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

Perez-Ruiz, E. R.; Vivoni, Enrique R.; Sala, Osvaldo E.

doi:10.1002/ecs2.4189

Cited by 9 publications

(6 citation statements)

References 89 publications

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“…In arid ecosystems, evaporation is more likely to depend on antecedent rainfall to ensure there is moisture available. While evaporation is clearly inherently instantaneous (when water and energy are available), transpiration, particularly from deeper‐rooted species, could potentially provide mechanisms for memory to act (Pérez‐Ruiz et al., 2022). For instance, delays between rainfall and peak plant water content could buffer the response of transpiration to precipitation (Feldman et al., 2020).…”

Section: Discussionmentioning

confidence: 99%

Non‐Stationary Lags and Legacies in Ecosystem Flux Response to Antecedent Rainfall

et al. 2023

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Section: Discussionmentioning

confidence: 99%

Non‐Stationary Lags and Legacies in Ecosystem Flux Response to Antecedent Rainfall

et al. 2023

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“…This mechanism was identified based on: (1) infiltration depths after events that were limited to the upper 5–15 cm, (2) peak hillslope runoff amounts that were linked primarily to the maximum rainfall intensity ( I 30 ), and (3) the negligible effects of antecedent wetness (θ Sur ) on runoff production. The limited role of θ Sur was likely due to the high evapotranspiration amounts in the summer (~2–4 mm/day; Pérez‐Ruiz et al, 2022), leading to a rapid drying of the surface soils. Similar conclusions were obtained by Kampf et al (2018) for small watersheds in the Sonoran Desert.…”

Section: Discussionmentioning

confidence: 99%

“…The first‐order ephemeral channel drains a portion of the piedmont slope from east to west that emanates from the San Andres Mountains and is largely disconnected from deep water tables which are not subject to groundwater pumping (Schreiner‐McGraw & Vivoni, 2017). Local climate is classified as a cold desert (Koppen zone BWk), with an annual average precipitation of 278 mm and a mean annual temperature of 18°C (Pérez‐Ruiz et al, 2022), with most of the precipitation occurring during the North American monsoon (NAM; Adams & Comrie, 1997) between July and September. The ecosystem is a mixed shrubland consisting primarily of creosote bush ( Larrea tridentata ), honey mesquite ( Prosopis glandulosa Torr.…”

Section: Study Sitementioning

confidence: 99%

“…For the analysis of internal and outlet runoff flumes, we use the period of June 1, 2010, to September 15, 2021, after establishment of the environmental sensor network (Templeton et al, 2014). We divided each year in the record into two 6-month seasons: cool (October-March) and warm (April-September), based on monthly mean air temperature, with the latter containing storms during the NAM (Pérez-Ruiz et al, 2022).…”

Section: Study Periods and Data Analysesmentioning

confidence: 99%

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Hillslope to channel hydrologic connectivity in a dryland ecosystem

Keller,

Vivoni,

Kimsal

et al. 2023

Ecosphere

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Hydrologic connectivity refers to the processes and thresholds leading to water transport across a landscape. In dryland ecosystems, runoff production is mediated by the arrangement of vegetation and bare soil patches on hillslopes and the properties of ephemeral channels. In this study, we used runoff measurements at multiple scales in a small (4.67 ha) mixed shrubland catchment of the Chihuahuan Desert to identify controls on and thresholds of hillslope‐channel connectivity. By relating short‐ and long‐term hydrologic records, we also addressed whether observed changes in outlet discharge since 1977 were linked to modifications in hydrologic connectivity. Hillslope runoff production was controlled by the maximum rainfall intensity occurring in a 30‐min interval (I30), with small‐to‐negligible effects of antecedent surface soil moisture, vegetation cover, or slope aspect. An I30 threshold of nearly 10 mm/h activated runoff propagation from the shrubland hillslopes and through the main ephemeral channel, whereas an I30 threshold of about 16 mm/h was required for discharge from the catchment outlet. Since storms rarely exceed I30, full hillslope‐channel connectivity occurs infrequently in the mixed shrubland, leading to <2% of the annual precipitation being converted into outlet discharge. Progressive decreases in outlet discharge since 1977 could not be explained by variations in precipitation metrics, including I30, or the process of woody plant encroachment. Instead, channel modifications from the buildup of sediment behind measurement flumes may have increased transmission losses and reduced outlet discharge. Thus, alterations in channel properties can play an important role in the long‐term (45‐year) variations of rainfall–runoff dynamics of small desert catchments.

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“…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 al., 2019; Zhou et al., 2021), disturbance history (Amiro et al., 2010; Pugh et al., 2019), 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.…”

Section: Discussionmentioning

confidence: 99%

Are Plant Functional Types Fit for Purpose?

Cranko Page,

Abramowitz,

De Kauwe

et al. 2023

Geophysical Research Letters

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For over 40 years, Plant Functional Types (PFTs) have been used to discretize the ∼400,000 species of terrestrial plants into “similar” classes. Within Earth System Models (ESMs), PFTs simplify terrestrial biosphere modeling in combination with soil information and other site characteristics. However, in flux analysis studies, PFT schemes are often implemented as the sole analytical lens to clarify complex behavior. This usage assumes that PFTs adequately enable a mapping between climate inputs and flux outputs. Here, we show that random forest models, trained using aggregated climate and flux measurements from 245 eddy‐covariance sites, cannot accurately predict PFT groupings, regardless of the nature of the PFT scheme. Similarly, PFTs provide negligible benefit when using site climate to predict site flux regimes and vice versa. While use of PFT classifications is convenient, our results suggest they do not aid analytical skill, which has important implications for future terrestrial flux studies.

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

Cited by 9 publications

References 89 publications

Non‐Stationary Lags and Legacies in Ecosystem Flux Response to Antecedent Rainfall

Non‐Stationary Lags and Legacies in Ecosystem Flux Response to Antecedent Rainfall

Hillslope to channel hydrologic connectivity in a dryland ecosystem

Are Plant Functional Types Fit for Purpose?

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