Effects of elevated CO2 on fine root biomass are reduced by aridity but enhanced by soil nitrogen: A global assessment. Pineiro, J., Ochoa-Hueso, R., Delgado-Baquerizo, M., Dobrick, S., Reich, P. B., Pendall, E., & Power, S. A. Scientific Reports, 7:9, November, 2017.
Effects of elevated CO2 on fine root biomass are reduced by aridity but enhanced by soil nitrogen: A global assessment [link]Paper  doi  abstract   bibtex   
Plant roots play a crucial role in regulating key ecosystem processes such as carbon (C) sequestration and nutrient solubilisation. Elevated (e)CO2 is expected to alter the biomass of fine, coarse and total roots to meet increased demand for other resources such as water and nitrogen (N), however, the magnitude and direction of observed changes vary considerably between ecosystems. Here, we assessed how climate and soil properties mediate root responses to eCO(2) by comparing 24 field-based CO2 experiments across the globe including a wide range of ecosystem types. We calculated response ratios (i.e. effect size) and used structural equation modelling (SEM) to achieve a system-level understanding of how aridity, mean annual temperature and total soil nitrogen simultaneously drive the response of total, coarse and fine root biomass to eCO(2). Models indicated that increasing aridity limits the positive response of fine and total root biomass to eCO(2), and that fine (but not coarse or total) root responses to eCO(2) are positively related to soil total N. Our results provide evidence that consideration of factors such as aridity and soil N status is crucial for predicting plant and ecosystem-scale responses to future changes in atmospheric CO2 concentrations, and thus feedbacks to climate change.
@article{pineiro_effects_2017,
	title = {Effects of elevated {CO}2 on fine root biomass are reduced by aridity but enhanced by soil nitrogen: {A} global assessment},
	volume = {7},
	issn = {2045-2322},
	shorttitle = {Effects of elevated {CO}2 on fine root biomass are reduced by aridity but enhanced by soil nitrogen: {A} global assessment},
	url = {://WOS:000414917800095},
	doi = {10.1038/s41598-017-15728-4},
	abstract = {Plant roots play a crucial role in regulating key ecosystem processes such as carbon (C) sequestration and nutrient solubilisation. Elevated (e)CO2 is expected to alter the biomass of fine, coarse and total roots to meet increased demand for other resources such as water and nitrogen (N), however, the magnitude and direction of observed changes vary considerably between ecosystems. Here, we assessed how climate and soil properties mediate root responses to eCO(2) by comparing 24 field-based CO2 experiments across the globe including a wide range of ecosystem types. We calculated response ratios (i.e. effect size) and used structural equation modelling (SEM) to achieve a system-level understanding of how aridity, mean annual temperature and total soil nitrogen simultaneously drive the response of total, coarse and fine root biomass to eCO(2). Models indicated that increasing aridity limits the positive response of fine and total root biomass to eCO(2), and that fine (but not coarse or total) root responses to eCO(2) are positively related to soil total N. Our results provide evidence that consideration of factors such as aridity and soil N status is crucial for predicting plant and ecosystem-scale responses to future changes in atmospheric CO2 concentrations, and thus feedbacks to climate change.},
	language = {English},
	journal = {Scientific Reports},
	author = {Pineiro, J. and Ochoa-Hueso, R. and Delgado-Baquerizo, M. and Dobrick, S. and Reich, P. B. and Pendall, E. and Power, S. A.},
	month = nov,
	year = {2017},
	keywords = {Science \& Technology - Other Topics, atmospheric co2, carbon-dioxide enrichment, climate-change, grassland, metaanalysis, n fertilization, plant-growth, responses, warm-temperate forest, water relations},
	pages = {9}
}
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