Osvaldo E. Sala’s research while affiliated with Arizona State University and other places

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Publications (273)


Major landholdings in the Western United States (a). US Department of defense installations (DOD; red) in the Western United States. Other large landholding organizations shown are Tribal lands (TRB; pink), National Park Service (NPS; blue), Bureau of Land Management (BLM; brown), and the US Forest Service (FS; green). Aridity values in the Western United States (b). Hyperarid (red), arid (orange), semiarid (green), dry subhumid (blue), and mesic (purple) lands for the landholders displayed in (a) are shown.
Conceptual diagram of the supply and demand of ecosystem services on Department of Defense (DoD) lands. The framework highlights DoD policies and land use decisions in the brown polygon in the center, influencing both supply and demand. Stakeholders across spatial scales are shown in the blue polygon, and the potential ecosystem services from the DoD land base are shown in the green polygon. Demands for ecosystem services are expressed via regulations and direct administrative linkages are shown as black arrows, where supply is shown with a green arrow. Demands originate on multiple levels of organization through federal, state, and public institutions, including demands from within the Department of Defense for direct use of lands for military training and other uses. The supply of ecosystem services from DoD lands is provided by different types of ecosystems contained in the land estate but is modulated through both land management decisions and controlled and restricted access to the public on DoD lands: Environmental management and limited accessibility are controls of the flow of ecosystem services to stakeholders.
Net primary productivity (NPP) (g of carbon/m²/year, a) across the Department of Defense (DoD) land base (red polygons) in the Western United States. Boxplot (b) displays distribution of NPP across major land‐holding organizations in the Western United States. Biodiversity across the DoD land base (red, c) in the Western United States, alongside Tribal lands (pink), National Park Service (NPS, blue), Bureau of Land Management (brown), and US Forest Service (green). Values represent an interpolated count of mammal, reptile, and bird species per pixel. Boxplot (d) displays distribution of these interpolated biodiversity values per pixel across major landholding organizations in the Western United States.
Distribution of ecosystem types by area of the Department of Defense land base in drylands of the Western United States. Only ecosystem types over 1000 ha are displayed.
Content analysis of the Integrated Natural Resources Management Plans (INRMPs) of 35 DoD bases in water‐limited landscapes. Common categories of ecosystem services: “cultural”, “supporting”, and “regulating” are included, and “provisioning” had <10 uses across all documents analyzed.
Ecosystem service indicators on military‐managed drylands in the Western United States
  • Article
  • Publisher preview available

November 2024

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36 Reads

Samuel E. Jordan

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Osvaldo E. Sala

Lands devoted to military use are globally important for the production of ecosystem services and for the conservation of biodiversity. The United States has one of the largest military land estates in the world, and most of these areas occur in water‐limited landscapes. Despite many of these areas receiving intense or sustained disturbance from military training activities, the structure and function of ecosystems contained within their boundaries continue to provide critical benefits to people across spatial scales. The land owned and managed by the Department of Defense is subject to regulation across local, state, and federal governing bodies, constraining and shaping both how land management is conducted and how ecosystem services are prioritized. Here, we explored the supply of ecosystem services from military lands in dryland areas of the United States using key indicators of ecosystem services: biodiversity estimates derived from range maps, ecosystem productivity estimates from satellite observations, and spatially explicit, hierarchical ecosystem classifications. Additionally, we utilized content analysis of the environmental management plans of these areas to describe the unique set of demands and regulatory constraints on these areas. We found that the US military land estate in drylands contains many types of ecosystems and provides a large and diverse supply of ecosystem services, comparable to the sum of services from public lands in these areas. Additionally, the degree to which the ecosystem services concept is captured in environmental management plans is strongly shaped by the language of the governing legislation that mandated the use of environmental management plans in these areas, although these plans do not explicitly address land management using the concept of ecosystem services. Collectively, our findings suggest that military use and management of land represents an important source of ecosystem services, that military land use can be considered a cultural ecosystem service unto itself, and that top‐down regulation can affect how these services are identified and valued. Our work highlights the need for the research and conservation communities to quantify ecosystem services from individual military installations so that both services and biodiversity can be safeguarded in an era of military conflict across the globe.

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Drivers of woody dominance across global drylands

October 2024

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973 Reads

Science Advances

Increases in the abundance of woody species have been reported to affect the provisioning of ecosystem services in drylands worldwide. However, it is virtually unknown how multiple biotic and abiotic drivers, such as climate, grazing, and fire, interact to determine woody dominance across global drylands. We conducted a standardized field survey in 304 plots across 25 countries to assess how climatic features, soil properties, grazing, and fire affect woody dominance in dryland rangelands. Precipitation, temperature, and grazing were key determinants of tree and shrub dominance. The effects of grazing were determined not solely by grazing pressure but also by the dominant livestock species. Interactions between soil, climate, and grazing and differences in responses to these factors between trees and shrubs were key to understanding changes in woody dominance. Our findings suggest that projected changes in climate and grazing pressure may increase woody dominance in drylands, altering their structure and functioning.



Unforeseen plant phenotypic diversity in a dry and grazed world

August 2024

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2,169 Reads

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7 Citations

Nature

Earth harbours an extraordinary plant phenotypic diversity¹ that is at risk from ongoing global changes2,3. However, it remains unknown how increasing aridity and livestock grazing pressure—two major drivers of global change4–6—shape the trait covariation that underlies plant phenotypic diversity1,7. Here we assessed how covariation among 20 chemical and morphological traits responds to aridity and grazing pressure within global drylands. Our analysis involved 133,769 trait measurements spanning 1,347 observations of 301 perennial plant species surveyed across 326 plots from 6 continents. Crossing an aridity threshold of approximately 0.7 (close to the transition between semi-arid and arid zones) led to an unexpected 88% increase in trait diversity. This threshold appeared in the presence of grazers, and moved toward lower aridity levels with increasing grazing pressure. Moreover, 57% of observed trait diversity occurred only in the most arid and grazed drylands, highlighting the phenotypic uniqueness of these extreme environments. Our work indicates that drylands act as a global reservoir of plant phenotypic diversity and challenge the pervasive view that harsh environmental conditions reduce plant trait diversity8–10. They also highlight that many alternative strategies may enable plants to cope with increases in environmental stress induced by climate change and land-use intensification.


Vulnerability of mineral-associated soil organic carbon to climate across global drylands

July 2024

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1,300 Reads

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1 Citation

Nature Climate Change

Mineral-associated organic carbon (MAOC) constitutes a major fraction of global soil carbon and is assumed less sensitive to climate than particulate organic carbon (POC) due to protection by minerals. Despite its importance for long-term carbon storage, the response of MAOC to changing climates in drylands, which cover more than 40% of the global land area, remains unexplored. Here we assess topsoil organic carbon fractions across global drylands using a standardized field survey in 326 plots from 25 countries and 6 continents. We find that soil biogeochemistry explained the majority of variation in both MAOC and POC. Both carbon fractions decreased with increases in mean annual temperature and reductions in precipitation, with MAOC responding similarly to POC. Therefore, our results suggest that ongoing climate warming and aridification may result in unforeseen carbon losses across global drylands, and that the protective role of minerals may not dampen these effects.


Disturbance amplifies sensitivity of dryland productivity to precipitation variability

July 2024

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174 Reads

Science Advances

Variability of the terrestrial global carbon sink is largely determined by the response of dryland productivity to annual precipitation. Despite extensive disturbance in drylands, how disturbance alters productivity-precipitation relationships remains poorly understood. Using remote-sensing to pair more than 5600 km of natural gas pipeline corridors with neighboring undisturbed areas in North American drylands, we found that disturbance reduced average annual production 6 to 29% and caused up to a fivefold increase in the sensitivity of net primary productivity (NPP) to interannual variation in precipitation. Disturbance impacts were larger and longer-lasting at locations with higher precipitation (>450 mm mean annual precipitation). Disturbance effects on NPP dynamics were mostly explained by shifts from woody to herbaceous vegetation. Severe disturbance will amplify effects of increasing precipitation variability on NPP in drylands.



Average function for the 288 plots at 88 sites across global drylands and examples of fertile islands at selected sites
The background map shows the distribution of aridity (1 − [precipitation/potential evapotranspiration]) across global drylands. The mean RII value is calculated across 24 soil attributes (Methods).
Source data
The fertile island effect, as measured with the RII, beneath perennial dryland plants for the 24 soil attributes measured across three functions
N = 288 for all the attributes; data are presented as mean ± 95% CI, and darker colours indicate significant positive effects.
Source data
Impacts of recent grazing and climate on the fertile island effect
a–c, RII value surfaces for the three measures of ecosystem function (Decomposition, Fertility, Conservation) in relation to recent grazing pressure (standardized dung mass) and aridity, and mean (±95% CI) predicted RII value for the three functions (a) in relation to long-term (historic) measure of herbivore grazing pressure (ungrazed, low, medium, high) (b), and herbivore type (livestock, native, mixed) (c). Numbers in b and c are replicates for each category.
Source data
SEM assessing direct and indirect effects on the fertile island effect
a–c, The effects of climate (aridity (ARID), rainfall seasonality (SEAS)), soil (pH and sand (SAND) content), plants (perennial cover (COV), perennial plant richness (RICH)), plant height (HT), plant shape (SHAPE), leaf area (AREA), leaf length (LNGTH), canopy width (WIDTH), palatability (PALAT), deciduousness (DECID), resprouting ability (RESP) and allelopathy (ALLEL)) and grazing (standardized grazing pressure) are considered for soil decomposition (a), soil fertility (b) and soil and water conservation (c) after accounting for the effects of location (latitude, cosine longitude, sine longitude). Standardized path coefficients, adjacent to the arrows, are analogous to partial correlation coefficients and indicative of the effect size of the relationship. Pathways are significantly negative (red unbroken line), significantly positive (blue unbroken line) or mixed significantly negative and significantly positive (black unbroken lines). Non-significant pathways are not shown in the models. Model fit details are as follows: a, organic matter decomposition: χ² = 31.9, d.f. = 26, P = 0.20, R² = 0.17, r.m.s.e.a. < 0.001, Bollen–Stine = 0.40 (2,000 bootstraps); b, fertility: χ² = 31.9, d.f. = 26, P = 0.20, R² = 0.19, r.m.s.e.a. < 0.001, Bollen–Stine = 0.40 (2,000 bootstraps); c, conservation: χ² = 31.9, d.f. = 26, P = 0.20, R² = 0.10, r.m.s.e.a. < 0.001, Bollen–Stine = 0.40 (2,000 bootstraps). N = 288 for all analyses.
Source data
Hotspots of biogeochemical activity linked to aridity and plant traits across global drylands

April 2024

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1,898 Reads

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5 Citations

Nature Plants

Perennial plants create productive and biodiverse hotspots, known as fertile islands, beneath their canopies. These hotspots largely determine the structure and functioning of drylands worldwide. Despite their ubiquity, the factors controlling fertile islands under conditions of contrasting grazing by livestock, the most prevalent land use in drylands, remain virtually unknown. Here we evaluated the relative importance of grazing pressure and herbivore type, climate and plant functional traits on 24 soil physical and chemical attributes that represent proxies of key ecosystem services related to decomposition, soil fertility, and soil and water conservation. To do this, we conducted a standardized global survey of 288 plots at 88 sites in 25 countries worldwide. We show that aridity and plant traits are the major factors associated with the magnitude of plant effects on fertile islands in grazed drylands worldwide. Grazing pressure had little influence on the capacity of plants to support fertile islands. Taller and wider shrubs and grasses supported stronger island effects. Stable and functional soils tended to be linked to species-rich sites with taller plants. Together, our findings dispel the notion that grazing pressure or herbivore type are linked to the formation or intensification of fertile islands in drylands. Rather, our study suggests that changes in aridity, and processes that alter island identity and therefore plant traits, will have marked effects on how perennial plants support and maintain the functioning of drylands in a more arid and grazed world.


Extreme drought impacts have been underestimated in grasslands and shrublands globally

January 2024

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2,126 Reads

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21 Citations

Proceedings of the National Academy of Sciences

Climate change is increasing the frequency and severity of short-term (~1 y) drought events—the most common duration of drought—globally. Yet the impact of this intensification of drought on ecosystem functioning remains poorly resolved. This is due in part to the widely disparate approaches ecologists have employed to study drought, variation in the severity and duration of drought studied, and differences among ecosystems in vegetation, edaphic and climatic attributes that can mediate drought impacts. To overcome these problems and better identify the factors that modulate drought responses, we used a coordinated distributed experiment to quantify the impact of short-term drought on grassland and shrubland ecosystems. With a standardized approach, we imposed ~a single year of drought at 100 sites on six continents. Here we show that loss of a foundational ecosystem function—aboveground net primary production (ANPP)—was 60% greater at sites that experienced statistically extreme drought (1-in-100-y event) vs. those sites where drought was nominal (historically more common) in magnitude (35% vs. 21%, respectively). This reduction in a key carbon cycle process with a single year of extreme drought greatly exceeds previously reported losses for grasslands and shrublands. Our global experiment also revealed high variability in drought response but that relative reductions in ANPP were greater in drier ecosystems and those with fewer plant species. Overall, our results demonstrate with unprecedented rigor that the global impacts of projected increases in drought severity have been significantly underestimated and that drier and less diverse sites are likely to be most vulnerable to extreme drought.


Citations (74)


... Difference in life-form is one of the main drivers of trait values globally (Díaz et al., 2015), which makes it difficult to infer community assembly processes from the leaf traits alone. This could be the case in many stressful environments where a large diversity of trait combinations can coexist (Gross et al., 2024). on the relative contribution of species turnover and intraspecific variation to trait shifts across the continuum from resource acquisition to stress tolerance strategies along large gradients of soil toxicity to highlight the ecological and evolutionary mechanisms leading to such unique plant communities. ...

Reference:

Interspecific trait differences drive plant community responses on serpentine soils
Unforeseen plant phenotypic diversity in a dry and grazed world

Nature

... bers (OTCs) following the International Tundra Experiment guidelines (Hollister et al., 2022), whereas precipitation was reduced using partial rain-out shelters (modified infrastructures of Yahdjian & Sala, 2002) following the International Drought Experiment protocol for short-statured vegetation (Smith et al., 2024). In particular, the imposed 'drought' simulated a rainfall reduction equal to the statistically extreme deviation in precipitation relative to longterm, site-specific records (Knapp et al., 2015(Knapp et al., , 2017. ...

Extreme drought impacts have been underestimated in grasslands and shrublands globally

Proceedings of the National Academy of Sciences

... Because the HIR projects are almost exclusively located in uncleared arid and semi-arid rangeland areas, their capacity to increase sequestration in these areas through natural regeneration of woody vegetation is likely to be limited (Richards and Brack 2004;Gifford and McIvor 2009;Sankaran et al. 2013). The areas are likely to be at or near their carrying capacity for woody vegetation, meaning any changes in tree cover are most likely to be attributable to seasonal variability in rainfall (Gifford and McIvor 2009;Eldridge and Sala 2023). ...

Australia’s carbon plan disregards evidence
  • Citing Article
  • November 2023

Science

... In the United States, rangelands cover 312 million hectares (~ 30% total land) (U.S. Forest Service 2024) and provide important ecosystem services (York et al 2019) including forage for livestock (Hulvey et al. 2021), wildlife habitat (Rhodes et al. 2021), water supply (Hulvey et al. 2021), and carbon sequestration (Fynn et al. 2010;Smith et al. 2019). However, invasive species, changes in wildfire characteristics, suburban and exurban development, climate change and other disturbances have caused plant compositional changes which impact rangelands and their associated ecosystem services (Reeves et al. 2018;Osborne et al. 2022;Briske et al. 2023). ...

Supplying ecosystem services on US rangelands

Nature Sustainability

... In North America, the demand for dryland ecosystem services likely exceeds the current supply, making conservation and careful management of the large dryland area within the DoD land estate crucial for providing and safeguarding ecosystem services (Bengtsson et al., 2019). Drylands that are warmer and have lower species diversity are particularly vulnerable to reductions in services due to increased disturbance, and biodiversity loss in drylands can further exacerbate the decline in ecosystem services when coupled with disturbances and land use pressures (Maestre et al., 2022). The climate-biodiversity status of DoD lands creates widespread management challenges for military training areas in drylands where the primary land use can be destructive (Warren et al., 2007;Zentelis et al., 2017). ...

Grazing and ecosystem service delivery in global drylands
  • Citing Article
  • November 2022

Science

... Pour les données pratiques, c'est encore plus indirect, les descriptifs du pâturage et des autres actions humaines (élagage, fauche) ne sont jamais disponibles pour des pâturages collectifs. Pour les zones arides, la distance au point d'eau est généralement utilisée comme un gradient d'intensité de pâturages (Maestre et al. 2022). Cette approche peut être contestée avec des pratiques d'élevage pas forcément liées à la distance au point d'eau (en particulier en saisons des pluies avec la création des points d'eau temporaires). ...

Grazing and ecosystem service delivery in global drylands
  • Citing Article
  • November 2022

Science

... Short pulses may end up costing more resources than can be acquired, leading to organismal demise. According to theory 23 , adaptations to a pulsed existence will fall along a continuum between two end-member strategies. At one end "Nimble Responders (NIRs)" transition swiftly in and out of growth mode by constantly allocating a proportion of resources to reserves, maintaining a constitutive physiological readiness for inter-pulse conditions, and ensuring that metabolic systems are inherently hardy and protected. ...

Expanding the Pulse–Reserve Paradigm to Microorganisms on the Basis of Differential Reserve Management Strategies
  • Citing Article
  • June 2022

BioScience

... However, other organisms with a sessile lifestyle, such as plants, must face abiotic stress situations in situ, often related to drought, flooding, soil salinity, and extreme temperatures. Although plants exhibit remarkable adaptive plasticity to changes in the environment [1], the current scenario of climate change exacerbates variations in the average value of atmospheric variables in an area, changes that occur even more frequently and have a large negative impact on plant growth and development and, therefore, on crop yield [2]. ...

Special Section on LTER and Climate Change - Cross-Site Comparisons of Dryland Ecosystem Response to Climate Change in the US Long-Term Ecological Research Network

BioScience

... This indicates a requirement for further ecosystem characteristics to model the connection between the land and the atmosphere, determining how input forcings to the land surface (i.e., climate) are transformed into outputs (i.e., carbon, water, and energy fluxes). Such information is likely to be related to vegetation, but may also describe site soil characteristics (De Long et , or factors such as hydrological functioning (Euskirchen et al., 2020;Griebel et al., 2020;Pérez-Ruiz et al., 2022) and topography (Hoover et al., 2021;Xie et al., 2021). Modern ESMs nearly always account for such characteristics, through for example, soil type maps and hydrological modules, but analysis of results may not consider these sources of information as explanatory factors. ...

Seasonal carryover of water and effects on carbon dynamics in a dryland ecosystem

... The perceptions reflected here are a first attempt to approach biodiversity conservation programs and actions in a more standardized and strategic way in order to help identify potential pitfalls. As perceptions of biodiversity loss and its drivers may differ depending on gender, cultural and geographic background and interactions between those (Isbell et al. 2023), such factors would be ideally considered, which however is not possible here due to the limited number of experts participating in the survey. In our survey, it is important to note that the majority of experts was primarily from Central European countries (Fig. S1). ...

Expert perspectives on global biodiversity loss and its drivers and impacts on people