Orla Dermody scite author profile

The effects of elevated [CO2] on 25 variables describing soybean physiology, growth and yield are reviewed using meta‐analytic techniques. This is the first meta‐analysis to our knowledge performed on a single crop species and summarizes the effects of 111 studies. These primary studies include numerous soybean growth forms, various stress and experimental treatments, and a range of elevated [CO2] levels (from 450 to 1250 p.p.m.), with a mean of 689 p.p.m. across all studies. Stimulation of soybean leaf CO2 assimilation rate with growth at elevated [CO2] was 39%, despite a 40% decrease in stomatal conductance and a 11% decrease in Rubisco activity. Increased leaf CO2 uptake combined with an 18% stimulation in leaf area to provide a 59% increase in canopy photosynthetic rate. The increase in total dry weight was lower at 37%, and seed yield still lower at 24%. This shows that even in an agronomic species selected for maximum investment in seed, several plant level feedbacks prevent additional investment in reproduction, such that yield fails to reflect fully the increase in whole plant carbon uptake. Large soil containers (> 9 L) have been considered adequate for assessing plant responses to elevated [CO2]. However, in open‐top chamber experiments, soybeans grown in large pots showed a significant threefold smaller stimulation in yield than soybeans grown in the ground. This suggests that conclusions about plant yield based on pot studies, even when using very large containers, are a poor reflection of performance in the absence of any physical restriction on root growth. This review supports a number of current paradigms of plant responses to elevated [CO2]. Namely, stimulation of photosynthesis is greater in plants that fix N and have additional carbohydrate sinks in nodules. This supports the notion that photosynthetic capacity decreases when plants are N‐limited, but not when plants have adequate N and sink strength. The root : shoot ratio did not change with growth at elevated [CO2], sustaining the charge that biomass allocation is unaffected by growth at elevated [CO2] when plant size and ontogeny are considered.

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Intensifying drought eliminates the expected benefits of elevated carbon dioxide for soybean

Gray

et al. 2016

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Stimulation of C3 crop yield by rising concentrations of atmospheric carbon dioxide ([CO2]) is widely expected to counteract crop losses that are due to greater drought this century. But these expectations come from sparse field trials that have been biased towards mesic growth conditions. This eight-year study used precipitation manipulation and year-to-year variation in weather conditions at a unique open-air field facility to show that the stimulation of soybean yield by elevated [CO2] diminished to zero as drought intensified. Contrary to the prevalent expectation in the literature, rising [CO2] did not counteract the effect of strong drought on photosynthesis and yield because elevated [CO2] interacted with drought to modify stomatal function and canopy energy balance. This new insight from field experimentation under hot and dry conditions, which will become increasingly prevalent in the coming decades, highlights the likelihood of negative impacts from interacting global change factors on a key global commodity crop in its primary region of production.

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Leaf photosynthesis and carbohydrate dynamics of soybeans grown throughout their life‐cycle under Free‐Air Carbon dioxide Enrichment

Rogers

Allen

Davey

et al. 2004

Plant Cell & Environment

190

170

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How does elevated CO₂ or ozone affect the leaf‐area index of soybean when applied independently?

2005

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Elevated atmospheric carbon dioxide and ozone alter soybean diseases at SoyFACE

Eastburn

Degennaro

DeLucia

et al. 2009

Global Change Biology

121

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Human driven changes in the Earth's atmospheric composition are likely to alter plant disease in the future. We evaluated the effects of elevated carbon dioxide (CO 2 ) and ozone (O 3 ) on three economically important soybean diseases (downy mildew, Septoria brown spot and sudden death syndrome-SDS) under natural field conditions at the soybean free air concentration enrichment (SoyFACE) facility. Disease incidence and/or severity were quantified from 2005 to 2007 using visual surveys and digital image analysis, and changes were related to microclimatic variability and to structural and chemical changes in soybean host plants. Changes in atmospheric composition altered disease expression, but responses of the three pathosystems varied considerably. Elevated CO 2 alone or in combination with O 3 significantly reduced downy mildew disease severity (measured as area under the disease progress curve-AUDPC) by 39-66% across the 3 years of the study. In contrast, elevated CO 2 alone or in combination with O 3 significantly increased brown spot severity in all 3 years, but the increase was small in magnitude. When brown spot severity was assessed in relation to differences in canopy height induced by the atmospheric treatments, disease severity increased under combined elevated CO 2 and O 3 treatment in only one of the 3 years. The atmospheric treatments had no effect on the incidence of SDS or brown spot throughout the study. Higher precipitation during the 2006 growing season was associated with increased AUDPC severity across all treatments by 2.7 and 1.4 times for downy mildew and brown spot, respectively, compared with drought conditions in 2005. In the 2 years with similar precipitation, the higher daily temperatures in the late spring of 2007 were associated with increased severity of downy mildew and brown spot. Elevated CO 2 and O 3 induced changes in the soybean canopy density and leaf age likely contributed to the disease expression modifications.

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Orla Dermody

A meta‐analysis of elevated [CO₂] effects on soybean (Glycine max) physiology, growth and yield

Intensifying drought eliminates the expected benefits of elevated carbon dioxide for soybean

Leaf photosynthesis and carbohydrate dynamics of soybeans grown throughout their life‐cycle under Free‐Air Carbon dioxide Enrichment

How does elevated CO₂ or ozone affect the leaf‐area index of soybean when applied independently?

Elevated atmospheric carbon dioxide and ozone alter soybean diseases at SoyFACE

Contact Info

Product

Resources

About

Orla Dermody

A meta‐analysis of elevated [CO2] effects on soybean (Glycine max) physiology, growth and yield

Intensifying drought eliminates the expected benefits of elevated carbon dioxide for soybean

Leaf photosynthesis and carbohydrate dynamics of soybeans grown throughout their life‐cycle under Free‐Air Carbon dioxide Enrichment

How does elevated CO2 or ozone affect the leaf‐area index of soybean when applied independently?

Elevated atmospheric carbon dioxide and ozone alter soybean diseases at SoyFACE

Contact Info

Product

Resources

About

A meta‐analysis of elevated [CO₂] effects on soybean (Glycine max) physiology, growth and yield

How does elevated CO₂ or ozone affect the leaf‐area index of soybean when applied independently?