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Decomposition of litter produced under elevated CO2: Dependence on plant species and nutrient supply

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Abstract

We investigated the effect of CO2 concentration and soilnutrient availability during growth on the subsequent decomposition andnitrogen (N) release from litter of four annual grasses that differ inresource requirements and native habitat. Vulpia microstachys isa native grass found on California serpentine soils, whereas Avenafatua, Bromus hordaceus, and Lolium multiflorum areintroduced grasses restricted to more fertile sandstone soils (Hobbs & Mooney 1991). Growth in elevated CO2 altered litter C:N ratio,decomposition, and N release, but the direction and magnitude of thechanges differed among plant species and nutrient treatments. ElevatedCO2 had relatively modest effects on C:N ratio of litter,increasing this ratio in Lolium roots (and shoots at high nutrients),but decreasing C:N ratio in Avena shoots. Growth of plants underelevated CO2 decreased the decomposition rate of Vulpialitter, but increased decomposition of Avena litter from the high-nutrient treatment. The impact of elevated CO2 on N loss fromlitter also differed among species, with Vulpia litter from high-CO2 plants releasing N more slowly than ambient-CO2litter, whereas growth under elevated CO2 caused increased Nloss from Avena litter. CO2 effects on N release in Lolium and Bromus depended on the nutrient regime in whichplants were grown. There was no overall relationship between litter C:Nratio and decomposition rate or N release across species and treatments.Based on our study and the literature, we conclude that the effects ofelevated CO2 on decomposition and N release from litter arehighly species-specific. These results do not support the hypothesis thatCO2 effects on litter quality consistently lead to decreasednutrient availability in nutrient-limited ecosystems exposed to elevatedCO2.

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References

  • Barnes JD & Pfirrmann T (1992) The influence of CO2 and O3, singly and in combination, on gas exchange, growth and nutrient status of radish (Raphanus sativus). New Phytol. 121: 403–412

    Google Scholar 

  • Bazzaz FA (1990) The response of natural ecosystems to the rising global CO2 levels. Annu. Rev. Ecol. Syst. 21: 167–196

    Google Scholar 

  • Billes G, Rouhier H & Bottner P (1990) Modifications of the carbon and nitrogen allocations in the plant (Triticum aestivumL.) soil system in response to increased atmospheric CO2 concentration. Plant Soil 157: 215–225

    Google Scholar 

  • Boerner REJ & Rebbeck J (1995) Decomposition and nitrogen release from leaves of three hardwood species grown under elevated O3 and/or CO2. Plant Soil 170: 149–157

    Google Scholar 

  • Brown KR (1991) Carbon dioxide enrichment accelerates the decline in nutrient status and relative growth rate of Populus tremuloidesMichx. seedlings. Tree Physiol. 8: 161–173

    Google Scholar 

  • Chu CC, Coleman JS & Mooney HA (1992) Control of biomass partitioning between roots and shoots: Atmospheric CO2 enrichment and the acquisition and allocation of carbon and nitrogen in wild radish. Oecologia 89: 580–587

    Google Scholar 

  • Chu CC, Field CB & Mooney HA (in press) Effects of CO2 and nutrient enrichment on tissue quality of two California annuals. Oecologia

  • Comins HN & McMurtrie RE (1993) Long-term response of nutrient-limited forests to CO2 enrichment: equilibrium behavior of plant-soil models. Ecol. Appl. 3: 666–681

    Google Scholar 

  • Cotrufo MF & Ineson P (1995) Effects of enhanced atmospheric CO2 and nutrient supply on the quality and subsequent decomposition of fine roots of Betula pendulaRoth. and Picea sitchensis(Bong.) Carr. Plant Soil 170: 267–277

    Google Scholar 

  • Cotrufo MF, Ineson P & Rowland AP (1994) Decomposition of tree leaf litters grown under elevated CO2: Effect of litter quality. Plant Soil 163: 121–130

    Google Scholar 

  • Coûteaux M-M, Mousseau M, Celerier M-L & Bottner P (1991) Increased atmospheric CO2 and litter quality: Decomposition of sweet chestnut leaf litter with animal food webs of different complexities. Oikos 61: 54–64

    Google Scholar 

  • Curtis PS, Balduman LM, Drake BG & Whigham DF (1990) Elevated atmospheric CO2 effects on belowground processes in C3 and C4 estuarine marsh communities. Ecology 71: 2001–2006

    Google Scholar 

  • Diaz SA, Grime JP, Harris J & McPherson E (1993) Evidence of a feedback mechanism limiting plant response to elevated carbon dioxide. Nature 364: 616–617

    Google Scholar 

  • Dixon RK & Turner DP (1991) The global carbon cycle and climate change: Responses and feedbacks from below-ground systems. Environ. Pollu. 73: 245–262

    Google Scholar 

  • Field C, Chapin FS III, Matson PA & Mooney HA(1992) Responses of terrestrial ecosystems to the changing atmosphere: A resource-based approach. Annu. Rev. Ecol. Syst. 23: 201–235

    Google Scholar 

  • Field CB, Chapin FS III, Chiariello NR, Holland EA & Mooney HA (1996) The Jasper Ridge CO2 experiment: Design and motivation. In: Koch GW & Mooney HA (Eds) Carbon Dioxide and Terrestrial Ecosystems (pp 121–145). Academic Press, San Diego

    Google Scholar 

  • Garbutt K, Williams WE & Bazzaz FA (1990) Analysis of the differential response of five annuals to elevated CO2 during growth. Ecology 71: 1185–1194

    Google Scholar 

  • Hickman JC (1993) The Jepson Manual, Higher Plants of California. University of California Press, Berkeley

    Google Scholar 

  • Hobbie SE (in press) Temperature and plant species' control over litter decomposition in Alaskan tundra. Ecology

  • Hobbs RJ & Mooney HA (1991) Effects of rainfall variability and gopher disturbance on serpentine annual grassland dynamics. Ecology 72: 59–68

    Google Scholar 

  • Huenneke LF, Hamburg SP, Koide R, Mooney HA & Vitousek PM (1990) Effects of soil resources on plant invasion and community structure in Californian serpentine grassland. Ecology 71: 478–491

    Google Scholar 

  • Hungate BA, Canadell JC & Chapin FS III (in press) Plant species mediate changes in microbial N in response to elevated CO2. Ecology

  • Hungate BA, Chapin FS III, Zhong H, Holland EA & Field CB (in press) Stimulation of grassland nitrogen cycling under carbon dioxide enrichment. Oecologia

  • Kemp PR, Waldecker DG, Owensby CE, Reynolds JF & Virginia RA(1994) Effects of elevated CO2 and nitrogen fertilization pretreatments on decomposition on tallgrass prairie leaf litter. Plant Soil 165: 115–127

    Google Scholar 

  • Kohen EI, Rouhier H & Mousseau M (1992) Changes in dry weight and nitrogen partitioning induced by elevated CO2 depend on soil nutrient availability in sweet chestnut (Castanea sativaMill.). Ann. Sci. For. 49: 83–90

    Google Scholar 

  • Lambers H (1993) Rising CO2, secondary plant metabolism, plant-herbivore interactions and litter decomposition. Vegetatio 104: 263–271

    Google Scholar 

  • Lindroth RL, Kinney KK & Platz CL (1993) Responses of deciduous trees to elevated atmospheric CO2: Productivity, phytochemistry and insect resistance. Ecology 74: 763–777

    Google Scholar 

  • Luo Y, Field CB & Mooney HA(1994) Predicting responses of photosynthesis and root fraction to elevated [CO2]: Interactions among carbon, nitrogen, and growth. Plant Cell Environ. 17: 1195–1204

    Google Scholar 

  • McNaughton SJ (1968) Structure and function of California grasslands. Ecology 49: 962–972

    Google Scholar 

  • Melillo JM, Aber JD & Muratore JF (1982) Nitrogen and lignin control of hardwood leaf litter decomposition dynamics. Ecology 63: 621–626

    Google Scholar 

  • Mooney HA, Drake BG, Luxmoore RJ, Oechel WC & Pitelka LF (1991) Predicting ecosystem responses to elevated CO2 concentrations. BioScience 41: 96–104

    Google Scholar 

  • Mooney HA, Hobbs RJ, Gorham J & Williams K (1986) Biomass accumulation and resource utilization in co-occurring grassland annuals. Oecologia 70: 555–558

    Google Scholar 

  • Norby RJ & O'Neill EG (1991) Leaf area compensation and nutrient interactions in CO2-enriched seedlings of yellow-poplar (Liriodendron tulipiferaL.). New Phytol. 117: 515–528

    Google Scholar 

  • Norby RJ, Pastor J & Melillo JM (1986) Carbon-nitrogen interactions in CO2-enriched white oak: Physiological and long term perspectives. Tree Physiology 2: 233–241

    Google Scholar 

  • O'Neill EG (1994) Responses of soil biota to elevated atmospheric carbon dioxide. Plant Soil 165: 55–65

    Google Scholar 

  • Post WM, Peng T-H, Emanuel WR, King AW, Dale VH & DeAngelis DL (1990) The global carbon cycle. Am. Sci. 78: 310–326

    Google Scholar 

  • Shaver GR, Billings WD, Chapin FS III, Giblin AE, Nadelhoffer KJ, Oechel WC & Rastetter EB (1992) Global change and the carbon balance of arctic ecosystems. BioScience 61: 415–435

    Google Scholar 

  • Taylor BR, Parkinson D & Parsons WFJ (1989) Nitrogen and lignin as predictors of litter decay rates: A microcosm test. Ecology 70: 97–104

    Google Scholar 

  • Turitzin SN (1982) Nutrient limitations to plant growth in a California serpentine grassland. Am. Midl. Nat. 107: 95–99

    Google Scholar 

  • Vitousek PM & Howarth RW (1991) Nitrogen limitation on land and in the sea: How can it occur? Biogeochemistry 13: 87–115

    Google Scholar 

  • Winer BJ, Brown DR & Michels KM (1991) Statistical Principles in Experimental Design. McGraw-Hill, Inc., New York, New York, USA

    Google Scholar 

Download references

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Author notes

  1. BRUCE A. HUNGATE

    Present address: Smithsonian Environmental Research Center, PO Box 28, Edgewater, MD, 21037, USA

Authors and Affiliations

  1. Department of Integrative Biology, University of California, Berkeley, CA, 94720-3140, USA

    VALERIE M. FRANCK, BRUCE A. HUNGATE & F. STUART CHAPIN III

  2. Carnegie Institution of Washington, Stanford, CA, 94305, USA

    CHRISTOPHER B. FIELD

Authors
  1. VALERIE M. FRANCK
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  2. BRUCE A. HUNGATE
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  3. F. STUART CHAPIN III
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  4. CHRISTOPHER B. FIELD
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Correspondence to F. STUART CHAPIN III.

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FRANCK, V.M., HUNGATE, B.A., CHAPIN, F.S. et al. Decomposition of litter produced under elevated CO2: Dependence on plant species and nutrient supply. Biogeochemistry 36, 223–237 (1997). https://doi.org/10.1023/A:1005705300959

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