Simple process-led algorithms for simulating habitats (SPLASH v.1.0): robust indices of radiation, evapotranspiration  and plant-available moisture

Davis, T. W.; Prentice, Iain Colin; Stocker, Benjamin D.; Thomas, Rebecca T.; Whitley, Robert; Wang, Han; Evans, Bradley J.; Gallego‐Sala, Angela; Sykes, Martin T.; Crämer, Wolfgang

doi:10.5194/gmd-10-689-2017

Cited by 77 publications

(91 citation statements)

References 64 publications

(71 reference statements)

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“…The ratio of actual evapotranspiration to equilibrium evapotranspiration (Priestley‐Taylor coefficient, α), which represents the plant‐available surface moisture, was calculated at each 0.5° resolution site using the SPLASH model run at a monthly timescale (Davis et al . ). Soil cation exchange capacity (CEC; cmol c kg −1 ), soil pH, soil C:N ratio, soil silt content (%) and soil clay content (%) at 0–40 cm depth were extracted from 1 km global data provided by ISRIC SoilGrids database (http://www.soilgrids.org).…”

Section: Methodsmentioning

confidence: 97%

Global photosynthetic capacity is optimized to the environment

et al. 2019

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Earth system models (ESMs) use photosynthetic capacity, indexed by the maximum Rubisco carboxylation rate (V cmax), to simulate carbon assimilation and typically rely on empirical estimates, including an assumed dependence on leaf nitrogen determined from soil fertility. In contrast, new theory, based on biochemical coordination and co‐optimization of carboxylation and water costs for photosynthesis, suggests that optimal V cmax can be predicted from climate alone, irrespective of soil fertility. Here, we develop this theory and find it captures 64% of observed variability in a global, field‐measured V cmax dataset for C3 plants. Soil fertility indices explained substantially less variation (32%). These results indicate that environmentally regulated biophysical constraints and light availability are the first‐order drivers of global photosynthetic capacity. Through acclimation and adaptation, plants efficiently utilize resources at the leaf level, thus maximizing potential resource use for growth and reproduction. Our theory offers a robust strategy for dynamically predicting photosynthetic capacity in ESMs.

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Section: Methodsmentioning

confidence: 97%

Global photosynthetic capacity is optimized to the environment

et al. 2019

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“…Three bioclimate variables adequately represented the controls on vegetation structure and composition across China (Wang et al ., ). These are the accumulated photosynthetically active radiation during the thermal growing season (PAR 0 ), defined as the period when daily temperature is above 0°C; the daily mean temperature during the thermal growing season (mGDD 0 ); and the ratio of mean annual precipitation to annual equilibrium evapotranspiration (moisture index, MI), calculated using Simple Process‐Led Algorithms for Simulating Habitats (S plash ) (Davis et al ., ). The primary data for the calculation of these bioclimatic variables were derived from 1814 meteorological stations (740 stations with data from 1971 to 2000, the rest from 1981 to 1990), interpolated to 1 km resolution with elevation as a covariate using A nusplin v.4.37 (Hutchinson, ).…”

Section: Methodsmentioning

confidence: 97%

“…We derived climate variables for each site from the nearest 10‐min grid cell in the CRU 2.0 dataset (New et al ., ), which provided long‐term monthly means of temperature, precipitation, and sunshine duration for the standard period 1961–1990. PAR 0 , mGDD 0 , and MI were calculated in the way performed for the sites in China, using S plash to calculate MI (Davis et al ., ).…”

Section: Methodsmentioning

confidence: 97%

Quantifying leaf‐trait covariation and its controls across climates and biomes

et al. 2018

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Summary Plant functional ecology requires the quantification of trait variation and its controls. Field measurements on 483 species at 48 sites across China were used to analyse variation in leaf traits, and assess their predictability. Principal components analysis (PCA) was used to characterize trait variation, redundancy analysis (RDA) to reveal climate effects, and RDA with variance partitioning to estimate separate and overlapping effects of site, climate, life‐form and family membership. Four orthogonal dimensions of total trait variation were identified: leaf area (LA), internal‐to‐ambient CO2 ratio (χ), leaf economics spectrum traits (specific leaf area (SLA) versus leaf dry matter content (LDMC) and nitrogen per area (Narea)), and photosynthetic capacities (Vcmax, Jmax at 25°C). LA and χ covaried with moisture index. Site, climate, life form and family together explained 70% of trait variance. Families accounted for 17%, and climate and families together 29%. LDMC and SLA showed the largest family effects. Independent life‐form effects were small. Climate influences trait variation in part by selection for different life forms and families. Trait values derived from climate data via RDA showed substantial predictive power for trait values in the available global data sets. Systematic trait data collection across all climates and biomes is still necessary.

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“…As the surface fluxes required to calculate PET using equation were not available, we approximated CRU‐based PET from equilibrium evapotranspiration (ET 0 ; mm/day) following Priestley and Taylor ():

{ET}_{0} = normalΔ / ((), normalΔ + γ) R_{n}

where Δ is the rate of increase of saturated vapor pressure with temperature (Pa/K), γ the psychrometric constant (65 Pa/K), and R n is net radiation (W/m 2 ). ET 0 was calculated from CRU mean monthly air temperature and cloud cover using the R package SPLASH (Davis et al, ). Data for the pixel incorporating each tower were used to calculate AI.…”

Section: Methodsmentioning

confidence: 99%

Evaluating the Contribution of Land‐Atmosphere Coupling to Heat Extremes in CMIP5 Models

Ukkola

Pitman

Donat

et al. 2018

Geophysical Research Letters

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Land‐atmosphere coupling can amplify heat extremes under declining soil moisture. Here we evaluate this coupling in 25 Coupled Model Intercomparison Project Phase 5 models using flux tower observations over Europe and North America. We compared heat extremes (2.5% of the hottest days of the year) and the evaporative fraction (EF; a measure of land surface dryness) on the day the heat extremes occurred. We found a negative relationship between the magnitude of heat extremes and EF in both models and observations in transitional regions, with the hottest temperatures occurring during the driest days, with a similar but less certain relationship in dry regions. Surprisingly, many models also showed an amplification of heat extremes by low EF in wet regions, a finding not supported by observations. Many models may therefore overamplify heat extremes over wet regions by overestimating the strength of land‐atmosphere coupling, with consequences for future projections of heat extremes.

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Simple process-led algorithms for simulating habitats (SPLASH v.1.0): robust indices of radiation, evapotranspiration and plant-available moisture

Cited by 77 publications

References 64 publications

Global photosynthetic capacity is optimized to the environment

Global photosynthetic capacity is optimized to the environment

Quantifying leaf‐trait covariation and its controls across climates and biomes

Evaluating the Contribution of Land‐Atmosphere Coupling to Heat Extremes in CMIP5 Models

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