Hydraulic Conductivity in a Piñon-Juniper Woodland

Wilcox, Bradford P.; Breshears, David D.; Turin, H.

doi:10.2136/sssaj2003.1243

Cited by 87 publications

(101 citation statements)

References 42 publications

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“…Disturbance events such as wildfire not only affect evapotranspiration but also reduce the rate of infiltration into the soil, leading to enhanced streamflow in regions with a Mediterranean or semi-arid climate (Hallema et al 2017). The streamflow regulation functions of forests depend on many watershed factors including background climate, forest structure (i.e., species composition, ages), soil properties such as hydraulic conductivity (Wilcox et al 2003b), geology, and watershed size ). It appears that the hydrological regulation functions of forests are scaledependent, and most of our knowledge is derived from small watershed vegetation manipulation experiments, and we lack empirical data about the role of vegetation in influencing streamflow of large river systems.…”

Section: Water Cycle and Supplymentioning

confidence: 99%

Ecohydrological processes and ecosystem services in the Anthropocene: a review

2017

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The framework for ecosystem services has been increasingly used in integrated watershed ecosystem management practices that involve scientists, engineers, managers, and policy makers. The objective of this review is to explore the intimate connections between ecohydrological processes and water-related ecosystem services in human-dominated ecosystems in the Anthropocene. We synthesize current literature to illustrate the importance of understanding the ecohydrological processes for accurately quantifying ecosystem services under different environmental and socioeconomic settings and scales. Our synthesis focuses on managed ecosystems that are dominated by humans and explores how ecological processes affect the tradeoffs and synergies of multiple ecosystem services. We identify research gaps in studying ecological processes mainly including energy, carbon, water, and nutrient balances to better assess and quantify ecosystem services that are critical for sustaining natural resources for future generations. To better assess ecosystem services, future ecohydrological studies need to better account for the scaling effects of natural and anthropogenic stressors exerted on evapotranspiration and other water supply and demand processes. Future studies should focus on the bidirectional interactions between hydrological functions and services and human actions to solve real world problems such as water shortages, ecological degradation, and climate change adaptation. Review

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Section: Water Cycle and Supplymentioning

confidence: 99%

Ecohydrological processes and ecosystem services in the Anthropocene: a review

2017

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“…Studies have found higher infiltrability for subcanopy soils due to many factors including the protection of the soil surface by leaf litter, enhanced aggregation of soil particles, and more developed macropore networks (Dunkerley, 2000;Wilcox et al, 2003). Owing to these effects, the magnitude of infiltration and soil moisture has been shown to be higher under vegetation than intercanopy areas under certain conditions (Bhark and Small, 2003).…”

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confidence: 99%

Effects of woody vegetation on shallow soil moisture at a semiarid montane catchment

Traff

2014

Ecohydrology

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“…At the Los Piños sites, due to the similarities between grama grass and juniper n-alkane signatures, there was a degree of difficulty in determining between sources; based upon n-alkane signature, a problem was previously experienced when using n-alkane signatures alone [Marschner et al, 2008;Gocke et al, 2011]. However, the use of n-alkane signatures from piñon and combined with the δ 13 C values of both piñon and juniper demonstrated that the same trends transcend to the mountainous, grassland to piñon-juniper transition [Wilcox et al, 2003b]. Evidence of legacy grass-C in bare areas has been observed in other southwestern U.S. landscapes following woody encroachment [Boutton et al, 1999;Bai et al, 2012 ].…”

Section: Change In the Source Of C Over Vegetation Transitionsmentioning

confidence: 99%

Woody plant encroachment into grasslands leads to accelerated erosion of previously stable organic carbon from dryland soils

et al. 2014

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Drylands worldwide are experiencing rapid and extensive environmental change, concomitant with the encroachment of woody vegetation into grasslands. Woody encroachment leads to changes in both the structure and function of dryland ecosystems and has been shown to result in accelerated soil erosion and loss of soil nutrients. Covering 40% of the terrestrial land surface, dryland environments are of global importance, both as a habitat and a soil carbon store. Relationships between environmental change, soil erosion, and the carbon cycle are uncertain. There is a clear need to further our understanding of dryland vegetation change and impacts on carbon dynamics. Here two grass-to-woody ecotones that occur across large areas of the southwestern United States are investigated. This study takes a multidisciplinary approach, combining ecohydrological monitoring of structure and function and a dual-proxy biogeochemical tracing approach using the unique natural biochemical signatures of the vegetation. Results show that following woody encroachment, not only do these drylands lose significantly more soil and organic carbon via erosion but that this includes significant amounts of legacy organic carbon which would previously have been stable under grass cover. Results suggest that these dryland soils may not act as a stable organic carbon pool, following encroachment and that accelerated erosion of carbon, driven by vegetation change, has important implications for carbon dynamics.

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Hydraulic Conductivity in a Piñon-Juniper Woodland

Cited by 87 publications

References 42 publications

Ecohydrological processes and ecosystem services in the Anthropocene: a review

Ecohydrological processes and ecosystem services in the Anthropocene: a review

Effects of woody vegetation on shallow soil moisture at a semiarid montane catchment

Woody plant encroachment into grasslands leads to accelerated erosion of previously stable organic carbon from dryland soils

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