Grazing increases evapotranspiration without the cost of lowering soil water storages in arid ecosystems

Pereyra, Diego; Arias, Nadia Soledad; Ciano, Nicolás; Cristiano, Piedad M.; Goldstein, Guillermo; Scholz, Fabián Gustavo

doi:10.1002/eco.1850

Cited by 27 publications

(16 citation statements)

References 63 publications

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“…The decrease in soil water availability during the dry season affects several physiological processes, leading to plant dehydration and a substantial loss of root functionality in this ecosystem (Bucci et al., 2013; Scholz et al., 2012). This was also reflected in a decrease in plant transpiration during the drought period (Pereyra et al., 2017), and hence a decrease in CO 2 capture. Furthermore, at low soil moisture conditions, decomposition is limited by soluble C availability (Davidson et al., 2012; Linn & Doran, 1984).…”

Section: Discussionmentioning

confidence: 99%

Controls of Temporal Variations on Soil Respiration in a Tropical Lowland Rainforest in Hainan Island, China

Cui

Feng

Liao

et al. 2020

Tropical Conservation Science

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Soil respiration represents the largest carbon (C) flux from terrestrial ecosystems to the atmosphere. We created a study site in tropical lowland rainforest and used static chamber method to measure the temporal variations of soil respiration and their relationship with environmental factors at monthly time scale. The temporal variations of soil respiration showed a seasonal pattern related to soil temperature (p < .01) and soil moisture (p < .05). We tested different regression models to explore the relationship between soil respiration and environmental factors. Soil respiration had a better fit with soil temperature than with soil moisture in single-factor models. At different temperatures, the Q 10 values from different models changed in rather different ways. We found that the mixed quadratic model composite of soil temperature and moisture had the best-fitting effect (R 2 ¼ .74) on soil respiration and could better explain the seasonal variation. In a certain soil moisture range close to 15%, soil respiration increased with soil temperature. However, soil respiration became restricted when the moisture was greatly higher or lower than this value. Furthermore, at low soil temperatures (lower than 16 C), higher soil moisture could decrease soil respiration rapidly. Thus, soil respiration in a tropical lowland rainforest is co-controlled by soil temperature and moisture. This study expands our observations of soil respiration in tropical forests and how it responds to environmental factors, which is important for reducing errors in evaluation and scaling up of soil carbon flux in climate change studies.

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Section: Discussionmentioning

confidence: 99%

Controls of Temporal Variations on Soil Respiration in a Tropical Lowland Rainforest in Hainan Island, China

Cui

Feng

Liao

et al. 2020

Tropical Conservation Science

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“…An increase in underground biomass with N and P addition has been previously reported in other ecosystems (Li et al 2015;Huang et al 2018). It should be noted that we only evaluated the effects of the treatments on root biomass in the rst 10 cm depth, but in this ecosystem more than 40% of roots are found in this soil layer and less than 20% at 50 cm depth (Pereyra et al 2017). Moreover, the ne roots located in the upper part of the soil pro le have higher rates of respiration than larger roots or the few roots located deeper in the soil (Pregitzer et al 1998).…”

Section: Discussionmentioning

confidence: 99%

Soil Respiration and N-Mineralization Processes in the Patagonian Steppe Are More Responsive to Nutrient Than to Water Addition

Carbonell‐Silletta

Cavallaro²,

Pereyra³

et al. 2021

Preprint

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Aims: Soil respiration and N-mineralization are key processes in C and N cycling of terrestrial ecosystems. Both processes are limited by soil temperature, moisture and nutrient content in arid and cold ecosystems, but how nutrient addition interacts with water addition requires further investigation. This study addresses the effects of water and N+P additions on soil respiration and mineralization rates in the Patagonian steppe.Methods: We measured soil respiration and N-mineralization throughout seasons in control, fertilized, irrigated and irrigated-fertilized plots. We also analyzed root density and soil physico-chemical properties.Results: The soil CO2 effluxes in the Patagonian steppe were controlled by soil temperature, soil water content and root density. Increases in water addition had no effects on soil respiration, except when combined with N+P addition. However, soil nutrient enrichment without water addition enhanced soil respiration during the plant growing season. We found a linear positive relationship between root density and soil respiration, without interaction with treatments. N+P addition had negative impacts on N-mineralization, resulting in a strong N-immobilization. However, soil ammonium and nitrate content increased with N+P addition all over the seasons.Conclusion: Moderate increases in the precipitation through small pulses lead to no long-term response of soil processes in arid and cold Patagonian ecosystems. However, soil CO2 effluxes are likely to increase with nutrient additions, such as anthropogenic N deposition, and microbial biomass could retain more nutrients in the soil. Therefore, high levels of N enrichment in arid ecosystems may strengthen the positive feedback between C cycle and climate change.

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“…Por último, el 8% de los estudios evaluó la tasa de descomposición radical (Tabla 1). Si bien la estimación de la BS parece ser la principal variable de estudio, es necesario obtener otras variables complementarias que permitan determinar cómo las plantas responden a distintos factores ambientales en diferentes ecosistemas y cuál es la profundidad de enraizamiento o la de captación de agua por parte de las raíces (Bucci et al 2009;Pereyra et al 2017).…”

Section: Principales Variables Evaluadasunclassified

Ojos que no ven... ¿Qué podemos hacer para incluir más a la fracción subterránea en estudios de vegetación?

et al. 2020

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Grazing increases evapotranspiration without the cost of lowering soil water storages in arid ecosystems

Cited by 27 publications

References 63 publications

Controls of Temporal Variations on Soil Respiration in a Tropical Lowland Rainforest in Hainan Island, China

Controls of Temporal Variations on Soil Respiration in a Tropical Lowland Rainforest in Hainan Island, China

Soil Respiration and N-Mineralization Processes in the Patagonian Steppe Are More Responsive to Nutrient Than to Water Addition

Ojos que no ven... ¿Qué podemos hacer para incluir más a la fracción subterránea en estudios de vegetación?

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