Abstract
Soil organic matter (SOM) is the largest terrestrial pool of organic carbon, and potential carbon-climate feedbacks involving SOM decomposition could exacerbate anthropogenic climate change. However, our understanding of the controls on SOM mineralization is still incomplete, and as such, our ability to predict carbon-climate feedbacks is limited. To improve our understanding of controls on SOM decomposition, A and upper B horizon soil samples from 26 National Ecological Observatory Network (NEON) sites spanning the conterminous U.S. were incubated for 52 weeks under conditions representing site-specific mean summer temperature and sample-specific field capacity (−33 kPa) water potential. Cumulative carbon dioxide respired was periodically measured and normalized by soil organic C content to calculate cumulative specific respiration (CSR), a metric of SOM vulnerability to mineralization. The Boruta algorithm, a feature selection algorithm, was used to select important predictors of CSR from 159 variables. A diverse suite of predictors was selected (12 for A horizons, 7 for B horizons) with predictors falling into three categories corresponding to SOM chemistry, reactive Fe and Al phases, and site moisture availability. The relationship between SOM chemistry predictors and CSR was complex, while sites that had greater concentrations of reactive Fe and Al phases or were wetter had lower CSR. Only three predictors were selected for both horizon types, suggesting dominant controls on SOM decomposition differ by horizon. Our findings contribute to the emerging consensus that a broad array of controls regulates SOM decomposition at large scales and highlight the need to consider changing controls with depth.
Highlights
Soils contain the largest actively cycled pool of terrestrial organic carbon (C) in the form of soil organic matter (SOM)
The analyses described in following sections were conducted on air-dried, sieved bulk samples from the composited horizons, and a subset of these analyses were conducted on density fractions
Using data from a 52-week laboratory incubation of soils from National Ecological Observatory Network (NEON) sites spanning the conterminous United States, this study provides evidence for the dominant role of three categories of controls on SOM vulnerability at a continental scale: SOM chemistry, reactive Fe and Al phases, and site moisture availability
Summary
Soils contain the largest actively cycled pool of terrestrial organic carbon (C) in the form of soil organic matter (SOM). Despite the size of this C reservoir and its potential to contribute to an amplifying carbon-climate feedback, we still lack a thorough understanding of how SOM will respond to global change drivers (Bradford et al 2016). This knowledge gap limits society’s ability to accurately predict the effectiveness of climate change mitigation strategies. The paradigm that has emerged over the past decade places less emphasis on the chemical properties of SOM in mineral soils.
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