Lena Müller scite author profile

Photosynthesis and soil respiration represent the two largest fluxes of CO2 in terrestrial ecosystems and are tightly linked through belowground carbon (C) allocation. Drought has been suggested to impact the allocation of recently assimilated C to soil respiration; however, it is largely unknown how drought effects are altered by a future warmer climate under elevated atmospheric CO2 (eT_eCO2). In a multifactor experiment on managed C3 grassland, we studied the individual and interactive effects of drought and eT_eCO2 (drought, eT_eCO2, drought × eT_eCO2) on ecosystem C dynamics. We performed two in situ 13CO2 pulse‐labeling campaigns to trace the fate of recent C during peak drought and recovery. eT_eCO2 increased soil respiration and the fraction of recently assimilated C in soil respiration. During drought, plant C uptake was reduced by c. 50% in both ambient and eT_eCO2 conditions. Soil respiration and the amount and proportion of 13C respired from soil were reduced (by 32%, 70% and 30%, respectively), the effect being more pronounced under eT_eCO2 (50%, 84%, 70%). Under drought, the diel coupling of photosynthesis and SR persisted only in the eT_eCO2 scenario, likely caused by dynamic shifts in the use of freshly assimilated C between storage and respiration. Drought did not affect the fraction of recent C remaining in plant biomass under ambient and eT_eCO2, but reduced the small fraction remaining in soil under eT_eCO2. After rewetting, C uptake and the proportion of recent C in soil respiration recovered more rapidly under eT_eCO2 compared to ambient conditions. Overall, our findings suggest that in a warmer climate under elevated CO2 drought effects on the fate of recent C will be amplified and the coupling of photosynthesis and soil respiration will be sustained. To predict the future dynamics of terrestrial C cycling, such interactive effects of multiple global change factors should be considered.

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Individual and interactive effects of warming and nitrogen supply on CO₂ fluxes and carbon allocation in subarctic grassland

Meeran

Verbrigghe

Ingrisch

et al. 2023

Global Change Biology

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Climate warming has been suggested to impact high latitude grasslands severely, potentially causing considerable carbon (C) losses from soil. Warming can also stimulate nitrogen (N) turnover, but it is largely unclear whether and how altered N availability impacts belowground C dynamics. Even less is known about the individual and interactive effects of warming and N availability on the fate of recently photosynthesized C in soil. On a 10‐year geothermal warming gradient in Iceland, we studied the effects of soil warming and N addition on CO2 fluxes and the fate of recently photosynthesized C through CO2 flux measurements and a 13CO2 pulse‐labeling experiment. Under warming, ecosystem respiration exceeded maximum gross primary productivity, causing increased net CO2 emissions. N addition treatments revealed that, surprisingly, the plants in the warmed soil were N limited, which constrained primary productivity and decreased recently assimilated C in shoots and roots. In soil, microbes were increasingly C limited under warming and increased microbial uptake of recent C. Soil respiration was increased by warming and was fueled by increased belowground inputs and turnover of recently photosynthesized C. Our findings suggest that a decade of warming seemed to have induced a N limitation in plants and a C limitation by soil microbes. This caused a decrease in net ecosystem CO2 uptake and accelerated the respiratory release of photosynthesized C, which decreased the C sequestration potential of the grassland. Our study highlights the importance of belowground C allocation and C‐N interactions in the C dynamics of subarctic ecosystems in a warmer world.

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Effect of soil warming and N availability on the fate of recent carbon in subarctic grassland

Meeran¹,

Verbrigghe²,

Fuchslueger³

et al. 2020

Preprint

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Climate warming has been suggested to impact high latitude grasslands severely, causing considerable carbon (C) losses from soil. Warming can also stimulate nitrogen (N) turnover, but it is largely unclear whether and how altered N availability impacts soil C dynamics. Even less is known about the individual and interactive effects of warming and N availability on the fate of recently photosynthesized C in soil. &#160;We hypothesized that warming would increase belowground C allocation, while enhanced N availability would decrease it, and that their interactive effects would be additive.We studied a subarctic grassland located at a natural geothermal soil warming gradient close to Hverager&#240;i, Iceland, which was established by an earthquake in 2008. We chose 14 plots along the gradient with soil warming temperatures ranging from 0 to 10&#176;C above ambient, and fertilized a subset of plots with 50kg ha-1 y-1 of NH4NO3 twice a year prior to the study. We performed 13CO2 canopy pulse labeling for an hour and tracked the 13C pulse through the plant-microbe-soil system and into soil respiration for ten days after labeling.Our preliminary results show that at higher temperatures microbial activity increased, causing higher C turnover and a higher respiration of recently assimilated C from the soil. Warming significantly decreased microbial biomass, however, the recent C allocated from roots to microbes increased. This indicates a higher microbial C-limitation and a tighter root-microbe coupling under warming. Nitrogen addition increased the allocation of recent C to roots, microbial biomass, and soil respiration. The effects of N addition and warming were additive with no interaction. Our results indicate that the microbes in warmed soil may not be N limited, but could be C limited and depend more on the supply of recent C from plants. We conclude that in a future climate with warmer soils, more C may be allocated belowground, however, its residence time may decrease.

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Managing the Nordic Mountain Birch Ecosystem: Local Communities and the State in Finland’s Forestry

Müller

Aikio

Luhta³

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Lena Müller

Drought legacies and ecosystem responses to subsequent drought

Warming and elevated CO₂ intensify drought and recovery responses of grassland carbon allocation to soil respiration

Individual and interactive effects of warming and nitrogen supply on CO₂ fluxes and carbon allocation in subarctic grassland

Effect of soil warming and N availability on the fate of recent carbon in subarctic grassland

Managing the Nordic Mountain Birch Ecosystem: Local Communities and the State in Finland’s Forestry

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Lena Müller

Drought legacies and ecosystem responses to subsequent drought

Warming and elevated CO2 intensify drought and recovery responses of grassland carbon allocation to soil respiration

Individual and interactive effects of warming and nitrogen supply on CO2 fluxes and carbon allocation in subarctic grassland

Effect of soil warming and N availability on the fate of recent carbon in subarctic grassland

Managing the Nordic Mountain Birch Ecosystem: Local Communities and the State in Finland’s Forestry

Contact Info

Product

Resources

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Warming and elevated CO₂ intensify drought and recovery responses of grassland carbon allocation to soil respiration

Individual and interactive effects of warming and nitrogen supply on CO₂ fluxes and carbon allocation in subarctic grassland