Litter is more effective than forest canopy reducing soil evaporation in Dry Chaco rangelands

Magliano, Patricio N.; Giménez, Raúl; Houspanossian, Javier; Páez, Ricardo; Nosetto, Marcelo D.; Fernández, Roberto; Jobbágy, Estéban G.

doi:10.1002/eco.1879

Cited by 43 publications

(24 citation statements)

References 75 publications

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“…Throughfall dripping from the canopy may concentrate water in a few points infiltrating deeper into the soil profile F I G U R E 5 Interception loss (a, b), throughfall (c, d) and stemflow (e, f) as a function of rainfall event size and intensity reducing evaporation losses and enhancing plant consumption (Fan et al, 2015;Loik, Breshears, Lauenroth, & Belnap, 2004;Magliano, Giménez, et al, 2017). Different studies have explored the relationship between throughfall fluxes and the distance from the stem-soil intersection to the periphery of the canopy, assuming that large throughfall inputs that infiltrate close to the base of stems and trunks may represent a benefit for the plants (similarly to stemflow localized inputs) (Loustau et al, 1992;Shachnovich et al, 2008;Zhang et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

Interception loss, throughfall and stemflow by Larrea divaricata: The role of rainfall characteristics and plant morphological attributes

Magliano

Whitworth‐Hulse

Florio

et al. 2019

Ecological Research

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Rainfall partitioning into interception loss, throughfall and stemflow affects the amount and the spatial heterogeneity of water entering into the soil at the patch scale, strongly controlling net primary productivity of drylands. In this paper, we explored rainfall partitioning and its biophysical controls in Larrea divaricata (jarilla), one of the most abundant shrubs in the Dry Chaco rangelands (Argentina). On average, interception loss, throughfall and stemflow accounted for 9.4, 78.6 and 12.0% of total rainfall, respectively. Interception loss proportion decreased with the increment of rainfall event size and intensity, whereas throughfall proportion showed the opposite pattern. Stemflow proportion increased with the increment of rainfall event size but presented different relations with rainfall event intensity. The increment of rainfall event intensity increased the stemflow in small events (<20 mm), but decreased it in large events (>20 mm). Stemflow increased in plants with higher angles of insertion of stems (measured at 50 and 100 cm from soil surface; p < .05 and p < .01, respectively), but decreased in plants with larger canopy areas (p = .01). Spatial distribution of throughfall (coefficient of variation) decreased with the increment of rainfall event size and intensity. L. divaricata presented more stemflow generation and fewer interception losses than other similar woody species. Our findings help to understand the key role of vegetation canopy affecting the amount of water entering into the soil in drylands.

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Section: Discussionmentioning

confidence: 99%

Interception loss, throughfall and stemflow by Larrea divaricata: The role of rainfall characteristics and plant morphological attributes

Magliano

Whitworth‐Hulse

Florio

et al. 2019

Ecological Research

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“…This contrasting behaviour is probably due to the fact that some of the dry forest species have deeper root systems (Canadell et al, 1996; Marchesini et al, 2013) than the pasture that would allow them to use deeper water (Jobbágy, Nosetto, Villagra, & Jackson, 2011) and sustain a certain carbon gain during rainless periods. There are three main mechanisms that favour water storage at greater depth in the studied dry forest, which include (i) run‐off/run‐on water redistribution that concentrates rainfall and favours percolation in a minor fraction of the area (Magliano, Breshears, Fernández, & Jobbágy, 2015; Magliano, Fernández, Florio, Murray, & Jobbágy, 2017), (ii) large amounts of stemflow generation by some dominant shrubs such us Larrea divaricata (Magliano, Whitworth‐Hulse, Florio, Aguirre, & Blanco, 2019) and (iii) the low atmospheric demand at the soil surface level caused by canopy shade and litter that maintains wet soil conditions increasing the probability that the next rain event reaches greater depths (Magliano et al, 2017). In addition, deep soil layers (>1 m) under dry forests of the region are typically salty because of long‐term accumulation of atmospheric salts resulting from an exhaustive use of rainfall inputs by plants (Santoni, Jobbágy, & Contreras, 2010).…”

Section: Resultsmentioning

confidence: 99%

Contrasting CO₂ and water vapour fluxes in dry forest and pasture sites of central Argentina

et al. 2020

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The dry forests of South America are a key player of the global carbon cycle and the regional water cycle, but they are being intensively deforested. We used eddy covariance measurements to compare the temporal patterns of CO 2 and water vapour fluxes and their relationships with environmental variables in dry forest and pastures sites of central Argentina. Ecosystem fluxes showed clear contrasts in magnitude, timing and response to environmental controls between ecosystems. The dry forest displayed higher daily gross primary productivity (GPP, 10.6 vs. 7.8 g CO 2 m −2 d −1) and ecosystem respiration (R eco , 9.1 vs. 7.0 g CO 2 m −2 d −1) and lower net ecosystem exchange (NEE, −1.5 vs. −0.7 g CO 2 m −2 d −1) than the pasture. These differences were explained by a lower tolerance of the pasture to cool temperatures and drought. The lowest NEE rates were observed between 26 C and 34 C in the pasture, but below this range, NEE increased sharply, switching to a carbon source with temperatures <20 C. By contrast, the dry forest remained as a strong carbon sink down to 18 C. The pasture also showed a stronger drop of GPP with drought compared with the dry forest, becoming a carbon source with soil wetness <25% of soil available water. Rainfall was strongly coupled with GPP in both ecosystems, but the dry forest responded to longer rainfall integration periods. This study helps to understand how ecosystems can respond to climate change, improve global scale modelling and increase the productivity and resilience of rangelands.

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“…Additionally, it is necessary to understand how individual plant species in tropical environments use different water sources. Water uptake by tropical trees is linked to leaf phenology and transpiration rates (Schwendenmann et al, 2015); however, the use of stable isotopes in xylem water could by affected due to evaporative fractionation during the transport within the plant tissues (Barbeta et al, 2019;Martín-Gómez et al, 2016;Zhao et al, 2016) or selective acquisition (Vargas et al, 2017). This evidence depicts the need to better understand the effect on stable water isotope signatures during the water transport within the plant.…”

Section: Discussionmentioning

confidence: 99%

“…However, recent evidence has shown that tree species such as Pinus sylvestris L., Quercus subpyrenaica Villar, Persea americana Mill., Fagus sylvatica L. and Populus euphratica Oliv. are able to fractionate the isotope signatures of xylem water (Barbeta et al, 2019;Martín-Gómez et al, 2016;Vargas et al, 2017;Zhao et al, 2016). This raises the question of whether tropical trees modify the isotope signature of xylem water, as a response to their plasticity to seasonal changes despite their similar root distribution (Schwendenmann et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Contribution of understory evaporation in a tropical wet forest during the dry season

Jiménez-Rodríguez¹,

Coenders-Gerrits

Wenninger

et al. 2020

Hydrol. Earth Syst. Sci.

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Abstract. Tropical wet forests are complex ecosystems with a large number of plant species. These environments are characterized by a high water availability throughout the whole year and a complex canopy structure. However, how the different sections of the canopy contribute to total evaporation is poorly understood. The aim of this work is to estimate the total evaporation flux and differentiate the contribution among canopy layers of a tropical wet forest in Costa Rica. The fluxes were monitored during the dry season by making use of the energy balance to quantify the fluxes and stable water isotopes to trace the sources of water vapor. Total evaporation was 275.5 mm and represents 55.9 % of the recorded precipitation (498.8 mm), with 11.7 % of the precipitation being intercepted and evaporated along the forest canopy. The understory beneath 8 m contributed 23.6 % of the evaporation, and almost half of it comes from the first 2 m of the understory. Stable water isotope signatures show different soil water sources depending on the plant type. Palms make use of a water source with an isotope signature similar to precipitation and throughfall. Soil water with a fractionated signature is used by trees, bushes and lianas. The isotope signature of water vapor samples overlap among different heights, but it was not possible to make use of the Keeling plot method due to the similar isotope signature of the possible sources of water vapor as well as the high water concentration even on the dryer days.

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Litter is more effective than forest canopy reducing soil evaporation in Dry Chaco rangelands

Cited by 43 publications

References 75 publications

Interception loss, throughfall and stemflow by Larrea divaricata: The role of rainfall characteristics and plant morphological attributes

Interception loss, throughfall and stemflow by Larrea divaricata: The role of rainfall characteristics and plant morphological attributes

Contrasting CO₂ and water vapour fluxes in dry forest and pasture sites of central Argentina

Contribution of understory evaporation in a tropical wet forest during the dry season

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Litter is more effective than forest canopy reducing soil evaporation in Dry Chaco rangelands

Cited by 43 publications

References 75 publications

Interception loss, throughfall and stemflow by Larrea divaricata: The role of rainfall characteristics and plant morphological attributes

Interception loss, throughfall and stemflow by Larrea divaricata: The role of rainfall characteristics and plant morphological attributes

Contrasting CO2 and water vapour fluxes in dry forest and pasture sites of central Argentina

Contribution of understory evaporation in a tropical wet forest during the dry season

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Contrasting CO₂ and water vapour fluxes in dry forest and pasture sites of central Argentina