Contrasting responses of shrubland carbon gain and soil carbon efflux to drought and warming across a European climate gradient

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Contrasting responses of shrubland carbon gain and soil carbon efflux to drought and warming across a European climate gradient. / Reinsch, Sabine; Koller, Eva; Sowerby, Alwyn; de Dato, Giovanbattista; Estiarte, Marc; Guidolotti, Gabriele; Kovács-Láng, Edit; Kröel-Dulay, György; Lellei-Kovács, Eszter; Larsen, Klaus S.; Liberati, Dario; Penuelas, Josep; Ransijn, Johannes; Schmidt, Inger K.; Smith, Andrew R.; Tietema, Albert; Dukes, Jeffrey S.; Emmett, Bridget A.

In: Geophysical Research Abstracts, Vol. 18, 2016.

Research output: Contribution to journalConference abstract in journalResearch

Harvard

Reinsch, S, Koller, E, Sowerby, A, de Dato, G, Estiarte, M, Guidolotti, G, Kovács-Láng, E, Kröel-Dulay, G, Lellei-Kovács, E, Larsen, KS, Liberati, D, Penuelas, J, Ransijn, J, Schmidt, IK, Smith, AR, Tietema, A, Dukes, JS & Emmett, BA 2016, 'Contrasting responses of shrubland carbon gain and soil carbon efflux to drought and warming across a European climate gradient', Geophysical Research Abstracts, vol. 18. <http://adsabs.harvard.edu/abs/2016EGUGA..1816183R>

APA

Reinsch, S., Koller, E., Sowerby, A., de Dato, G., Estiarte, M., Guidolotti, G., Kovács-Láng, E., Kröel-Dulay, G., Lellei-Kovács, E., Larsen, K. S., Liberati, D., Penuelas, J., Ransijn, J., Schmidt, I. K., Smith, A. R., Tietema, A., Dukes, J. S., & Emmett, B. A. (2016). Contrasting responses of shrubland carbon gain and soil carbon efflux to drought and warming across a European climate gradient. Geophysical Research Abstracts, 18. http://adsabs.harvard.edu/abs/2016EGUGA..1816183R

Vancouver

Reinsch S, Koller E, Sowerby A, de Dato G, Estiarte M, Guidolotti G et al. Contrasting responses of shrubland carbon gain and soil carbon efflux to drought and warming across a European climate gradient. Geophysical Research Abstracts. 2016;18.

Author

Reinsch, Sabine ; Koller, Eva ; Sowerby, Alwyn ; de Dato, Giovanbattista ; Estiarte, Marc ; Guidolotti, Gabriele ; Kovács-Láng, Edit ; Kröel-Dulay, György ; Lellei-Kovács, Eszter ; Larsen, Klaus S. ; Liberati, Dario ; Penuelas, Josep ; Ransijn, Johannes ; Schmidt, Inger K. ; Smith, Andrew R. ; Tietema, Albert ; Dukes, Jeffrey S. ; Emmett, Bridget A. / Contrasting responses of shrubland carbon gain and soil carbon efflux to drought and warming across a European climate gradient. In: Geophysical Research Abstracts. 2016 ; Vol. 18.

Bibtex

@article{2be3e3ea78c24081b786b8d421ef5e95,
title = "Contrasting responses of shrubland carbon gain and soil carbon efflux to drought and warming across a European climate gradient",
abstract = "Understanding the relationship between above- and belowground processes is crucial if we are to forecast feedbacks between terrestrial carbon (C) dynamics and future climate. To test if climate-induced changes in annual aboveground net primary productivity (aNPP) will drive changes in C loss by soil respiration (Rs), we integrated data across a European temperature and precipitation gradient. For over a decade, six European shrublands were exposed to repeated drought (-30 % annual rain) during the plants' growth season or year-round night-time warming (+1.5 oC), using an identical experimental approach. As a result, drought reduced ecosystem C gain via aNPP by 0-25 % (compared to an untreated control) with the lowest C gain in warm-dry sites and highest in wet-cold sites (R2=0.078, p-value = 0.544, slope = 14.35 %). In contrast, drought induced C loss via Rs was of a lower magnitude (10-20 %) and was most pronounced in warm-dry sites compared to wet-cold sites (R2=0.687, p-value = 0.131, slope = 7.86 %). This suggests that belowground activity (microbes and roots) is stabilizing ecosystem processes and functions in terms of C storage. However, when the drought treatment permanently altered the soil structure at our hydric site, indicating we had exceeded the resilience of the system, the ecosystem C gain was no longer predictable from current (linear) relationships. Results from the warming treatment were generally of lower magnitude and of opposing direction compared to the drought treatment, indicating different mechanisms were driving ecosystem responses. Overall, our results suggest that aNPP is less sensitive than Rs to climate stresses and soil respiration C fluxes are not predictable from changes in plant productivity. Drought and warming effects on aNPP and Rs did not weaken over decadal timescales at larger, continental scales if no catastrophic threshold is passed. However, indirect effects of climate change on soil properties and/or microbial communities need to be further explored",
author = "Sabine Reinsch and Eva Koller and Alwyn Sowerby and {de Dato}, Giovanbattista and Marc Estiarte and Gabriele Guidolotti and Edit Kov{\'a}cs-L{\'a}ng and Gy{\"o}rgy Kr{\"o}el-Dulay and Eszter Lellei-Kov{\'a}cs and Larsen, {Klaus S.} and Dario Liberati and Josep Penuelas and Johannes Ransijn and Schmidt, {Inger K.} and Smith, {Andrew R.} and Albert Tietema and Dukes, {Jeffrey S.} and Emmett, {Bridget A.}",
year = "2016",
language = "English",
volume = "18",
journal = "Geophysical Research Abstracts",
issn = "1607-7962",
publisher = "Copernicus GmbH",
note = "EGU General Assembly 2016 ; Conference date: 18-04-2016 Through 24-04-2016",

}

RIS

TY - ABST

T1 - Contrasting responses of shrubland carbon gain and soil carbon efflux to drought and warming across a European climate gradient

AU - Reinsch, Sabine

AU - Koller, Eva

AU - Sowerby, Alwyn

AU - de Dato, Giovanbattista

AU - Estiarte, Marc

AU - Guidolotti, Gabriele

AU - Kovács-Láng, Edit

AU - Kröel-Dulay, György

AU - Lellei-Kovács, Eszter

AU - Larsen, Klaus S.

AU - Liberati, Dario

AU - Penuelas, Josep

AU - Ransijn, Johannes

AU - Schmidt, Inger K.

AU - Smith, Andrew R.

AU - Tietema, Albert

AU - Dukes, Jeffrey S.

AU - Emmett, Bridget A.

PY - 2016

Y1 - 2016

N2 - Understanding the relationship between above- and belowground processes is crucial if we are to forecast feedbacks between terrestrial carbon (C) dynamics and future climate. To test if climate-induced changes in annual aboveground net primary productivity (aNPP) will drive changes in C loss by soil respiration (Rs), we integrated data across a European temperature and precipitation gradient. For over a decade, six European shrublands were exposed to repeated drought (-30 % annual rain) during the plants' growth season or year-round night-time warming (+1.5 oC), using an identical experimental approach. As a result, drought reduced ecosystem C gain via aNPP by 0-25 % (compared to an untreated control) with the lowest C gain in warm-dry sites and highest in wet-cold sites (R2=0.078, p-value = 0.544, slope = 14.35 %). In contrast, drought induced C loss via Rs was of a lower magnitude (10-20 %) and was most pronounced in warm-dry sites compared to wet-cold sites (R2=0.687, p-value = 0.131, slope = 7.86 %). This suggests that belowground activity (microbes and roots) is stabilizing ecosystem processes and functions in terms of C storage. However, when the drought treatment permanently altered the soil structure at our hydric site, indicating we had exceeded the resilience of the system, the ecosystem C gain was no longer predictable from current (linear) relationships. Results from the warming treatment were generally of lower magnitude and of opposing direction compared to the drought treatment, indicating different mechanisms were driving ecosystem responses. Overall, our results suggest that aNPP is less sensitive than Rs to climate stresses and soil respiration C fluxes are not predictable from changes in plant productivity. Drought and warming effects on aNPP and Rs did not weaken over decadal timescales at larger, continental scales if no catastrophic threshold is passed. However, indirect effects of climate change on soil properties and/or microbial communities need to be further explored

AB - Understanding the relationship between above- and belowground processes is crucial if we are to forecast feedbacks between terrestrial carbon (C) dynamics and future climate. To test if climate-induced changes in annual aboveground net primary productivity (aNPP) will drive changes in C loss by soil respiration (Rs), we integrated data across a European temperature and precipitation gradient. For over a decade, six European shrublands were exposed to repeated drought (-30 % annual rain) during the plants' growth season or year-round night-time warming (+1.5 oC), using an identical experimental approach. As a result, drought reduced ecosystem C gain via aNPP by 0-25 % (compared to an untreated control) with the lowest C gain in warm-dry sites and highest in wet-cold sites (R2=0.078, p-value = 0.544, slope = 14.35 %). In contrast, drought induced C loss via Rs was of a lower magnitude (10-20 %) and was most pronounced in warm-dry sites compared to wet-cold sites (R2=0.687, p-value = 0.131, slope = 7.86 %). This suggests that belowground activity (microbes and roots) is stabilizing ecosystem processes and functions in terms of C storage. However, when the drought treatment permanently altered the soil structure at our hydric site, indicating we had exceeded the resilience of the system, the ecosystem C gain was no longer predictable from current (linear) relationships. Results from the warming treatment were generally of lower magnitude and of opposing direction compared to the drought treatment, indicating different mechanisms were driving ecosystem responses. Overall, our results suggest that aNPP is less sensitive than Rs to climate stresses and soil respiration C fluxes are not predictable from changes in plant productivity. Drought and warming effects on aNPP and Rs did not weaken over decadal timescales at larger, continental scales if no catastrophic threshold is passed. However, indirect effects of climate change on soil properties and/or microbial communities need to be further explored

M3 - Conference abstract in journal

VL - 18

JO - Geophysical Research Abstracts

JF - Geophysical Research Abstracts

SN - 1607-7962

T2 - EGU General Assembly 2016

Y2 - 18 April 2016 through 24 April 2016

ER -

ID: 289237581