Alaskan carbon-climate feedbacks will be weaker than inferred from short-term experiments

Bouskill, N.; Riley, William J.; Zhu, Qing; Mekonnen, Z. A.; Grant, R. F.

doi:10.1038/s41467-020-19574-3

Cited by 24 publications

(22 citation statements)

References 77 publications

(183 reference statements)

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“…In contrast, soil P stocks summarize the net effect of plant inputs and microbial activity. Our lack of response with P stocks is consistent with no response after 2 and 10 yr of warming in alpine meadow or 5 yr in Swedish heath tundra (Jonasson et al 1999, Wang et al 2014) and indicate that warming has no longterm net effect on belowground P. This is consistent with growing global evidence that long-term warming does not alter C stocks in ways that are predicted from short-term warming manipulations (van Gestel et al 2018, Bouskill et al 2020, Jian et al 2020. Therefore, we suggest that inconsistencies between tundra systems in response to warming encompass both seasonal variation, ecosystem specificity, and differences in duration of warming.…”

Section: Belowground Effectssupporting

confidence: 86%

Enhanced plant leaf P and unchanged soil P stocks after a quarter century of warming in the arctic tundra

McLaren

Buckeridge

2021

Ecosphere

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Phosphorus (P) limits or co-limits plant and microbial life in multiple ecosystems, including the arctic tundra. Although current global carbon (C) models focus on the coupling between soil nitrogen (N) and C, ecosystem P response to climate warming may also influence the global C cycle. Permafrost soils may see enhanced or reduced P availability under climate warming through multiple mechanisms including changing litter inputs through plant community change, changing plant-microbial dynamics, altered rates of mineralization of soil organic P through increased microbial activity, and newly exposed mineral-bound P via deeper thaw. We investigated the effect of long-term warming on plant leaf, multiple soil and microbial C, N, and P pools, and microbial extracellular enzyme activities, in Alaskan tundra plots underlain by permafrost. Here, we show that 25 yr of experimental summer warming increases community-level plant leaf P through changing community composition to favour relatively P-rich plant species. However, despite associated increases in P-rich litter inputs, we found only a few responses in the belowground pools of P available for plant and microbial uptake, including a weak positive response for citric acid-extractable PO 4 in the surface soil, a decrease in microbial biomass P, and no change in soil P (or C or N) stocks. This weak, neutral, or negative belowground P response to warming despite enhanced litter P inputs is consistent with a growing number of studies in the arctic tundra that find no long-term response of soil C and N stocks to warming.

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Section: Belowground Effectssupporting

confidence: 86%

Enhanced plant leaf P and unchanged soil P stocks after a quarter century of warming in the arctic tundra

McLaren

Buckeridge

2021

Ecosphere

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“…These results, and previously described evaluations of the model against diurnal, seasonal, and inter-annual variability of high-latitude ecosystems with 39 and without fire [43][44][45][46] , and the review of previous comparisons provided above, demonstrate that ecosys provides a reasonable representation of tundra ecosystems, and can be extended to our 21 st century model experiments.…”

Section: Figuresupporting

confidence: 74%

“…were tested using an analysis of variance test. Finally, we used an information theory approach (transfer entropy; 43 ) to examine directional impacts from one variable (e.g., soil nutrient cycling) to another (e.g., net primary productivity). These relationships were inferred by Shannon information entropy (H) and its transfer (TE) (unit bits), as previously described 103 .…”

Section: Discussionmentioning

confidence: 99%

“…However, while there exists observational evidence 33,34,60 and model simulations 43 for the expansion of shrubs across tundra ecosystems, the majority of these studies attribute the expansion to deciduous shrubs, such as dwarf shrubs or willow 34 . At the northern Anaktuvuk River site, evergreen shrubs were observed and modeled to be significant contributors to ecosystem biomass and NPP at the beginning of the 21 st century 17 , and modeled to increase over time.…”

Section: Long-term Climate Responsesmentioning

confidence: 99%

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Microbial contribution to post-fire tundra ecosystem recovery over the 21st century

Bouskill¹,

Mekonnen²,

Zhu³

et al. 2021

Preprint

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Tundra ecosystems have experienced an increased frequency of fire in recent decades, and this trend is predicted to continue throughout the 21st Century. Post-fire recovery is underpinned by complex interactions among microbial functional groups that drive nutrient cycling post-fire. Here we use a mechanistic model to demonstrate an acceleration of the nitrogen cycle post-fire driven by changes in niche space and microbial competitive dynamics. We show that over the first 5-years post-fire, fast-growing bacterial heterotrophs colonize regions of the soil previously occupied by slower-growing saprotrophic fungi. The bacterial heterotrophs mineralize organic matter, releasing organic and inorganic nutrients into the soil. This pathway outweighs new sources of nitrogen and facilitates the recovery of plant productivity. We broadly show here that while consideration of distinct microbial metabolisms related to carbon and nutrient cycling remains rare in terrestrial ecosystem models, they are important when considering the rate of ecosystem recovery post-disturbance and the feedback to soil nutrient cycles on centennial timescales.

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“…Thus, our study shows the importance of including plant community transition, in addition to within-community growth patterns, when quantifying changes in NPP, biomass, and soil C resulting from climate change. It will be important for models of ecosystem response to include such shifts in plant community composition in order to accurately predict warming-induced changes to C cycling (Bouskill et al, 2020). It should also be noted that the lack of significant differences in aboveground biomass and photosynthetic tissue was partly due to high heterogeneity in plant growth patterns at our site, particularly in the density and composition of aboveground biomass.…”

Section: Plant C Uptake and Input To Soilmentioning

confidence: 97%

Coupling plant litter quantity to a novel metric for litter quality explains C storage changes in a thawing permafrost peatland

Hough

McCabe

Vining

et al. 2021

Global Change Biology

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Alaskan carbon-climate feedbacks will be weaker than inferred from short-term experiments

Cited by 24 publications

References 77 publications

Enhanced plant leaf P and unchanged soil P stocks after a quarter century of warming in the arctic tundra

Enhanced plant leaf P and unchanged soil P stocks after a quarter century of warming in the arctic tundra

Microbial contribution to post-fire tundra ecosystem recovery over the 21st century

Coupling plant litter quantity to a novel metric for litter quality explains C storage changes in a thawing permafrost peatland

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