CMIP5 Models Predict Rapid and Deep Soil Warming Over the 21st Century

Soong, Jennifer L.; Phillips, Claire L.; Ledna, Catherine; Koven, C.; Torn, M. S.

doi:10.1029/2019jg005266

Cited by 76 publications

(45 citation statements)

References 68 publications

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“…However, the net benefits of mitigation at higher atmospheric CO 2 become smaller if relative humidity decreases (a trend being already observed in Spain in Moratiel et al, 2010). Additionally, there is a general trend towards warmer and dryer soils that can further reduce water availability and increase drought stress for biocrusts (Soong et al, 2020). Field studies on this subject are still very rare, but a study conducted in the Mojave desert suggests that higher atmospheric CO 2 cannot mitigate the negative effects of drought on biocrust cover (Wertin et al, 2012).…”

Section: Relative Humidity Drives Climate Change Responses Of D Dimentioning

confidence: 94%

Relative humidity predominantly determines long‐term biocrust‐forming lichen cover in drylands under climate change

et al. 2020

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1. Manipulative experiments typically show a decrease in dryland biocrust cover and altered species composition under climate change. Biocrust-forming lichens, such as the globally distributed Diploschistes diacapsis, are particularly affected and show a decrease in cover with simulated climate change. However, the underlying mechanisms are not fully understood, and long-term interacting effects of different drivers are largely unknown due to the short-term nature of the experimental studies conducted so far. 2. We addressed this gap and successfully parameterised a process-based model for D. diacapsis to quantify how changing atmospheric CO 2 , temperature, rainfall amount and relative humidity affect its photosynthetic activity and cover. We also mimicked a long-term manipulative climate change experiment to understand the mechanisms underlying observed patterns in the field. 3. The model reproduced observed experimental findings: warming reduced lichen cover, whereas less rainfall had no effect on lichen performance. This warming effect was caused by the associated decrease in relative humidity and nonrainfall water inputs, which are major water sources for biocrust-forming lichens. Warming alone, however, increased cover because higher temperatures promoted photosynthesis during early morning hours with high lichen activity. When combined, climate variables showed non-additive effects on lichen cover, and effects of increased CO 2 levelled off with decreasing levels of relative humidity. 4. Synthesis. Our results show that a decrease in relative humidity, rather than an increase in temperature, may be the key factor for the survival of the lichen D. diacapsis under climate change and that effects of increased CO 2 levels might be offset by a reduction in non-rainfall water inputs in the future. Because of a global trend towards warmer and drier air and the widespread global distribution of D. diacapsis, this will affect lichen-dominated dryland biocrust communities and their role in regulating ecosystem functions worldwide. This is an open access article under the terms of the Creat ive Commo ns Attri butio n-NonCo mmercial License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited and is not used for commercial purposes.

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Section: Relative Humidity Drives Climate Change Responses Of D Dimentioning

confidence: 94%

Relative humidity predominantly determines long‐term biocrust‐forming lichen cover in drylands under climate change

et al. 2020

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“…Each sample was analyzed twice, and the average results for each sample were recorded. Analytical precision was 0.2‰ for 13 C.…”

Section: Whole-ecosystem Warming and Elevated Atmospheric [Co 2 ]mentioning

confidence: 99%

“…1a). Capturing comprehensive peatland responses to climate change requires the use of active surface and deep-soil warming because deep-soil temperatures will naturally increase in concert with rising annual air temperatures [13][14][15] . Based on current greenhouse gas emission rates 16 , forcing estimates in line or greater than the RCP 8.5 scenario are likely to occur.…”

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confidence: 99%

Massive peatland carbon banks vulnerable to rising temperatures

et al. 2020

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Peatlands contain one-third of the world's soil carbon (C). If destabilized, decomposition of this vast C bank could accelerate climate warming; however, the likelihood of this outcome remains unknown. Here, we examine peatland C stability through five years of wholeecosystem warming and two years of elevated atmospheric carbon dioxide concentrations (eCO 2). Warming exponentially increased methane (CH 4) emissions and enhanced CH 4 production rates throughout the entire soil profile; although surface CH 4 production rates remain much greater than those at depth. Additionally, older deeper C sources played a larger role in decomposition following prolonged warming. Most troubling, decreases in CO 2 :CH 4 ratios in gas production, porewater concentrations, and emissions, indicate that the peatland is becoming more methanogenic with warming. We observed limited evidence of eCO 2 effects. Our results suggest that ecosystem responses are largely driven by surface peat, but that the vast C bank at depth in peatlands is responsive to prolonged warming.

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“…Nevertheless, Soong et al (2020) showed the models do agree on the speed with which the warming signal is propagated through the most biologically active soil layers. Answering the question of whether shallow soils (1–5 cm depth) will warm faster than deep soils (100 cm depth), they showed no difference in warming rate predicted by the models.…”

Section: How Much Will Soil Warm?mentioning

confidence: 99%

How Much Will Soil Warm?

Phillips

2020

JGR Biogeosciences

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For years, carbon cycle scientists have sought to understand how a warming climate will impact the decay of soil carbon. However, there have been relatively few investigations of how soils will warm in comparison to the atmosphere. Three recent papers in American Geophysical Union journals have looked at expected soil warming by synthesizing predictions in the Climate Model Intercomparison Project 5 (CMIP5). Collectively, these papers show that soil warming will keep pace with air warming except where snow and ice occur, and that the magnitude of soil warming in northern latitudes is uncertain due to model variability in snow and ice extent. They also show that a considerable portion of anthropogenic warming is being stored in deep soils, and that in comparison to observations, soil heat storage is underrepresented by land models. These studies highlight how important continued investigations of soil climatology are to understanding carbon cycling and Earth energy balance.

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CMIP5 Models Predict Rapid and Deep Soil Warming Over the 21st Century

Cited by 76 publications

References 68 publications

Relative humidity predominantly determines long‐term biocrust‐forming lichen cover in drylands under climate change

Relative humidity predominantly determines long‐term biocrust‐forming lichen cover in drylands under climate change

Massive peatland carbon banks vulnerable to rising temperatures

How Much Will Soil Warm?

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