Stephen P. Good scite author profile

Continental precipitation not routed to the oceans as runoff returns to the atmosphere as evapotranspiration. Partitioning this evapotranspiration flux into interception, transpiration, soil evaporation, and surface water evaporation is difficult using traditional hydrological methods, yet critical for understanding the water cycle and linked ecological processes. We combined two large-scale flux-partitioning approaches to quantify evapotranspiration subcomponents and the hydrologic connectivity of bound, plant-available soil waters with more mobile surface waters. Globally, transpiration is 64 ± 13% (mean ± 1 standard deviation) of evapotranspiration, and 65 ± 26% of evaporation originates from soils and not surface waters. We estimate that 38 ± 28% of surface water is derived from the plant-accessed soil water pool. This limited connectivity between soil and surface waters fundamentally structures the physical and biogeochemical interactions of water transiting through catchments.

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Global synthesis of vegetation control on evapotranspiration partitioning

Wang

Good

Caylor

2014

Geophysical Research Letters

332

237

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Evapotranspiration (ET) is an important component of the global hydrological cycle. However, to what extent transpiration ratios (T/ET) are controlled by vegetation and the mechanisms of global-scale T/ET variations are not clear. We synthesized all the published papers that measured at least two of the three components (E, T, and ET) and leaf area index (LAI) simultaneously. Nonlinear relationships between T/ET and LAI were identified for both the overall data set and agricultural or natural data subsets. Large variations in T/ET occurred across all LAI ranges with wider variability at lower LAI. For a given LAI, higher T/ET was observed during later vegetation growing stage within a season. We developed a function relating T/ET to the growing stage relative to the timing of peak LAI. LAI and growing stage collectively explained 43% of the variations in the global T/ET data set, providing a new way to interpret and model global T/ET variability.

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Climatological determinants of woody cover in Africa

Good

Caylor

2011

Proc. Natl. Acad. Sci. U.S.A.

190

155

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Determining the factors that influence the distribution of woody vegetation cover and resolving the sensitivity of woody vegetation cover to shifts in environmental forcing are critical steps necessary to predict continental-scale responses of dryland ecosystems to climate change. We use a 6-year satellite data record of fractional woody vegetation cover and an 11-year daily precipitation record to investigate the climatological controls on woody vegetation cover across the African continent. We find that-as opposed to a relationship with only mean annual rainfall-the upper limit of fractional woody vegetation cover is strongly influenced by both the quantity and intensity of rainfall events. Using a set of statistics derived from the seasonal distribution of rainfall, we show that areas with similar seasonal rainfall totals have higher fractional woody cover if the local rainfall climatology consists of frequent, less intense precipitation events. Based on these observations, we develop a generalized response surface between rainfall climatology and maximum woody vegetation cover across the African continent. The normalized local gradient of this response surface is used as an estimator of ecosystem vegetation sensitivity to climatological variation. A comparison between predicted climate sensitivity patterns and observed shifts in both rainfall and vegetation during 2009 reveals both the importance of rainfall climatology in governing how ecosystems respond to interannual fluctuations in climate and the utility of our framework as a means to forecast continental-scale patterns of vegetation shifts in response to future climate change.quantile regression | intraannual variability | remote sensing | potential cover | ecohydrology T he direction and magnitude of ecosystem state shifts in response to altered patterns of regional precipitation is a global earth science research focus (1). Semiarid ecosystems are particularly susceptible to rapid structural changes due to the sensitive balance between vegetation structure, soils, and climates (2). The widespread distribution of semiarid ecosystems in Africa has made this continent a central focus of efforts to determine the principle factors that govern patterns of regional vegetation structure (3,4).In the arid and semiarid regions where savannas are commonly found, climate and vegetation are linked through the dynamics of soil moisture (5). Actual soil moisture levels are determined by the intensity and frequency of rainfall and runoff events, as well as evapotranspirive demands and leakage losses acting on the soil column (2). Currently, the availability of regional scale soil moisture data is limited in temporal and spatial availability, thus analysis of spatial patterns of rainfall statistics provide the best available means of assessing climatological impacts on ecosystem status. Numerous studies have demonstrated the effect of both annual rainfall totals (4-8) and interannual variability of rainfall (7-10) on vegetation structure. In contrast, the influence o...

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Measurements and Observations in the XXI century (MOXXI): innovation and multi-disciplinarity to sense the hydrological cycle

Tauro

Selker

Giesen

et al. 2018

Hydrological Sciences Journal

179

142

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To promote the advancement of novel observation techniques that may lead to new sources of information to help better understand the hydrological cycle, the International Association of Hydrological Sciences (IAHS) established the Measurements and Observations in the XXI century (MOXXI) Working Group in July 2013. The group comprises a growing community of techenthusiastic hydrologists that design and develop their own sensing systems, adopt a multidisciplinary perspective in tackling complex observations, often use low-cost equipment intended for other applications to build innovative sensors, or perform opportunistic measurements. This paper states the objectives of the group and reviews major advances carried out by MOXXI members toward the advancement of hydrological sciences. Challenges and opportunities are outlined to provide strategic guidance for advancement of measurement, and thus discovery.

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Stephen P. Good

Hydrologic connectivity constrains partitioning of global terrestrial water fluxes

Global synthesis of vegetation control on evapotranspiration partitioning

Climatological determinants of woody cover in Africa

Measurements and Observations in the XXI century (MOXXI): innovation and multi-disciplinarity to sense the hydrological cycle

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