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| DOI: | 10.1046/j.1469-8137.2000.00685 |
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| Web URL(s): | http://www.jstor.org/stable/view/2588690
Last checked: 07/16/2014
Access conditions: Item is within a limited-access website
http://www.jstor.org/stable/pdfplus/2588690.pdf
Last checked: 07/16/2014
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Access conditions: Item is within a limited-access website |
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| Publication Type:
| Refereed |
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| Author(s): | Arnone, J. A. III;
Zaller, J. G.;
Spehn, E. M.;
Niklaus, P. A.;
Wells, C. E.;
Körner, C. |
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| Author Affiliation: | Arnone: Department of Integrative Biology, University of Basel- Botanical Institute, Basel, Switzerland, Desert Research Institute, Division of Earth and Ecosystem Sciences, Reno, NV; Zaller: Department of Integrative Biology, University of Basel- Botanical Institute, Basel, Switzerland, The Ecology Center, Utah State University, Logan, UT; Spehn, Niklaus and Körner: Department of Integrative Biology, University of Basel- Botanical Institute, Basel, Switzerland; Wells: Department of Environmental and Resource Sciences, University of Nevada-Reno, Reno, NV |
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| Title: | Dynamics of root systems in native grasslands: effects of elevated atmospheric CO₂ |
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| Source: | New Phytologist. Vol. 147, No. 1, July 2000, p. 73-86. |
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| Publishing Information: | Oxford, England: Cambridge University Press. |
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| # of Pages: | 14 |
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| Related Web URL: | http://www.jstor.org/stable/info/2588690
Last checked: 07/16/2014
Notes: Abstract only |
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| Keywords: | TIC Keywords: Root systems; Carbon dioxide; Native grasses; Ecosystems; Calcareous soils; Biomass; Root length; Density; Life cycle; Temperatures; Survival; Grasslands; Carbon dioxide exchange rate; Carbon dioxide enrichment; Respiration; Atmospheric ecodormancy
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| Abstract/Contents: | "The objectives of this paper were to review the literature on the responses of root systems to elevated CO₂ in intact, native grassland ecosystems, and to present the results from a 2-yr study of root production and mortality in an intact calcareous grassland in Switzerland. Previous work in intact native grassland systems has revealed that significant stimulation of the size of root systems (biomass, length density or root number) is not a universal response to elevated CO₂. Of the 12 studies reviewed, seven showed little or no change in root-system size under elevated CO₂, while five showed marked increases (average increase 38%). Insufficient data are available on the effects of elevated CO₂ on root production, mortality and life span to allow generalization about effects. The diversity of experimental techniques employed in these native grassland studies also makes generalization difficult. In the present study, root production and mortality were monitored in situ in a species-rich calcareous grassland community using minirhizotrons in order to test the hypothesis that an increase in these two measures would help explain the increase in net ecosystem CO₂ uptake (net ecosystem exchange) previously observed under elevated CO₂ at this site (600 vs 350 μ1 CO₂ 1⁻¹; eight 1.2-m² experimental plots per CO₂ using the screen-aided CO₂ control method). However, results from the first 2 yr showed no difference in overall root production or mortality in the top 18 cm of soil, where 80-90% of the roots occur. Elevated CO₂ was associated with an upward shift in root length density: under elevated CO₂ a greater proportion of roots were found in the upper 0-6-cm soil layer, and a lower proportion of roots in the lower 12-18 cm, than under ambient CO₂. Elevated CO₂ CO₂ was also associated with an increase in root survival probability (RSP; e.g. for roots still alive 280 d after they were produced under ambient CO₂, RSP= 0.30;elevated CO₂, RSP= 0.56) and an increase (48%) in median root life span in the deepest (12-18 cm) soil layer. The factors driving changes in root distribution and longevity with depth under elevated CO₂ were not clear, but might have been related to increases in soil moisture under elevated CO₂ interacting with vertical patterns in soil temperatures. Thus extra CO₂ taken up in this grassland ecosystem during the growing season under elevated CO₂ could not be explained by changes in root production and mortality. However, C and nutrient cycling might be shifted closer to the soil surface, which could potentially have a substantial effect on the activities of soil heterotrophic organisms as CO₂ levels rise." |
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| Language: | English |
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| References: | 88 |
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| Note: | Erratum, published in volume 147, issue 2, August 2000, p. 411: "In Table 1, for alpine grassland (Switzerland, 2480 m) in year 2 (cool), the observed soil depth should be given as 0-10 cm (as originally printed there is no soil depth given). In Table 2, the period covered should be 28 April 1994 to 6 April 1995, not 28 April 1994 to 6 April 1996, as erroneously stated."
Figures
Tables
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| ASA/CSSA/SSSA Citation (Crop Science-Like - may be incomplete):
Arnone, J. A. III, J. G. Zaller, E. M. Spehn, P. A. Niklaus, C. E. Wells, and C. Körner. 2000. Dynamics of root systems in native grasslands: effects of elevated atmospheric CO₂. New Phytol. 147(1):p. 73-86. |
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| DOI: 10.1046/j.1469-8137.2000.00685 |
| Web URL(s):
http://www.jstor.org/stable/view/2588690
Last checked: 07/16/2014
Access conditions: Item is within a limited-access website
http://www.jstor.org/stable/pdfplus/2588690.pdf
Last checked: 07/16/2014
Requires: PDF Reader
Access conditions: Item is within a limited-access website |
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MSU catalog number: QK 1 .N38 |
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