate Model version 3 forced with observed sea surface temperatures (SSTs) from 1856 to 2012 to separate and quantify the influences of the tropical Pacific and internal atmospheric variability on pan-coastal droughts; all other boundary conditions are kept at climatological levels to explicitly isolate for the impacts of SST changes. Internal atmospheric variability is the dominant driver of pan-coastal droughts, accounting for 84% of their severity, and can reliably generate pan-coastal droughts even when ocean conditions do not favor drought. Cold phases of the Pacific Ocean play a secondary role and contribute, on average, only 16% to pan-coastal drought severity. Spatiotemporal analyses of precipitation and soil moisture along the U.S. Pacific coast corroborate these findings and identify an antiphased wet–dry dipole pattern induced by the Pacific to play a more secondary role. Our model framework expands on previous observational analyses that point to the spatially uniform forcing of internal atmospheric variability as the more dominant mode of hydroclimate variability along the U.S. Pacific coast. The secondary nature of oceanic forcing suggests limited predictability of pan-continental droughts.

Published
2021

5. Publisher Correction: Soil moisture–atmosphere feedbacks mitigate declining water availability in drylands

Author

Zhou, Sha, Williams, A Park, Lintner, Benjamin R, Berg, Alexis M, Zhang, Yao, Keenan, Trevor F, Cook, Benjamin I, Hagemann, Stefan, Seneviratne, Sonia I, and Gentine, Pierre

Subjects
Atmospheric Sciences, Physical Geography and Environmental Geoscience, Environmental Science and Management
Abstract

In the version of this Article originally published, the multiplication symbol was mistakenly used instead of the dot product in equations (1) and (4)–(11). This has now been corrected in the online versions of the Article.

Published
2021

6. Soil moisture–atmosphere feedbacks mitigate declining water availability in drylands

Author

Zhou, Sha, Williams, A Park, Lintner, Benjamin R, Berg, Alexis M, Zhang, Yao, Keenan, Trevor F, Cook, Benjamin I, Hagemann, Stefan, Seneviratne, Sonia I, and Gentine, Pierre

Subjects
Atmospheric Sciences, Physical Geography and Environmental Geoscience, Environmental Science and Management
Abstract

Global warming alters surface water availability (precipitation minus evapotranspiration, P–E) and hence freshwater resources. However, the influence of land–atmosphere feedbacks on future P–E changes and the underlying mechanisms remain unclear. Here we demonstrate that soil moisture (SM) strongly impacts future P–E changes, especially in drylands, by regulating evapotranspiration and atmospheric moisture inflow. Using modelling and empirical approaches, we find a consistent negative SM feedback on P–E, which may offset ~60% of the decline in dryland P–E otherwise expected in the absence of SM feedbacks. The negative feedback is not caused by atmospheric thermodynamic responses to declining SM; rather, reduced SM, in addition to limiting evapotranspiration, regulates atmospheric circulation and vertical ascent to enhance moisture transport into drylands. This SM effect is a large source of uncertainty in projected dryland P–E changes, underscoring the need to better constrain future SM changes and improve the representation of SM–atmosphere processes in models.

Published
2021

8. Dynamics, variability, and change in seasonal precipitation reconstructions for North America Dynamics, variability, and change in seasonal precipitation reconstructions for North America

Author

Stahle, David W, Cook, Edward R, Burnette, Dorian J, Torbenson, Max CA, Howard, Ian M, Griffin, Daniel, Diaz, Jose Villanueva, Cook, Benjamin I, Williams, A Park, Watson, Emma, Sauchyn, David J, Pederson, Neil, Woodhouse, Connie A, Pederson, Gregory T, Meko, David, Coulthard, Bethany, and Crawford, Christopher J

Subjects
Earth Sciences, Oceanography, Climate Change Science, Climate Action, Atmospheric Sciences, Geomatic Engineering, Meteorology & Atmospheric Sciences, Atmospheric sciences, Climate change science
Abstract

Abstract: Cool- and warm-season precipitation totals have been reconstructed on a gridded basis for North America using 439 tree-ring chronologies correlated with December–April totals and 547 different chronologies correlated with May–July totals. These discrete seasonal chronologies are not significantly correlated with the alternate season; the December–April reconstructions are skillful over most of the southern and western United States and north-central Mexico, and the May–July estimates have skill over most of the United States, southwestern Canada, and northeastern Mexico. Both the strong continent-wide El Niño–Southern Oscillation (ENSO) signal embedded in the cool-season reconstructions and the Arctic Oscillation signal registered by the warm-season estimates faithfully reproduce the sign, intensity, and spatial patterns of these ocean–atmospheric influences on North American precipitation as recorded with instrumental data. The reconstructions are included in the North American Seasonal Precipitation Atlas (NASPA) and provide insight into decadal droughts and pluvials. They indicate that the sixteenth-century megadrought, the most severe and sustained North American drought of the past 500 years, was the combined result of three distinct seasonal droughts, each bearing unique spatial patterns potentially associated with seasonal forcing from ENSO, the Arctic Oscillation, and the Atlantic multidecadal oscillation. Significant 200–500-yr-long trends toward increased precipitation have been detected in the cool- and warm-season reconstructions for eastern North America. These seasonal precipitation changes appear to be part of the positive moisture trend measured in other paleoclimate proxies for the eastern area that began as a result of natural forcing before the industrial revolution and may have recently been enhanced by anthropogenic climate change.

Published
2020

9. Land–atmosphere feedbacks exacerbate concurrent soil drought and atmospheric aridity

Author

Zhou, Sha, Williams, A Park, Berg, Alexis M, Cook, Benjamin I, Zhang, Yao, Hagemann, Stefan, Lorenz, Ruth, Seneviratne, Sonia I, and Gentine, Pierre

Subjects
Earth Sciences, Atmospheric Sciences, Ecology, Biological Sciences, Atmosphere, Climate Change, Droughts, Feedback, Geographic Mapping, Humidity, Models, Theoretical, Soil, Weather, soil moisture, vapor pressure deficit, compound extreme events, GLACE-CMIP5
Abstract

Compound extremes such as cooccurring soil drought (low soil moisture) and atmospheric aridity (high vapor pressure deficit) can be disastrous for natural and societal systems. Soil drought and atmospheric aridity are 2 main physiological stressors driving widespread vegetation mortality and reduced terrestrial carbon uptake. Here, we empirically demonstrate that strong negative coupling between soil moisture and vapor pressure deficit occurs globally, indicating high probability of cooccurring soil drought and atmospheric aridity. Using the Global Land Atmosphere Coupling Experiment (GLACE)-CMIP5 experiment, we further show that concurrent soil drought and atmospheric aridity are greatly exacerbated by land-atmosphere feedbacks. The feedback of soil drought on the atmosphere is largely responsible for enabling atmospheric aridity extremes. In addition, the soil moisture-precipitation feedback acts to amplify precipitation and soil moisture deficits in most regions. CMIP5 models further show that the frequency of concurrent soil drought and atmospheric aridity enhanced by land-atmosphere feedbacks is projected to increase in the 21st century. Importantly, land-atmosphere feedbacks will greatly increase the intensity of both soil drought and atmospheric aridity beyond that expected from changes in mean climate alone.

Published
2019

10. Climate Change Amplification of Natural Drought Variability: The Historic Mid-Twentieth Century North American Drought In a Warmer World Climate Change Amplification of Natural Drought Variability: The Historic Mid-Twentieth Century North American Drought In a Warmer World

Author

Cook, Benjamin I, Seager, Richard, Williams, A Park, Puma, Michael J, McDermid, Sonali, Kelley, Maxwell, and Nazarenko, Larissa

Subjects
Climate Action, North America, Drought, Climate change, Climate models, Atmospheric Sciences, Oceanography, Geomatic Engineering, Meteorology & Atmospheric Sciences
Abstract

AbstractIn the mid-twentieth century (1948–57), North America experienced a severe drought forced by cold tropical Pacific sea surface temperatures (SSTs). If these SSTs recurred, it would likely cause another drought, but in a world substantially warmer than the one in which the original event took place. We use a 20-member ensemble of the GISS climate model to investigate the drought impacts of a repetition of the mid-twentieth-century SST anomalies in a significantly warmer world. Using observed SSTs and mid-twentieth-century forcings (Hist-DRGHT), the ensemble reproduces the observed precipitation deficits during the cold season (October–March) across the Southwest, southern plains, and Mexico and during the warm season (April–September) in the southern plains and the Southeast. Under analogous SST forcing and enhanced warming (Fut-DRGHT, ≈3 K above preindustrial), cold season precipitation deficits are ameliorated in the Southwest and southern plains and intensified in the Southeast, whereas during the warm season precipitation deficits are enhanced across North America. This occurs primarily from greenhouse gas–forced trends in mean precipitation, rather than changes in SST teleconnections. Cold season runoff deficits in Fut-DRGHT are significantly amplified over the Southeast, but otherwise similar to Hist-DRGHT over the Southwest and southern plains. In the warm season, however, runoff and soil moisture deficits during Fut-DRGHT are significantly amplified across the southern United States, a consequence of enhanced precipitation deficits and increased evaporative losses due to warming. Our study highlights how internal variability and greenhouse gas–forced trends in hydroclimate are likely to interact over North America, including how changes in both precipitation and evaporative demand will affect future drought.

Published
2019

11. Dynamics and variability of the spring dry season in the United States Southwest as observed in AmeriFlux and NLDAS-2 data Dynamics and variability of the spring dry season in the United States Southwest as observed in AmeriFlux and NLDAS-2 data

Author

Pascolini-Campbell, Madeleine, Seager, Richard, Williams, A Park, Cook, Benjamin I, and Pinson, Ariane O

Subjects
Climate Action, North America, Climate records, Land surface model, Climate variability, Spring season, Ecosystem effects, Atmospheric Sciences, Meteorology & Atmospheric Sciences
Abstract

Abstract The spring dry season occurring in an arid region of the southwestern United States, which receives both winter storm track and summer monsoon precipitation, is investigated. Bimodal precipitation and vegetation growth provide an opportunity to assess multiple climate mechanisms and their impact on hydroclimate and ecosystems. We detect multiple shifts from wet to drier conditions in the observational record and land surface model output. Focusing on the recent dry period, a shift in the late 1990s resulted in earlier and greater spring soil moisture draw down, and later and reduced spring vegetation green-up, compared to a prior wet period (1979–97). A simple soil moisture balance model shows this shift is driven by changes in winter precipitation. The recent post-1999 dry period and an earlier one from 1948 to 1966 are both related to the cool tropics phase of Pacific decadal variability, which influences winter precipitation. In agreement with other studies for the southwestern United States, we find the recent drought cannot be explained in terms of precipitation alone, but also is due to the rising influence of temperature, thus highlighting the sensitivity of this region to warming temperatures. Future changes in the spring dry season will therefore be affected by how tropical decadal variability evolves, and also by emerging trends due to human-driven warming.

Published
2019

14. Investigating the causes of increased 20th-century fall precipitation over the southeastern United States.

Author

Bishop, Daniel A, Williams, A Park, Seager, Richard, Fiore, Arlene M, Cook, Benjamin I, Mankin, Justin S, Singh, Deepti, Smerdon, Jason E, and Rao, Mukund P

Subjects
drought, hydroclimate, moisture transport, pluvial, subtropical High, North America, Atmospheric circulation, Forcing, Mass fluxes, transport, Precipitation, Climate variability, Atmospheric Sciences, Oceanography, Geomatic Engineering, Meteorology & Atmospheric Sciences
Abstract

Much of the eastern United States (US) experienced increased precipitation over the 20th century. Characterizing these trends and their causes is critical for assessing future hydroclimate risks. Here, US precipitation trends are analyzed during 1895-2016, revealing that fall precipitation in the southeastern region north of the Gulf of Mexico (SE-Gulf) increased by nearly 40%, primarily increasing after the mid-1900s. As fall is the climatological dry season in the SE-Gulf and precipitation in other seasons changed insignificantly, the seasonal precipitation cycle diminished substantially. The increase in SE-Gulf fall precipitation was caused by increased southerly moisture transport from the Gulf of Mexico, which was almost entirely driven by stronger winds associated with enhanced anticyclonic circulation west of the North Atlantic Subtropical High (NASH) and not by increases in specific humidity. Atmospheric models forced by observed SSTs and fully-coupled models forced by historical anthropogenic forcing do not robustly simulate 20th-century fall wetting in the SE-Gulf. SST-forced atmospheric models do simulate an intensified anticyclonic low-level circulation around the NASH, but the modeled intensification occurred farther west than observed. CMIP5 analyses suggest an increased likelihood of positive SE-Gulf fall precipitation trends given historical and future GHG forcing. Nevertheless, individual model simulations (both SST-forced and fully-coupled) only very rarely produce the observed magnitude of the SE-Gulf fall precipitation trend. Further research into model representation of the western ridge of the fall NASH is needed, which will help us better predict whether 20th-century increases in SE-Gulf fall precipitation will persist into the future.

Published
2018

15. Revisiting the Leading Drivers of Pacific Coastal Drought Variability in the Contiguous United States

Author

Cook, Benjamin I, Williams, A Park, Mankin, Justin S, Seager, Richard, Smerdon, Jason E, and Singh, Deepti

Subjects
Atmospheric Sciences, Oceanography, Geomatic Engineering, Meteorology & Atmospheric Sciences
Abstract

Abstract Coastal droughts that simultaneously affect California, Oregon, and Washington are rare, but they have extensive and severe impacts (e.g., wildfire and agriculture). To better understand these events, historical observations are used to investigate 1) drought variability along the Pacific coast of the contiguous United States and 2) years when extreme drought affects the entire coast. The leading pattern of cold-season (October–March) precipitation variability along the Pacific coast favors spatially coherent moisture anomalies, accounting for >40% of the underlying variance, and is forced primarily by internal atmospheric dynamics. This contrasts with a much weaker dipole mode (~20% of precipitation variability) characterized by antiphased moisture anomalies across 40°N and strong correlations with tropical Pacific sea surface temperatures (SSTs). Sixteen coastal-wide summer droughts occurred from 1895 to 2016 (clustering in the 1920s–1930s and post-2000), events most strongly linked with the leading precipitation mode and internal atmospheric variability. The frequency of landfalling atmospheric rivers south of 40°N is sharply reduced during coastal droughts but not north of this boundary, where their frequency is more strongly influenced by the dipole. The lack of a consistent pattern of SST forcing during coastal droughts suggests little potential for skillful seasonal predictions. However, their tendency to cluster in time and the impact of warming during recent droughts may help inform decadal and longer-term drought risks.

Published
2018

16. The curious case of projected 21st-century drying but greening in the American West

Author

Mankin, Justin S, Smerdon, Jason E, Cook, Benjamin I, Williams, A Park, and Seager, Richard

Subjects
Earth Sciences, Oceanography, Atmospheric Sciences, Climate Change Science, Climate Action, Geomatic Engineering, Meteorology & Atmospheric Sciences, Atmospheric sciences, Climate change science
Abstract

Climate models project significant twenty-first-century declines in water availability over the American West from anthropogenic warming. However, the physical mechanisms underpinning this response are poorly characterized, as are the uncertainties from vegetation's modulation of evaporative losses. To understand the drivers and uncertainties of future hydroclimate in the American West, a 35-member single model ensemble is used to examine the response of summer soil moisture and runoff to anthropogenic forcing. Widespread dry season soil moisture declines occur across the region despite increases in total water-year precipitation and ubiquitous increases in plant water-use efficiency. These modeled soil moisture declines are initially forced by significant snowpack losses that directly diminish summer soil water, even in regions where water-year precipitation increases. When snowpack priming is coupled with a warming- and CO2-induced shift in phenology and increased primary production, widespread increases in leaf area further reduces summer soil moisture and runoff by outpacing decreased stomatal conductance from high CO2. The net effects lead to the cooccurrence of both a "greener" and "drier" future across the western United States. Because simulated vegetation exerts a large influence on predicted changes in water availability in the American West, these findings highlight the importance of reducing the substantial uncertainties in the ecological processes increasingly incorporated into numerical Earth system models.

Published
2017

17. The 2016 Southeastern U.S. Drought: An Extreme Departure From Centennial Wetting and Cooling

Author

Williams, A Park, Cook, Benjamin I, Smerdon, Jason E, Bishop, Daniel A, Seager, Richard, and Mankin, Justin S

Subjects
Atmospheric Sciences, Physical Geography and Environmental Geoscience
Abstract

The fall 2016 drought in the southeastern United States (SE US) appeared exceptional based on its widespread impacts, but the current monitoring framework that only extends from 1979-present does not readily facilitate evaluation of soil-moisture anomalies in a centennial context. A new method to extend monthly gridded soil-moisture estimates back to 1895 is developed, indicating that since 1895, October-November 2016 soil moisture (0-200 cm) in the SE US was likely the second lowest on record, behind 1954. This severe drought developed rapidly and was brought on by low September-November precipitation and record-high September-November daily maximum temperatures (Tmax). Record Tmax drove record-high atmospheric moisture demand, accounting for 28% of the October-November 2016 soil-moisture anomaly. Drought and heat in fall 2016 contrasted with 20th-century wetting and cooling in the region, but resembled conditions more common from 1895-1956. Dynamically, the exceptional drying in fall 2016 was driven by anomalous ridging over the central United States that reduced south-southwesterly moisture transports into the SE US by approximately 75%. These circulation anomalies were likely promoted by a moderate La Niña and warmth in the tropical Atlantic, but these processes accounted for very little of the SE US drying in fall 2016, implying a large role for internal atmospheric variability. The extended analysis back to 1895 indicates that SE US droughts as strong as the 2016 event are more likely than indicated from a shorter 60-year perspective, and continued multi-decadal swings in precipitation may combine with future warming to further enhance the likelihood of such events.

Published
2017

18. Precipitation, Temperature, and Teleconnection Signals across the Combined North American, Monsoon Asia, and Old World Drought Atlases

Author

Baek, Seung H, Smerdon, Jason E, Coats, Sloan, Williams, A Park, Cook, Benjamin I, Cook, Edward R, and Seager, Richard

Subjects
Mental Health, Climate Action, Atmospheric Sciences, Oceanography, Geomatic Engineering, Meteorology & Atmospheric Sciences
Abstract

The tree-ring-based North American Drought Atlas (NADA), Monsoon Asia Drought Atlas (MADA), and Old World Drought Atlas (OWDA) collectively yield a near-hemispheric gridded reconstruction of hydroclimate variability over the last millennium. To test the robustness of the large-scale representation of hydroclimate variability across the drought atlases, the joint expression of seasonal climate variability and teleconnections in the NADA, MADA, and OWDA are compared against two global, observation-based PDSI products. Predominantly positive (negative) correlations are determined between seasonal precipitation (surface air temperature) and collocated tree-ring-based PDSI, with average Pearson's correlation coefficients increasing in magnitude from boreal winter to summer. For precipitation, these correlations tend to be stronger in the boreal winter and summer when calculated for the observed PDSI record, while remaining similar for temperature. Notwithstanding these differences, the drought atlases robustly express teleconnection patterns associated with the El Niño-Southern Oscillation (ENSO), North Atlantic Oscillation (NAO), Pacific Decadal Oscillation (PDO), and Atlantic Multidecadal Oscillation (AMO). These expressions exist in the drought atlas estimates of boreal summer PDSI despite the fact that these modes of climate variability are dominant in boreal winter, with the exception of the Atlantic Multidecadal Oscillation. ENSO and NAO teleconnection patterns in the drought atlases are particularly consistent with their well-known dominant expressions in boreal winter and over the OWDA domain, respectively. Collectively, our findings confirm that the joint Northern Hemisphere drought atlases robustly reflect large-scale patterns of hydroclimate variability on seasonal to multidecadal timescales over the 20th century and are likely to provide similarly robust estimates of hydroclimate variability prior to the existence of widespread instrumental data.

Published
2017

19. Western Pacific hydroclimate linked to global climate variability over the past two millennia

Author

Griffiths, Michael L, Kimbrough, Alena K, Gagan, Michael K, Drysdale, Russell N, Cole, Julia E, Johnson, Kathleen R, Zhao, Jian-Xin, Cook, Benjamin I, Hellstrom, John C, and Hantoro, Wahyoe S

Subjects
Oceanography, Physical Geography and Environmental Geoscience, Earth Sciences, Atmospheric Sciences, Geology, Climate Action
Abstract

Interdecadal modes of tropical Pacific ocean-atmosphere circulation have a strong influence on global temperature, yet the extent to which these phenomena influence global climate on multicentury timescales is still poorly known. Here we present a 2,000-year, multiproxy reconstruction of western Pacific hydroclimate from two speleothem records for southeastern Indonesia. The composite record shows pronounced shifts in monsoon rainfall that are antiphased with precipitation records for East Asia and the central-eastern equatorial Pacific. These meridional and zonal patterns are best explained by a poleward expansion of the Australasian Intertropical Convergence Zone and weakening of the Pacific Walker circulation (PWC) between ∼1000 and 1500 CE Conversely, an equatorward contraction of the Intertropical Convergence Zone and strengthened PWC occurred between ∼1500 and 1900 CE. Our findings, together with climate model simulations, highlight the likelihood that century-scale variations in tropical Pacific climate modes can significantly modulate radiatively forced shifts in global temperature.

Published
2016

20. Divergent Regional Climate Consequences of Maintaining Current Irrigation Rates in the 21st Century

Author

Cook, Benjamin I., McDermid, Sonali, Puma, Michael, Williams, A. Park, Seager, Richard, Kelley, Maxwell, Nazarenko, Larissa S., and Aleinov, Igor D.

Subjects
Climate Action, climate change, Irrigation farming--Climatic factors, Greenhouse gases--Environmental aspects, Life on Land, Land use, Climatic changes, Irrigation, irrigation, Physical Geography and Environmental Geoscience, Atmospheric Sciences
Abstract

There is strong evidence that the expansion and intensification of irrigation over the twentieth century has affected climate in many regions. However, it remains uncertain if these irrigation effects, including buffered warming trends, will weaken or persist under future climate change conditions. Using a 20-member climate model ensemble simulation, we demonstrate that irrigation will continue to attenuate greenhouse gas-forced warming and soil moisture drying in many regions over the 21st century, including Mexico, the Mediterranean, Southwest Asia, and China. Notably, this occurs without any further expansion or intensification of irrigation beyond current levels, even while greenhouse gas forcing steadily increases. However, the magnitude and significance of these moderating irrigation effects vary across regions and are highly sensitive to the background climate state and the degree to which evapotranspiration is supply (moisture) versus demand (energy) limited. Further, limitations on water and land availability may restrict our ability to maintain modern irrigation rates into the future. Nevertheless, it is likely that irrigation, alongside other components of intensive land management, will continue to strongly modulate regional climate impacts in the future. Irrigation should therefore be considered in conjunction with other key regional anthropogenic forcings (e.g., land cover change and aerosols) when investigating the local manifestation of global climate drivers (e.g., greenhouse gases) in model projections.

Published
2020

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