Effect of precipitation variability on net primary production and soil respiration in a Chihuahuan Desert grassland

Thomey, Michell L.; Collins, Scott L.; Vargas, Rodrigo; Johnson, Jennifer E.; Brown, Renée F; Natvig, Donald O.; Friggens, Michael T.

doi:10.1111/j.1365-2486.2010.02363.x

Cited by 340 publications

(279 citation statements)

References 59 publications

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“…In this direction, reductions in approximately 30 per cent in annual precipitation have been reported to lower daily soil CO 2 efflux by 50 per cent in Mediterranean semiarid shrublands [51]. Moreover, less frequent, more intense rainfall pulses have been found to increase this variable up to 30 per cent in the Chihuahuan Desert [37]. Modelling studies suggest that expected changes in precipitation and temperature, coupled with increases in [CO 2 ], will increase soil respiration in a nonlinear fashion in this desert [84].…”

Section: Global Environmental Change Effects On Drylandsmentioning

confidence: 96%

“…Climate models project an increase in precipitation variability in drylands, including more extreme rainfall events and intense droughts [34]. Large rainfall pulses infiltrate deeper and last longer than smaller rain events [35], and thus even areas undergoing decreases in annual precipitation could experience increased soil moisture if precipitation becomes more variable but is characterized by larger pulses [36,37]. Nevertheless, there is evidence that climate change will exacerbate the aridity of most drylands worldwide, such as the southwestern US [38], the Mediterranean Basin [39], southern Africa [40], Australia [41], South America [42] and China [33].…”

Section: Global Environmental Change Effects On Drylandsmentioning

confidence: 99%

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It is getting hotter in here: determining and projecting the impacts of global environmental change on drylands

Maestre

Salguero‐Gómez

Quero

2012

Phil. Trans. R. Soc. B

253

209

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Drylands occupy large portions of the Earth, and are a key terrestrial biome from the socio-ecological point of view. In spite of their extent and importance, the impacts of global environmental change on them remain poorly understood. In this introduction, we review some of the main expected impacts of global change in drylands, quantify research efforts on the topic, and highlight how the articles included in this theme issue contribute to fill current gaps in our knowledge. Our literature analyses identify key under-studied areas that need more research (e.g. countries such as Mauritania, Mali, Burkina Faso, Chad and Somalia, and deserts such as the Thar, Kavir and Taklamakan), and indicate that most global change research carried out to date in drylands has been done on a unidisciplinary basis. The contributions included here use a wide array of organisms (from micro-organisms to humans), spatial scales (from local to global) and topics (from plant demography to poverty alleviation) to examine key issues to the socio-ecological impacts of global change in drylands. These papers highlight the complexities and difficulties associated with the prediction of such impacts. They also identify the increased use of long-term experiments and multidisciplinary approaches as priority areas for future dryland research. Major advances in our ability to predict and understand global change impacts on drylands can be achieved by explicitly considering how the responses of individuals, populations and communities will in turn affect ecosystem services. Future research should explore linkages between these responses and their effects on water and climate, as well as the provisioning of services for human development and well-being.

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Section: Global Environmental Change Effects On Drylandsmentioning

confidence: 96%

Section: Global Environmental Change Effects On Drylandsmentioning

confidence: 99%

It is getting hotter in here: determining and projecting the impacts of global environmental change on drylands

Maestre

Salguero‐Gómez

Quero

2012

Phil. Trans. R. Soc. B

253

209

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“…Some examples of relationships that could be tested and validated are those observed between phenology and CO 2 fluxes , control of GPP on RS (Vargas et al, 2011b), or the role of drought and water pulses (Thomey et al, 2011). What follows are examples from measurements at MexFlux sites to illustrate the diversity of patterns and magnitudes of CO 2 fluxes.…”

Section: Water Vapor and Co 2 Fluxes In Terrestrial Ecosystems Of Mexicomentioning

confidence: 99%

“…These changes in precipitation patterns can substantially affect carbon sequestration in semiarid rangelands by reducing or increasing water stress within the ecosystem (Thomey et al, 2011, Vargas et al, 2012b.…”

Section: Water Vapor and Co 2 Fluxes In Terrestrial Ecosystems Of Mexicomentioning

confidence: 99%

Progress and opportunities for monitoring greenhouse gases fluxes in Mexican ecosystems: the MexFlux network

Vargas¹,

Yépez²,

Andrade³

et al. 2013

Atmósfera

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RESUMENPara entender los procesos de los ecosistemas desde un punto de vista funcional es fundamental entender las relaciones entre la variabilidad climática, los ciclos biogeoquímicos y las interacciones superficie-atmósfera. En las últimas décadas se ha aplicado de manera creciente el método de covarianza de flujos turbulentos (EC, por sus siglas en inglés) en ecosistemas terrestres, marinos y urbanos para medir los flujos de gases de invernadero (p. ej., CO 2 , H 2 O ) y energía (p. ej., calor sensible y latente). En diversas regiones se han establecido redes de sistemas EC que han aportado información científica para el diseño de políticas ambientales y de adaptación. En este contexto, el presente trabajo delimita el marco conceptual y técnico para el establecimiento de una red regional de medición de flujos de gases de efecto invernadero en México, denominada MexFlux, cuyo objetivo principal es mejorar nuestra comprensión de la forma en que la variabilidad climática y la transformación ambiental influye en la dinámica de los ecosistemas mexicanos ante los factores de cambio ambiental global. En este documento se analiza primero la importancia del intercambio de CO 2 y vapor de agua entre los ecosistemas terrestres y la atmósfera. Después se describe brevemente la técnica de covarianza de flujos turbulentos para la medición de éstos, y se presentan ejemplos de mediciones en dos ecosistemas terrestres y uno urbano en México. Por último, se describen las bases conceptuales y operativas a corto, mediano y largo plazo para la continuidad de la red MexFlux. 325-336 (2013) Atmósfera 26(3), 326 R. Vargas et al. ABSTRACTUnderstanding ecosystem processes from a functional point of view is essential to study relationships among climate variability, biogeochemical cycles, and surface-atmosphere interactions. Increasingly during the last decades, the eddy covariance (EC) method has been applied in terrestrial, marine and urban ecosystems to quantify fluxes of greenhouse gases (e.g., CO 2 , H 2 O) and energy (e.g., sensible and latent heat). Networks of EC systems have been established in different regions and have provided scientific information that has been used for designing environmental and adaptation policies. In this context, this article outlines the conceptual and technical framework for the establishment of an EC regional network (i.e., MexFlux) to measure the surface-atmosphere exchange of heat and greenhouse gases in Mexico. The goal of the network is to improve our understanding of how climate variability and environmental change influence the dynamics of Mexican ecosystems. First, we discuss the relevance of CO 2 and water vapor exchange between terrestrial ecosystems and the atmosphere. Second, we briefly describe the EC basis and present examples of measurements in terrestrial and urban ecosystems of Mexico. Finally, we describe the conceptual and operational goals at short-, medium-, and long-term scales for continuity of the MexFlux network.

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“…近年来, 人类活动导致大气中的CO 2 浓度升高, 引起了全球升温和降水格局的改变 (Borken et al, 2002;Chimner et al, 2010;IPCC, 2013)。多个气候模型预测结果一致显示, 未来气候变化会带来全球或局部降水格局的变化 (Fischer et al, 2013;Knapp et al, 2015)。未来降水将在高纬度和部分热带地区增加, 而在中低纬度和部分亚热带地区减少 (Harper et al, 2005)。同时, 极端降水事件的发生频率增加, 降雨强度和降雨时间分布进一步变化 (Thomey et al, 2011;彭琴等, 2012;IPCC, 2013 (Raich & Sehlesinger, 1992;Hanson et al, 2000;Wang et al, …”

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降水格局改变背景下土壤呼吸变化的主要影响因素及其调控过程

Qing-Xiao¹,

Tian²,

Zeng³

et al. 2017

Chin. J. Plant Ecol.

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Effect of precipitation variability on net primary production and soil respiration in a Chihuahuan Desert grassland

Cited by 340 publications

References 59 publications

It is getting hotter in here: determining and projecting the impacts of global environmental change on drylands

It is getting hotter in here: determining and projecting the impacts of global environmental change on drylands

Progress and opportunities for monitoring greenhouse gases fluxes in Mexican ecosystems: the MexFlux network

降水格局改变背景下土壤呼吸变化的主要影响因素及其调控过程

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