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United States Department of Agriculture

Agricultural Research Service

Title: Photosynthetic water use efficiency and biomass of Sorghastrum nutans (C4) and Solidago canadensis (C3) in three soils along a CO2 concentration gradient

Authors
item Fay, Philip
item Hui, Dafend - DUKE UNIVERSITY
item Procter, Andrew - DUKE UNIVERSITY
item Jin, Virginia
item Johnson, Hyrum - COLLABORATOR
item Polley, Wayne
item Jackson, Robert - DUKE UNIVERSITY

Submitted to: Ecological Society of America Abstracts
Publication Type: Abstract Only
Publication Acceptance Date: June 4, 2007
Publication Date: September 5, 2007
Citation: Fay, P.A., Hui, D., Procter, A., Jin, V.L., Johnson, H.B., Polley, H.W., Jackson, R.B. 2007. Photosynthetic water use efficiency and biomass of Sorghastrum nutans (C4) and Solidago canadensis (C3) in three soils along a CO2 concentration gradient. In: Proceedings of the Ecological Society of America, August 5-10, 2007, San Jose, California. 2007 CDROM.

Technical Abstract: The water use efficiency (WUE) of leaf photosynthetic carbon uptake is a key regulator of plant production in grasslands. However WUE may differ with soil type because of differences in soil moisture retention and plant uptake efficiency. We measured soil water content (SWC, 0-30 cm, %), leaf-level WUE (ratio of photosynthesis, AC02, to transpiration, E) and end-of-season biomass in the C4 grass Sorghastrum nutans and the C3 forb Solidago canadensis growing in well-established multi-species communities on three soil types (Austin, Bastrop, and Houston series) along an experimental [CO2] gradient. SWC was lower on the Bastrop than Austin or Houston soils (p < 0.0001). WUE did not differ between soil types for either species, but the biomass of both S. nutans and S. canadensis was 2 to 4 -fold greater on Bastrop and Houston than on Austin soils (p </- 0.05). However, photosynthetic WUE increased strongly (p<0.0001) at higher [CO2] in both species (species x [CO2] ns), due to a combination of decreasing E and increasing ACO2 (p </- 0.005). Biomass of S. nutans was not related to [CO2], however biomass of S. canadensis increased strongly at higher [CO2] on Bastrop and Houston soils (soil x [CO2] p = 0.0003). We conclude that 1) [CO2] was the primary control on leaf-level photosynthetic water use efficiency, 2) soil type was the primary control on growth, and 3) there was not a consistent association between WUE and biomass responses to [CO2] in these species.

Last Modified: 11/26/2014
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