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Title: Rangeland -- Plant responses to elevated CO sub 2

Abstract

Several broad conclusions which can be drawn from the work that was accomplished during the first 3-year phase of the study is described. In prairie ecosystems dominated by C{sub 4} grasses, it is likely that elevated atmospheric CO{sub 2} will increase ecosystem level productivity, with a greater increase in belowground productivity. The increased productivity will primarily result from increased water use efficiency due to the anti-transpirant action of CO{sub 2}. Fumigation chambers are directly confounded with elevated CO{sub 2} effects, in that both reduce evapotranspiration. The reduced evapotranspiration of the fumigation chamber is primarily through reduced wind speeds and reduced radiation. In very dry years, fumigation chamber effects are negligible, but in years with normal precipitation, chamber effects and elevated CO{sub 2} effects are essentially equal with respect to reduced evapotranspiration effects. Increased production under elevated CO{sub 2} results in reduced nitrogen concentration in the herbage and increased fiber concentrations. Consequently, digestibility of the herbage is reduced, and microbial degradation of surface litter and soil organic matter is slowed. On the negative side, ruminant productivity will likely be reduced substantially, but increased carbon storage in the soil may buffer against future rise in atmospheric CO{sub 2}. Tallgrass prairie will notmore » likely change greatly in botanical composition, since the C{sub 4} dominants responded to elevated CO{sub 2} more than the C{sub 3} subdominants.« less

Authors:
; ; ; ; ; ;
Publication Date:
Research Org.:
Kansas State Univ., Manhattan, KS (United States). Dept. of Agronomy
Sponsoring Org.:
USDOE; USDOE, Washington, DC (United States)
OSTI Identifier:
7034458
Report Number(s):
DOE/ER/60253-T5
ON: DE93000883
DOE Contract Number:
FG02-84ER60253
Resource Type:
Technical Report
Country of Publication:
United States
Language:
English
Subject:
54 ENVIRONMENTAL SCIENCES; CARBON DIOXIDE; ENVIRONMENTAL EFFECTS; GRAMINEAE; PLANT GROWTH; RANGELANDS; CARBON CYCLE; BIOMASS; CARBON 13; CARBON DIOXIDE FIXATION; CARBON SINKS; CLIMATIC CHANGE; FIELD TESTS; ISOTOPE RATIO; NITROGEN CYCLE; PROGRESS REPORT; CARBON COMPOUNDS; CARBON ISOTOPES; CARBON OXIDES; CHALCOGENIDES; DOCUMENT TYPES; ECOSYSTEMS; ENERGY SOURCES; EVEN-ODD NUCLEI; GROWTH; ISOTOPES; LIGHT NUCLEI; LILIOPSIDA; MAGNOLIOPHYTA; NUCLEI; OXIDES; OXYGEN COMPOUNDS; PLANTS; RENEWABLE ENERGY SOURCES; SINKS; STABLE ISOTOPES; TERRESTRIAL ECOSYSTEMS; TESTING; 540220* - Environment, Terrestrial- Chemicals Monitoring & Transport- (1990-); 540120 - Environment, Atmospheric- Chemicals Monitoring & Transport- (1990-)

Citation Formats

Owensby, C.E., Coyne, P.I., Ham, J.M., Parton, W., Rice, C., Auen, L.M., and Adam, N. Rangeland -- Plant responses to elevated CO sub 2. United States: N. p., 1992. Web. doi:10.2172/7034458.
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Owensby, C.E., Coyne, P.I., Ham, J.M., Parton, W., Rice, C., Auen, L.M., & Adam, N. Rangeland -- Plant responses to elevated CO sub 2. United States. doi:10.2172/7034458.
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Owensby, C.E., Coyne, P.I., Ham, J.M., Parton, W., Rice, C., Auen, L.M., and Adam, N. Wed . "Rangeland -- Plant responses to elevated CO sub 2". United States. doi:10.2172/7034458. https://www.osti.gov/servlets/purl/7034458.
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@article{osti_7034458,
title = {Rangeland -- Plant responses to elevated CO sub 2},
author = {Owensby, C.E. and Coyne, P.I. and Ham, J.M. and Parton, W. and Rice, C. and Auen, L.M. and Adam, N.},
abstractNote = {Several broad conclusions which can be drawn from the work that was accomplished during the first 3-year phase of the study is described. In prairie ecosystems dominated by C{sub 4} grasses, it is likely that elevated atmospheric CO{sub 2} will increase ecosystem level productivity, with a greater increase in belowground productivity. The increased productivity will primarily result from increased water use efficiency due to the anti-transpirant action of CO{sub 2}. Fumigation chambers are directly confounded with elevated CO{sub 2} effects, in that both reduce evapotranspiration. The reduced evapotranspiration of the fumigation chamber is primarily through reduced wind speeds and reduced radiation. In very dry years, fumigation chamber effects are negligible, but in years with normal precipitation, chamber effects and elevated CO{sub 2} effects are essentially equal with respect to reduced evapotranspiration effects. Increased production under elevated CO{sub 2} results in reduced nitrogen concentration in the herbage and increased fiber concentrations. Consequently, digestibility of the herbage is reduced, and microbial degradation of surface litter and soil organic matter is slowed. On the negative side, ruminant productivity will likely be reduced substantially, but increased carbon storage in the soil may buffer against future rise in atmospheric CO{sub 2}. Tallgrass prairie will not likely change greatly in botanical composition, since the C{sub 4} dominants responded to elevated CO{sub 2} more than the C{sub 3} subdominants.},
doi = {10.2172/7034458},
journal = {},
number = ,
volume = ,
place = {United States},
year = {Wed Jan 01 00:00:00 EST 1992},
month = {Wed Jan 01 00:00:00 EST 1992}
}
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Technical Report:
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DOI:  10.2172/7034458
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  • Research is described on plant (tallgrass) response to elevated carbon dioxide. Variables addressed include biomass production, as well as water use efficiency, photosynthetic capacity, decomposition, nutrient cycling, and forage quality.

  • ; ; ; ...
    Several broad conclusions which can be drawn from the work that was accomplished during the first 3-year phase of the study is described. In prairie ecosystems dominated by C{sub 4} grasses, it is likely that elevated atmospheric CO{sub 2} will increase ecosystem level productivity, with a greater increase in belowground productivity. The increased productivity will primarily result from increased water use efficiency due to the anti-transpirant action of CO{sub 2}. Fumigation chambers are directly confounded with elevated CO{sub 2} effects, in that both reduce evapotranspiration. The reduced evapotranspiration of the fumigation chamber is primarily through reduced wind speeds and reducedmore » radiation. In very dry years, fumigation chamber effects are negligible, but in years with normal precipitation, chamber effects and elevated CO{sub 2} effects are essentially equal with respect to reduced evapotranspiration effects. Increased production under elevated CO{sub 2} results in reduced nitrogen concentration in the herbage and increased fiber concentrations. Consequently, digestibility of the herbage is reduced, and microbial degradation of surface litter and soil organic matter is slowed. On the negative side, ruminant productivity will likely be reduced substantially, but increased carbon storage in the soil may buffer against future rise in atmospheric CO{sub 2}. Tallgrass prairie will not likely change greatly in botanical composition, since the C{sub 4} dominants responded to elevated CO{sub 2} more than the C{sub 3} subdominants.« less

  • Nine circular plots were established on native tallgrass prairie near Kansas State University campus. Plots were separately exposed to ambient CO2, double ambient (enriched) CO2. Plots were moved annually in late February and have had various fertilization schemes applied. Grasses were examined for biomass production, water use efficiency, photosynthetic capacity, nutrient limitations, decomposition and nutrient cycling, and forage quality. It was found that C4, but not C3, grass species exhibited increased biomass production.

  • ; ;
    Effects of carbon dioxide enrichment on a tallgrass ecosystem were monitored during the 1989 growing season. The experimental site was located in pristine Tallgrass Prairie north of/and adjacent to the Kansas State University campus. Vegetation on the site was a mixture of C{sub 3} and C{sub 4} species and was dominated by big bluestem and indiangrass. Subdominants included Kentucky bluegrass, sideoats grama, and tall dropseed. Principal forbs included western ragweed, Louisiana sagewort, and mayflower scurfpea. The area was ideal for meeting the experimental objectives, in that the mixture of C3 and C4 plants would allow for assessment of competitive relationshipsmore » among numerous species of both carbon fixation pathways. The objectives of this project were: to characterize the effects of CO{sub 2} enrichment on changes in diet selection and diet quality for ruminants, to monitor plant population dynamics under ambient and CO{sub 2}-enriched atmospheres, and to measure biomass accumulation and leaf area during the growing season under ambient and Co{sub 2}-enriched atmospheres. During 1989 we developed and tested the system and were able to collect substantial data concerning the effects of CO{sub 2} enrichment of tallgrass prairie. In this report we detail chamber design, data acquisition, control of the chamber environment, biomass and leaf area response to CO{sub 2} enrichment, and collection of forage quality samples using esophageally-fistulated sheep. 23 refs., 21 figs., 1 tab.« less

  • ; ; ; ...
    No studies have been published concerning the effect of elevated levels of atmospheric carbon dioxide (CO{sub 2}) on the growth of range plants in a natural habitat. Therefore, the objective of this research was to determine the response of plants on a native grassland to different CO{sub 2} concentrations and soil-moisture conditions. The study was carried out during the 1989 growing season on a rangeland in Manhattan, Kansas. Sixteen large, closed-top, plastic chambers were constructed and placed on the experimental site. Half of the chambers received the ambient level of CO{sub 2} and half of the chambers received two-times themore » ambient concentration. Half of the chambers were irrigated to maintain well-watered conditions and half of the chambers were drought-stressed. There were four replications. During the season, measurements of soil-water content were taken, as well as measurements of transpiration, stomatal resistance photosynthesis, and CO{sub 2} concentration in the intercellular spaces of the leaves of big bluestem. At harvest on 31 October 1989, plants were divided into four groups: warm-season grasses; cool-season grasses; sedges; and forbs. 20 refs., 16 figs., 9 tabs.« less