Your search keyword '"Trueman, Rebecca J."' showing total 2 results

1. Carbon losses in soils previously exposed to elevated atmospheric CO2 in a chaparral ecosystem: Potential implications for a sustained biospheric C sink

Author

Trueman, Rebecca J., Taneva, Lina, Gonzalez-Meler, Miquel A., Oechel, Walter C., and BassiriRad, Hormoz

Subjects

*CARBON in soils, *ATMOSPHERIC carbon dioxide, *CHAPARRAL, *BIOTIC communities, *CARBON sequestration, *STABLE isotope tracers, *BIOSPHERE, *CARBON dioxide sinks

Abstract

Abstract: Between 1996 and 2001 an experimental set up in a chaparral community near San Diego, CA, examined various plant and ecosystem responses to CO2 concentrations ranging from 250 to 750 μl l−1. These experiments indicated a significant increase in soil C sequestration as CO2 rose above the ambient levels. In 2003, two years after the cessation of the CO2 treatments, we returned to this site to examine soil C dynamics with a particular emphasis on stability of specific pools of C. We found that in as little as two years, C content in the surface soils (0–15 cm) of previously CO2 enriched plots had dropped to levels below those of the ambient and pretreatment soils. In contrast, C retained in response to CO2 enrichment was more durable in the deeper soil layers (>25 cm deep) where both organic and inorganic C were on average 26% and 55% greater, respectively, than C content of ambient plots. Using stable isotope tracers, we found that treatment C represented 25% of total soil C and contributed to 55% of soil CO2 efflux, suggesting that most of treatment C is readily accessible to decomposers. We also found that, C present before CO2 fumigation was decomposed at a faster rate in the plots that were exposed to elevated CO2 than in those exposed to ambient CO2 levels. To our knowledge, this is the first report that allows for a detail accounting of soil C after ceasing CO2 treatments. Our study provides a unique insight to how stable the accrued soil C is as CO2 increases in the atmosphere. [Copyright &y& Elsevier]

Published

2009

2. Plant Respiration and Elevated Atmospheric CO2 Concentration: Cellular Responses and Global Significance.

Author

GONZALEZ-MELER, MIQUEL A., TANEVA, LINA, and TRUEMAN, REBECCA J.

Subjects

RESPIRATION in plants, EFFECT of carbon dioxide on plants, PLANT growth, PHOTOSYNTHESIS, BIOTIC communities, PLANT size

Abstract

• Background Elevated levels of atmospheric [CO2] are likely to enhance photosynthesis and plant growth, which, in turn, should result in increased specific and whole-plant respiration rates. However, a large body of literature has shown that specific respiration rates of plant tissues are often reduced when plants are exposed to, or grown at, high [CO2] due to direct effects on enzymes and indirect effects derived from changes in the plant's chemical composition.• Scope Although measurement artefacts may have affected some of the previously reported effects of CO2 on respiration rates, the direction and magnitude for the effects of elevated [CO2] on plant respiration may largely depend on the vertical scale (from enzymes to ecosystems) at which measurements are taken. In this review, the effects of elevated [CO2] from cells to ecosystems are presented within the context of the enzymatic and physiological controls of plant respiration, the role(s) of non-phosphorylating pathways, and possible effects associated with plant size.• Conclusions Contrary to what was previously thought, specific respiration rates are generally not reduced when plants are grown at elevated [CO2]. However, whole ecosystem studies show that canopy respiration does not increase proportionally to increases in biomass in response to elevated [CO2], although a larger proportion of respiration takes place in the root system. Fundamental information is still lacking on how respiration and the processes supported by it are physiologically controlled, thereby preventing sound interpretations of what seem to be species-specific responses of respiration to elevated [CO2]. Therefore the role of plant respiration in augmenting the sink capacity of terrestrial ecosystems is still uncertain. [ABSTRACT FROM AUTHOR]

Published

2004