Distribution of ecosystem C and N within contrasting vegetation types in a semiarid rangeland in the Great Basin, USA

Semiarid sagebrush ecosystems are being transformed by wildfire, rangeland improvement techniques, and exotic plant invasions, but the effects on ecosystem C and N dynamics are poorly understood. We compared ecosystem C and N pools to 1 m depth among historically grazed Wyoming big sagebrush, introd...

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Bibliographic Details
Published in:Biogeochemistry 2008-09, Vol.90 (3), p.291-308
Main Authors: Hooker, Toby D, Stark, John M, Norton, Urszula, Joshua Leffler, A, Peek, Michael, Ryel, Ron
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Biogeosciences
Biological and medical sciences
Biomass
Carbon
Desert soils
Earth and Environmental Science
Earth Sciences
Earth, ocean, space
Ecological function
Ecosystem degradation
Ecosystems
Environmental Chemistry
Exact sciences and technology
Fundamental and applied biological sciences. Psychology
Geochemistry
Grasses
Introduced plants
Isotopes
Leaf litter
Life Sciences
Nitrogen
Nonnative species
Nutrient cycles
Nutrient loss
Organic matter
Organic soils
Plant biomass
Plant roots
Plants
Rangelands
Soil and rock geochemistry
Soil depth
Soil ecology
Soil organic matter
Soil surfaces
Soil water
Soils
Surficial geology
Synecology
Terrestrial ecosystems
Vegetation
Wildfires
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Summary:Semiarid sagebrush ecosystems are being transformed by wildfire, rangeland improvement techniques, and exotic plant invasions, but the effects on ecosystem C and N dynamics are poorly understood. We compared ecosystem C and N pools to 1 m depth among historically grazed Wyoming big sagebrush, introduced perennial crested wheatgrass, and invasive annual cheatgrass communities, to examine whether the quantity and quality of plant inputs to soil differs among vegetation types. Natural abundance δ¹⁵N isotope ratios were used to examine differences in ecosystem N balance. Sagebrush-dominated sites had greater C and N storage in plant biomass compared to perennial or annual grass systems, but this was predominantly due to woody biomass accumulation. Plant C and N inputs to soil were greatest for cheatgrass compared to sagebrush and crested wheatgrass systems, largely because of slower root turnover in perennial plants. The organic matter quality of roots and leaf litter (as C:N ratios) was similar among vegetation types, but lignin:N ratios were greater for sagebrush than grasses. While cheatgrass invasion has been predicted to result in net C loss and ecosystem degradation, we observed that surface soil organic C and N pools were greater in cheatgrass and crested wheatgrass than sagebrush-dominated sites. Greater biomass turnover in cheatgrass and crested wheatgrass versus sagebrush stands may result in faster rates of soil C and N cycling, with redistribution of actively cycled N towards the soil surface. Plant biomass and surface soil δ¹⁵N ratios were enriched in cheatgrass and crested wheatgrass relative to sagebrush-dominated sites. Source pools of plant available N could become ¹⁵N enriched if faster soil N cycling rates lead to greater N trace gas losses. In the absence of wildfire, if cheatgrass invasion does lead to degradation of ecosystem function, this may be due to faster nutrient cycling and greater nutrient losses, rather than reduced organic matter inputs.
ISSN:0168-2563
1573-515X
DOI:10.1007/s10533-008-9254-z