Loss of deep roots limits biogenic agents of soil development that are only partially restored by decades of forest regeneration
Roots and associated microbes generate acid-forming CO2 and organic acids and accelerate mineral weathering deep within Earth’s critical zone (CZ). At the Calhoun CZ Observatory in the USA’s Southern Piedmont, we tested the hypothesis that deforestation-induced deep root losses reduce root- and micr...
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| Language: | English |
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BioOne
2018-04-01
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| Series: | Elementa: Science of the Anthropocene |
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| Online Access: | https://www.elementascience.org/articles/287 |
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doaj-c137a167d78e4bae84fd1dd532b76b4b2020-11-24T22:50:40ZengBioOneElementa: Science of the Anthropocene2325-10262018-04-016110.1525/elementa.287259Loss of deep roots limits biogenic agents of soil development that are only partially restored by decades of forest regenerationSharon A. Billings0Daniel Hirmas1Pamela L. Sullivan2Christoph A. Lehmeier3Samik Bagchi4Kyungjin Min5Zachary Brecheisen6Emma Hauser7Rena Stair8Rebecca Flournoy9Daniel deB. Richter10Department of Ecology and Evolutionary Biology and Kansas Biological Survey, University of Kansas, Lawrence, KansasDepartment of Geography and Atmospheric Sciences, University of Kansas, Lawrence, KansasDepartment of Geography and Atmospheric Sciences, University of Kansas, Lawrence, KansasDepartment of Ecology and Evolutionary Biology and Kansas Biological Survey, University of Kansas, Lawrence, KansasDepartment of Ecology and Evolutionary Biology and Kansas Biological Survey, University of Kansas, Lawrence, Kansas; Department of Civil, Environmental, and Architectural Engineering, University of Kansas, Lawrence, KansasDepartment of Ecology and Evolutionary Biology and Kansas Biological Survey, University of Kansas, Lawrence, KansasNicholas School of the Environment, Duke University, Durham, North CarolinaDepartment of Ecology and Evolutionary Biology and Kansas Biological Survey, University of Kansas, Lawrence, KansasDepartment of Ecology and Evolutionary Biology and Kansas Biological Survey, University of Kansas, Lawrence, KansasDepartment of Ecology and Evolutionary Biology and Kansas Biological Survey, University of Kansas, Lawrence, KansasNicholas School of the Environment, Duke University, Durham, North CarolinaRoots and associated microbes generate acid-forming CO2 and organic acids and accelerate mineral weathering deep within Earth’s critical zone (CZ). At the Calhoun CZ Observatory in the USA’s Southern Piedmont, we tested the hypothesis that deforestation-induced deep root losses reduce root- and microbially-mediated weathering agents well below maximum root density (to 5 m), and impart land-use legacies even after ~70 y of forest regeneration. In forested plots, root density declined with depth to 200 cm; in cultivated plots, roots approached zero at depths >70 cm. Below 70 cm, root densities in old-growth forests averaged 2.1 times those in regenerating forests. Modeled root distributions suggest declines in density with depth were steepest in agricultural plots, and least severe in old-growth forests. Root densities influenced biogeochemical environments in multiple ways. Microbial community composition varied with land use from surface horizons to 500 cm; relative abundance of root-associated bacteria was greater in old-growth soils than in regenerating forests, particularly at 100–150 cm. At 500 cm in old-growth forests, salt-extractable organic C (EOC), an organic acid proxy, was 8.8 and 12.5 times that in regenerating forest and agricultural soils, respectively. The proportion of soil organic carbon comprised of EOC was greater in old-growth forests (20.0 ± 2.6%) compared to regenerating forests (2.1 ± 1.1) and agricultural soils (1.9 ± 0.9%). Between 20 and 500 cm, [EOC] increased more with root density in old-growth relative to regenerating forests. At 300 cm, 'in situ' growing season [CO2] was significantly greater in old-growth forests relative to regenerating forests and cultivated plots; at 300 and 500 cm, cultivated soil [CO2] was significantly lower than in forests. Microbially-respired d13C-CO2 suggests that microbes may rely partially on crop residue even after ~70 y of forest regeneration. We assert that forest conversion to frequently disturbed ecosystems limits deep roots and reduces biotic generation of downward-propagating weathering agents.https://www.elementascience.org/articles/287Biotic weatheringcritical zone biogeochemistryland conversionsoil organic acidsin situ CO2forest succession |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Sharon A. Billings Daniel Hirmas Pamela L. Sullivan Christoph A. Lehmeier Samik Bagchi Kyungjin Min Zachary Brecheisen Emma Hauser Rena Stair Rebecca Flournoy Daniel deB. Richter |
| spellingShingle |
Sharon A. Billings Daniel Hirmas Pamela L. Sullivan Christoph A. Lehmeier Samik Bagchi Kyungjin Min Zachary Brecheisen Emma Hauser Rena Stair Rebecca Flournoy Daniel deB. Richter Loss of deep roots limits biogenic agents of soil development that are only partially restored by decades of forest regeneration Elementa: Science of the Anthropocene Biotic weathering critical zone biogeochemistry land conversion soil organic acids in situ CO2 forest succession |
| author_facet |
Sharon A. Billings Daniel Hirmas Pamela L. Sullivan Christoph A. Lehmeier Samik Bagchi Kyungjin Min Zachary Brecheisen Emma Hauser Rena Stair Rebecca Flournoy Daniel deB. Richter |
| author_sort |
Sharon A. Billings |
| title |
Loss of deep roots limits biogenic agents of soil development that are only partially restored by decades of forest regeneration |
| title_short |
Loss of deep roots limits biogenic agents of soil development that are only partially restored by decades of forest regeneration |
| title_full |
Loss of deep roots limits biogenic agents of soil development that are only partially restored by decades of forest regeneration |
| title_fullStr |
Loss of deep roots limits biogenic agents of soil development that are only partially restored by decades of forest regeneration |
| title_full_unstemmed |
Loss of deep roots limits biogenic agents of soil development that are only partially restored by decades of forest regeneration |
| title_sort |
loss of deep roots limits biogenic agents of soil development that are only partially restored by decades of forest regeneration |
| publisher |
BioOne |
| series |
Elementa: Science of the Anthropocene |
| issn |
2325-1026 |
| publishDate |
2018-04-01 |
| description |
Roots and associated microbes generate acid-forming CO2 and organic acids and accelerate mineral weathering deep within Earth’s critical zone (CZ). At the Calhoun CZ Observatory in the USA’s Southern Piedmont, we tested the hypothesis that deforestation-induced deep root losses reduce root- and microbially-mediated weathering agents well below maximum root density (to 5 m), and impart land-use legacies even after ~70 y of forest regeneration. In forested plots, root density declined with depth to 200 cm; in cultivated plots, roots approached zero at depths >70 cm. Below 70 cm, root densities in old-growth forests averaged 2.1 times those in regenerating forests. Modeled root distributions suggest declines in density with depth were steepest in agricultural plots, and least severe in old-growth forests. Root densities influenced biogeochemical environments in multiple ways. Microbial community composition varied with land use from surface horizons to 500 cm; relative abundance of root-associated bacteria was greater in old-growth soils than in regenerating forests, particularly at 100–150 cm. At 500 cm in old-growth forests, salt-extractable organic C (EOC), an organic acid proxy, was 8.8 and 12.5 times that in regenerating forest and agricultural soils, respectively. The proportion of soil organic carbon comprised of EOC was greater in old-growth forests (20.0 ± 2.6%) compared to regenerating forests (2.1 ± 1.1) and agricultural soils (1.9 ± 0.9%). Between 20 and 500 cm, [EOC] increased more with root density in old-growth relative to regenerating forests. At 300 cm, 'in situ' growing season [CO2] was significantly greater in old-growth forests relative to regenerating forests and cultivated plots; at 300 and 500 cm, cultivated soil [CO2] was significantly lower than in forests. Microbially-respired d13C-CO2 suggests that microbes may rely partially on crop residue even after ~70 y of forest regeneration. We assert that forest conversion to frequently disturbed ecosystems limits deep roots and reduces biotic generation of downward-propagating weathering agents. |
| topic |
Biotic weathering critical zone biogeochemistry land conversion soil organic acids in situ CO2 forest succession |
| url |
https://www.elementascience.org/articles/287 |
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