Yield Response to Soil Warming: Agronomic Crops<sup>1</sup>

Rykbost, K. A.; Boersma, L.; Mack, H. J.; Schmisseur, W.E.

doi:10.2134/agronj1975.00021962006700060001x

Cited by 20 publications

(13 citation statements)

References 3 publications

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“…Soil warming increased the yields of crops by 19%-50% and vegetables by 19%-100% (Rykbost et al 1975), primarily owing to enhanced growth in early spring. Experimental warming increased NPP by up to 25% in a tallgrass prairie (Luo et al 2007) (Figure 3).…”

Section: Photosynthesismentioning

confidence: 99%

Terrestrial Carbon–Cycle Feedback to Climate Warming

Luo

2007

Annu. Rev. Ecol. Evol. Syst.

461

418

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The coupled carbon-climate models reported in the literature all demonstrate a positive feedback between terrestrial carbon cycles and climate warming. A primary mechanism underlying the modeled positive feedback is the kinetic sensitivity of photosynthesis and respiration to temperature. Field experiments, however, suggest much richer mechanisms driving ecosystem responses to climate warming, including extended growing seasons, enhanced nutrient availability, shifted species composition, and altered ecosystem-water dynamics. The diverse mechanisms likely define more possibilities of carbon-climate feedbacks than projected by the kinetics-based models. Nonetheless, experimental results are so variable that we have not generated the necessary insights on ecosystem responses to effectively improve global models. To constrain model projections of carbon-climate feedbacks, we need more empirical data from wholeecosystem warming experiments across a wide range of biomes, particularly in tropic regions, and closer interactions between models and experiments. 683 Annu. Rev. Ecol. Evol. Syst. 2007.38:683-712. Downloaded from www.annualreviews.org Access provided by University of Rhode Island on 02/06/15. For personal use only.

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Section: Photosynthesismentioning

confidence: 99%

Terrestrial Carbon–Cycle Feedback to Climate Warming

Luo

2007

Annu. Rev. Ecol. Evol. Syst.

461

418

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“…Such changes will have a marked effect on soil biology including growth and physiological characteristics of roots. Soil temperature has long been considered as an important ecological factor that determines a variety of structural and functional characteristics in managed and natural ecosystems (Chapin, 1974 ;Rykbost et al, 1975 ;Dixon & Turner, 1991 ;Farnsworth et al, 1995 ;Chapin, 1977 ;Weih & Karlsson, 1999). In some ecosystems, temperature of the root zone is the most important factor in determining net primary productivity (Van Cleve et al, 1981 ;Risser, 1985).…”

Section: Responses To Soil Temperaturementioning

confidence: 99%

Kinetics of nutrient uptake by roots: responses to global change

2000

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There is a growing recognition that accurate predictions of plant and ecosystem responses to global change require a better understanding of the mechanisms that control acquisition of growth-limiting resources. One such key mechanism is root physiological capacity to acquire nutrients. Changes in kinetics of root nitrogen (N) uptake might influence the extent to which terrestrial ecosystems will be able to sequester excesses in carbon (C) and N loads. Despite its significant role in determining plant and ecosystem cycling of C and N, there is little information on whether, or how, root nutrient uptake responds to global change. In this review various components of global change, namely increased CO # concentration, increased soil temperature and increased atmospheric N deposition and their effects on kinetics of root nutrient uptake are examined. The response of root nutrient uptake kinetics to high CO # is highly variable. Most of this variability might be attributable to differences in experimental protocols, but more recent evidence suggests that kinetic responses to high CO # are also species-specific. This raises the possibility that elevated CO # might alter community composition by shifting the competitive interaction of co-occurring species. Uptake of NH % + and NO $ − seem to be differentially sensitive to high CO # , which could influence ecosystem trajectory toward N saturation. Increased soil temperature might increase N and P uptake capacity to a greater extent in species from warm and fluctuating soil habitats than in species from cold and stable soil environments. The few available data also indicate that increased soil temperature elicits a differential effect on uptake of NH % + versus NO $ − . Root uptake kinetics are generally down-regulated in response to long-term exposure to atmospheric N deposition. The extent of this down-regulation might, however, vary among species, stages of succession, land-use history and plant demand. Nonetheless, it is suggested that root N uptake kinetics might be an accurate biological indicator of the ecosystem capacity to retain N. The results reviewed here clearly highlight the scanty nature of the literature in the area of root nutrient absorption responses to global change. It is also clear that effects of one component of global change on root nutrient absorption capacity might be counterbalanced by another. Therefore, the generalizations offered here must be viewed with caution and more effort should be directed to rigorously test these initial observations in future research.

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“…For these species, breeding for cold tolerance in the seedling stage may have little relevance to the growth and development of the plant when the nodal (adventitious) roots are following the 17 -18°C isotherm down into the soil. The observations of Allmaras et al (1973) and Rykbost et al (1975) suggest that breeding adventitious (nodal) roots of these species for cold tolerance may be highly advantageous.…”

Section: B Temperaturementioning

confidence: 96%

Soil Environment Constraints to Root Growth

Zobel¹

1992

Advances in Soil Science

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Yield Response to Soil Warming: Agronomic Crops¹

Cited by 20 publications

References 3 publications

Terrestrial Carbon–Cycle Feedback to Climate Warming

Terrestrial Carbon–Cycle Feedback to Climate Warming

Kinetics of nutrient uptake by roots: responses to global change

Soil Environment Constraints to Root Growth

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Yield Response to Soil Warming: Agronomic Crops1

Cited by 20 publications

References 3 publications

Terrestrial Carbon–Cycle Feedback to Climate Warming

Terrestrial Carbon–Cycle Feedback to Climate Warming

Kinetics of nutrient uptake by roots: responses to global change

Soil Environment Constraints to Root Growth

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Product

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About

Yield Response to Soil Warming: Agronomic Crops¹