Soil organic matter turnover is governed by accessibility not recalcitrance

Dungait, Jennifer A. J.; Hopkins, D. W.; Gregory, Andrew S.; Whitmore, A. P.

doi:10.1111/j.1365-2486.2012.02665.x

Cited by 1,241 publications

(737 citation statements)

References 201 publications

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“…The importance of physical protection to the stabilization of soil organic matter (SOM) has been understood for decades (Sollins et al, 1996;Krull et al, 2003;Dungait et al, 2012), as has the importance of plant litter chemistry upon the extent of its decay (Melillo et al, 1982;Taylor et al, 1989). However, the role microbial community structure and function plays in soil and litter turnover, and its response to elevated temperatures and N availability, is less understood.…”

Section: Introductionmentioning

confidence: 99%

Microbial community structure mediates response of soil C decomposition to litter addition and warming

Creamer

Menezes

Krull

et al. 2015

Soil Biology and Biochemistry

188

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Section: Introductionmentioning

confidence: 99%

Microbial community structure mediates response of soil C decomposition to litter addition and warming

Creamer

Menezes

Krull

et al. 2015

Soil Biology and Biochemistry

188

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“…This estimate of 38-109 kg N 2 O ha −1 year −1 is far greater than current estimates of emissions under both arable (0.9-11.0 kg N 2 O ha −1 year −1 ) and grassland agriculture (1.6-22.0 kg N 2 O ha −1 year −1 ) in the UK [59]. Sequestration in the subsoil may be especially important as such SOC may become protected against further processing [60].…”

Section: Soc and Tn Under Bioenergy Cropsmentioning

confidence: 85%

Species and Genotype Effects of Bioenergy Crops on Root Production, Carbon and Nitrogen in Temperate Agricultural Soil

et al. 2018

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Bioenergy crops have a secondary benefit if they increase soil organic C (SOC) stocks through capture and allocation belowground. The effects of four genotypes of short-rotation coppice willow (Salix spp., 'Terra Nova' and 'Tora') and Miscanthus (M. × giganteus ('Giganteus') and M. sinensis ('Sinensis')) on roots, SOC and total nitrogen (TN) were quantified to test whether below-ground biomass controls SOC and TN dynamics. Soil cores were collected under ('plant') and between plants ('gap') in a field experiment on a temperate agricultural silty clay loam after 4 and 6 years' management. Root density was greater under Miscanthus for plant (up to 15.5 kg m −3 ) compared with gap (up to 2.7 kg m −3 ), whereas willow had lower densities (up to 3.7 kg m −3 ). Over 2 years, SOC increased below 0.2 m depth from 7.1 to 8.5 kg m −3 and was greatest under Sinensis at 0-0.1 m depth (24.8 kg m −3 ). Miscanthus-derived SOC, based on stable isotope analysis, was greater under plant (11.6 kg m −3 ) than gap (3.1 kg m −3 ) for Sinensis. Estimated SOC stock change rates over the 2-year period to 1-m depth were 6.4 for Terra Nova, 7.4 for Tora, 3.1 for Giganteus and 8.8 Mg ha −1 year −1 for Sinensis. Rates of change of TN were much less. That SOC matched root mass down the profile, particularly under Miscanthus, indicated that perennial root systems are an important contributor. Willow and Miscanthus offer both biomass production and C sequestration when planted in arable soil.

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“…Several soil management practices such as tillage or organic fertilizer application are known to stimulate the microbial decomposition of SOM (Luo et al 2010;McLauchlan 2006;Pisani et al 2016). Beyond their role as decomposers, microorganisms are a ubiquitous source of OM to soils through recycling of plant and animal-derived OM and synthesis of new products (Dungait et al 2012;Gleixner 2013;Miltner et al 2012). Consequently, SOM decomposition leads to an enrichment in microbial compounds in residual SOM at the expense of plant-derived compounds (Hobara et al 2014;Kaiser and Kalbitz 2012;Malik and Gleixner 2013).…”

Section: Introductionmentioning

confidence: 99%

Effects of human land use on the terrestrial and aquatic sources of fluvial organic matter in a temperate river basin (The Meuse River, Belgium)

et al. 2017

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The impact of human activities on the concentrations and composition of dissolved organic matter (DOM) and particulate organic matter (POM) was investigated in the Walloon Region of the Meuse River basin (Belgium). Water samples were collected at different hydrological periods along a gradient of human disturbance (50 sampling sites ranging from 8.0 to 20,407 km 2 ) and during a 1.5 year monitoring of the Meuse River at the city of Liège. This dataset was completed by the characterization of the DOM pool in groundwaters. The composition of DOM and POM was investigated through elemental (C:N ratios), isotopic (d 13 C) and optical measurements including excitation emission matrix fluorescence with parallel factor analysis (EEM-PARAFAC). Land use was a major driver on fluvial OM composition at the regional scale of the Meuse Basin, the composition of both fluvial DOM and POM pools showing a shift toward a more microbial/algal and less plant/soil-derived character as human disturbance increased. The comparison of DOM composition between surface and groundwaters demonstrated that this pattern can be attributed in part to the transformation of terrestrial sources by agricultural practices that promote the decomposition of soil organic matter in agricultural lands and subsequent microbial inputs in terrestrial sources. In parallel, human land had contrasting effects on the autochthonous production of DOM and POM. While the in-stream generation of fresh DOM through biological activity was promoted in urban areas, summer autochthonous POM production was not influenced by land use. Finally, soil erosion by agricultural management practices favored the transfer of terrestrial organic matter via the particulate phase. Stable isotope data suggest that the hydrological transfer of terrestrial DOM and POM in humanimpacted catchment are not subject to the same controls, and that physical exchange between these two pools of organic matter is limited.

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Soil organic matter turnover is governed by accessibility not recalcitrance

Cited by 1,241 publications

References 201 publications

Microbial community structure mediates response of soil C decomposition to litter addition and warming

Microbial community structure mediates response of soil C decomposition to litter addition and warming

Species and Genotype Effects of Bioenergy Crops on Root Production, Carbon and Nitrogen in Temperate Agricultural Soil

Effects of human land use on the terrestrial and aquatic sources of fluvial organic matter in a temperate river basin (The Meuse River, Belgium)

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