Soil fauna: key to new carbon models

Filser, Juliane; Faber, J.H.; Tiunov, Alexei V.; Brussaard, L.; Frouz, Jan; Deyn, Gerlinde B. De; Uvarov, Alexei V.; Berg, M.P.; Lavelle, Patrick; Loreau, Michel; Wall, Diana H.; Querner, Pascal; Eijsackers, H.J.P.; Jiménez, Juan J.

doi:10.5194/soil-2-565-2016

Cited by 162 publications

(103 citation statements)

References 124 publications

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“…The ambition here is to show how PTFs can be improved to better parameterize soil processes by better quantifying rate parameters in biogeochemical processes related to soil carbon (e.g., Q10 and first‐order rate constants), nitrogen (e.g., mineralization constants), and biotic and biodiversity‐related processes. The latter has been largely neglected as there is a rising awareness of the different soil biotic processes and their role in the C, N, and general nutrient cycling in terrestrial ecosystems (Filser, et al, ).…”

Section: Challenges For Ptfs In Earth System Sciencementioning

confidence: 99%

Pedotransfer Functions in Earth System Science: Challenges and Perspectives

Looy

Bouma

Herbst

et al. 2017

Reviews of Geophysics

357

267

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Soil, through its various functions, plays a vital role in the Earth's ecosystems and provides multiple ecosystem services to humanity. Pedotransfer functions (PTFs) are simple to complex knowledge rules that relate available soil information to soil properties and variables that are needed to parameterize soil processes. In this paper, we review the existing PTFs and document the new generation of PTFs developed in the different disciplines of Earth system science. To meet the methodological challenges for a successful application in Earth system modeling, we emphasize that PTF development has to go hand in hand with suitable extrapolation and upscaling techniques such that the PTFs correctly represent the spatial heterogeneity of soils. PTFs should encompass the variability of the estimated soil property or process, in such a way that the estimation of parameters allows for validation and can also confidently provide for extrapolation and upscaling purposes capturing the spatial variation in soils. Most actively pursued recent developments are related to parameterizations of solute transport, heat exchange, soil respiration, and organic carbon content, root density, and vegetation water uptake. Further challenges are to be addressed in parameterization of soil erosivity and land use change impacts at multiple scales. We argue that a comprehensive set of PTFs can be applied throughout a wide range of disciplines of Earth system science, with emphasis on land surface models. Novel sensing techniques provide a true breakthrough for this, yet further improvements are necessary for methods to deal with uncertainty and to validate applications at global scale.

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Section: Challenges For Ptfs In Earth System Sciencementioning

confidence: 99%

Pedotransfer Functions in Earth System Science: Challenges and Perspectives

Looy

Bouma

Herbst

et al. 2017

Reviews of Geophysics

357

267

View full text Add to dashboard Cite

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“…The goal of these models is to predict the dependent variable (e.g., decomposition; Parton, Schimel, Cole, & Ojima, ). Explicit trait‐based models, such as those developed for the simulation of microbial communities (e.g., Allison, ) and faunal communities (Filser et al., ), require extensive knowledge of the intra‐ and interspecific trait variation along environmental gradients and their effects on ecosystem pools and fluxes. Two major advantages of this approach are: (a) the explicit parameterization of traits allows for measured values as direct model input and (b) complex interactions between organisms are allowed and may lead to emergent properties, such as top‐down or bottom‐up regulation of food web structure.…”

Section: Incorporating a Trait‐based Approach Into Biogeochemical Modelsmentioning

confidence: 99%

“…Increasingly, more nuanced models are possible due to better understanding of the role of faunal groups and availability of more comprehensive data on traits of these groups at different spatial and temporal scales. Evidence from soil food web models indicates that inclusion of plant, microbial, and soil faunal traits and their interactions is imperative to improve the predictive power of biogeochemical models (Allison, ; Faucon et al., ; Filser et al., ; Funk et al., ; Wieder, Bonan, & Allison, ). To move forward, we propose that gaps in knowledge of measuring and understanding functional traits must be addressed and general principles must be identified.…”

Section: Introductionmentioning

confidence: 99%

Using plant, microbe, and soil fauna traits to improve the predictive power of biogeochemical models

et al. 2018

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Process‐based models describing biogeochemical cycling are crucial tools to understanding long‐term nutrient dynamics, especially in the context of perturbations, such as climate and land‐use change. Such models must effectively synthesize ecological processes and properties. For example, in terrestrial ecosystems, plants are the primary source of bioavailable carbon, but turnover rates of essential nutrients are contingent on interactions between plants and soil biota. Yet, biogeochemical models have traditionally considered plant and soil communities in broad terms. The next generation of models must consider how shifts in their diversity and composition affect ecosystem processes. One promising approach to synthesize plant and soil biodiversity and their interactions into models is to consider their diversity from a functional trait perspective. Plant traits, which include heritable chemical, physical, morphological and phenological characteristics, are increasingly being used to predict ecosystem processes at a range of scales, and to interpret biodiversity–ecosystem functional relationships. There is also emerging evidence that the traits of soil microbial and faunal communities can be correlated with ecosystem functions such as decomposition, nutrient cycling, and greenhouse gas production. Here, we draw on recent advances in measuring and using traits of different biota to predict ecosystem processes, and provide a new perspective as to how biotic traits can be integrated into biogeochemical models. We first describe an explicit trait‐based model framework that operates at small scales and uses direct measurements of ecosystem properties; second, an integrated approach that operates at medium scales and includes interactions between biogeochemical cycling and soil food webs; and third, an implicit trait‐based model framework that associates soil microbial and faunal functional groups with plant functional groups, and operates at the Earth‐system level. In each of these models, we identify opportunities for inclusion of traits from all three groups to reduce model uncertainty and improve understanding of biogeochemical cycles. These model frameworks will generate improved predictive capacity of how changes in biodiversity regulate biogeochemical cycles in terrestrial ecosystems. Further, they will assist in developing a new generation of process‐based models that include plant, microbial, and faunal traits and facilitate dialogue between empirical researchers and modellers.

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“…Although logistically challenging, combining multiyear and multisite standardized field experimental approaches across climatically contrasting regions is crucial to draw conclusions that are realistic and apply across large regions (Kröel-Dulay et al, 2015). Springtails are a highly diverse and abundant group of soil fauna involved in many key ecosystem functions such as leaf litter decomposition and nutrient cycling (Bardgett & van der Putten, 2014;Filser et al, 2016;Handa et al, 2014). Notwithstanding, our current knowledge of whether and how their phylogenetic and functional diversity will be altered by climate change is still poor despite recent advances with some biodiversity metrics and in particular ecosystem types (Alatalo, Jägerbrand, & Čuchta, 2015;Blankinship, Niklaus, & Hungate, 2011;Holmstrup et al, 2013Holmstrup et al, , 2017Holmstrup et al, , 2018Kardol, Reynolds, Norby, & Classen, 2011;Lindberg, Bengtsson, & Persson, 2002;Makkonen et al, 2011;Petersen, 2011).…”

Section: Introductionmentioning

confidence: 99%

Fast attrition of springtail communities by experimental drought and richness–decomposition relationships across Europe

Peguero

Sol

Arnedo

et al. 2019

Global Change Biology

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Soil fauna play a fundamental role on key ecosystem functions like organic matter decomposition, although how local assemblages are responding to climate change and whether these changes may have consequences to ecosystem functioning is less clear. Previous studies have revealed that a continued environmental stress may result in poorer communities by filtering out the most sensitive species. However, these experiments have rarely been applied to climate change factors combining multiyear and multisite standardized field treatments across climatically contrasting regions, which has limited drawing general conclusions. Moreover, other facets of biodiversity, such as functional and phylogenetic diversity, potentially more closely linked to ecosystem functioning, have been largely neglected. Here, we report that the abundance, species richness, phylogenetic diversity, and functional richness of springtails (Subclass Collembola), a major group of fungivores and detritivores, decreased within 4 years of experimental drought across six European shrublands. The loss of phylogenetic and functional richness was higher than expected by the loss of species richness, leading to communities of phylogenetically similar species sharing evolutionary conserved traits. Additionally, despite the great climatic differences among study sites, we found that taxonomic, phylogenetic, and functional richness of springtail communities alone were able to explain up to 30% of the variation in annual decomposition rates. Altogether, our results suggest that the forecasted reductions in precipitation associated with climate change may erode springtail communities and likely other drought‐sensitive soil invertebrates, thereby retarding litter decomposition and nutrient cycling in ecosystems.

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Soil fauna: key to new carbon models

Cited by 162 publications

References 124 publications

Pedotransfer Functions in Earth System Science: Challenges and Perspectives

Pedotransfer Functions in Earth System Science: Challenges and Perspectives

Using plant, microbe, and soil fauna traits to improve the predictive power of biogeochemical models

Fast attrition of springtail communities by experimental drought and richness–decomposition relationships across Europe

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