Using Stable Carbon Isotopes of Seasonal Ecosystem Respiration to Determine Permafrost Carbon Loss

M. Mauritz; G. Celis; C. Ebert; J. Hutchings; J. Ledman; S. M. Natali; E. Pegoraro; V. G. Salmon; C. Schädel; M. Taylor; E. A.G. Schuur

doi:10.1029/2018JG004619

Using Stable Carbon Isotopes of Seasonal Ecosystem Respiration to Determine Permafrost Carbon Loss

M. Mauritz, G. Celis, C. Ebert, J. Hutchings, J. Ledman, S. M. Natali, E. Pegoraro, V. G. Salmon, C. Schädel, M. Taylor, E. A.G. Schuur

Plant-Soil Interactions

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

High latitude warming and permafrost thaw will expose vast stores of deep soil organic carbon (SOC) to decomposition. Thaw also changes water movement causing either wetter or drier soil. The fate of deep SOC under different thaw and moisture conditions is unclear. We measured weekly growing-season δ ¹³ C of ecosystem respiration (Recoδ ¹³ C) across thaw and moisture conditions (Shallow-Dry; Deep-Dry; Deep-Wet) in a soil warming manipulation. Deep SOC loss was inferred from known δ ¹³ C signatures of plant shoot, root, surface soil, and deep soil respiration. In addition, a 2-year-old vegetation removal treatment (No Veg) was used to isolate surface and deep SOC decomposition contributions to Reco. In No Veg, seasonal Recoδ ¹³ C indicated that deep SOC loss increased as the soil column thawed, while in vegetated areas, root contributions appeared to dominate Reco. The Recoδ ¹³ C differences between Shallow-Dry and Deep-Dry were significant but surprisingly small. This most likely suggests that, under dry conditions, soil warming stimulates root and surface SOC respiration with a negative ¹³ C signature that opposes the more positive ¹³ C signal from increased deep SOC respiration. In Deep-Wet conditions, Recoδ ¹³ C suggests reduced deep SOC loss but could also reflect altered diffusion or methane (CH ₄ ) dynamics. Together, these results demonstrate that frequent Recoδ ¹³ C measurements can detect deep SOC loss and that plants confound the signal. In future studies, soil profile δ ¹³ C measurements, vegetation removal across thaw gradients, and isotopic effects of CH ₄ dynamics could further deconvolute deep SOC loss via surface Reco.

Original language	English
Pages (from-to)	46-60
Number of pages	15
Journal	Journal of Geophysical Research: Biogeosciences
Volume	124
Issue number	1
DOIs	https://doi.org/10.1029/2018JG004619
State	Published - Jan 2019

Funding

All data in this paper are archived at Bonanza Creek LTER Data Catalog under the EML research site. The link for Recoδ13C data is http://www.lter.uaf.edu/data/data-detail/id/700. We thank three anonymous reviewers whose constructive comments helped to improve this manuscript. The Bonanza Creek LTER crew tirelessly assists with snow removal every spring. Chris Greyson-Gaito and Stephanie Hall helped in all aspects of the field work, particularly navigating tussocks while carrying the analyzer across tundra and boardwalks. Thanks to Sylvia Englund Michel with NOAA's Global Monitoring Division for helping with δ13C data from the Barrow tower in Utqiagvik, AK, and to Xiaomei Xu at UCI for Barrow Δ14C published in Graven et al. () and Newman et al. (). This work was supported by funding from the U.S. Department of Energy, Office of Biological and Environmental Research, Terrestrial Ecosystem Science (TES) Program, award DE-SC0006982 updated with DE-SC0014085 (2015–2018); National Science Foundation CAREER program, award 0747195; National Parks Inventory and Monitoring Program; National Science Foundation Bonanza Creek LTER program, award 1026415; and National Science Foundation Office of Polar Programs, award 1203777. All data in this paper are archived at Bonanza Creek LTER Data Catalog under the EML research site. The link for Recoδ13C data is http://www.lter. uaf.edu/data/data-detail/id/700. We thank three anonymous reviewers whose constructive comments helped to improve this manuscript. The Bonanza Creek LTER crew tirelessly assists with snow removal every spring. Chris Greyson-Gaito and Stephanie Hall helped in all aspects of the field work, particularly navigating tussocks while carrying the analyzer across tundra and boardwalks. Thanks to Sylvia Englund Michel with NOAA’s Global Monitoring Division for helping with δ13C data from the Barrow tower in Utqiagvik, AK, and to Xiaomei Xu at UCI for Barrow Δ14C published in Graven et al. (2013) and Newman et al. (2016). This work was supported by funding from the U.S. Department of Energy, Office of Biological and Environmental Research, Terrestrial Ecosystem Science (TES) Program, award DE-SC0006982 updated with DE-SC0014085 (2015–2018); National Science Foundation CAREER program, award 0747195; National Parks Inventory and Monitoring Program; National Science Foundation Bonanza Creek LTER program, award 1026415; and National Science Foundation Office of Polar Programs, award 1203777.

Keywords

carbon
isotope partitioning
permafrost
respiration
thaw
warming

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@article{a8d566de0cb7430a8428c4f6dec8d86b,

title = "Using Stable Carbon Isotopes of Seasonal Ecosystem Respiration to Determine Permafrost Carbon Loss",

abstract = " High latitude warming and permafrost thaw will expose vast stores of deep soil organic carbon (SOC) to decomposition. Thaw also changes water movement causing either wetter or drier soil. The fate of deep SOC under different thaw and moisture conditions is unclear. We measured weekly growing-season δ 13 C of ecosystem respiration (Recoδ 13 C) across thaw and moisture conditions (Shallow-Dry; Deep-Dry; Deep-Wet) in a soil warming manipulation. Deep SOC loss was inferred from known δ 13 C signatures of plant shoot, root, surface soil, and deep soil respiration. In addition, a 2-year-old vegetation removal treatment (No Veg) was used to isolate surface and deep SOC decomposition contributions to Reco. In No Veg, seasonal Recoδ 13 C indicated that deep SOC loss increased as the soil column thawed, while in vegetated areas, root contributions appeared to dominate Reco. The Recoδ 13 C differences between Shallow-Dry and Deep-Dry were significant but surprisingly small. This most likely suggests that, under dry conditions, soil warming stimulates root and surface SOC respiration with a negative 13 C signature that opposes the more positive 13 C signal from increased deep SOC respiration. In Deep-Wet conditions, Recoδ 13 C suggests reduced deep SOC loss but could also reflect altered diffusion or methane (CH 4 ) dynamics. Together, these results demonstrate that frequent Recoδ 13 C measurements can detect deep SOC loss and that plants confound the signal. In future studies, soil profile δ 13 C measurements, vegetation removal across thaw gradients, and isotopic effects of CH 4 dynamics could further deconvolute deep SOC loss via surface Reco.",

keywords = "carbon, isotope partitioning, permafrost, respiration, thaw, warming",

author = "M. Mauritz and G. Celis and C. Ebert and J. Hutchings and J. Ledman and Natali, {S. M.} and E. Pegoraro and Salmon, {V. G.} and C. Sch{\"a}del and M. Taylor and Schuur, {E. A.G.}",

year = "2019",

month = jan,

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language = "English",

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AU - Mauritz, M.

AU - Celis, G.

AU - Ebert, C.

AU - Hutchings, J.

AU - Ledman, J.

AU - Natali, S. M.

AU - Pegoraro, E.

AU - Salmon, V. G.

AU - Schädel, C.

AU - Taylor, M.

AU - Schuur, E. A.G.

PY - 2019/1

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N2 - High latitude warming and permafrost thaw will expose vast stores of deep soil organic carbon (SOC) to decomposition. Thaw also changes water movement causing either wetter or drier soil. The fate of deep SOC under different thaw and moisture conditions is unclear. We measured weekly growing-season δ 13 C of ecosystem respiration (Recoδ 13 C) across thaw and moisture conditions (Shallow-Dry; Deep-Dry; Deep-Wet) in a soil warming manipulation. Deep SOC loss was inferred from known δ 13 C signatures of plant shoot, root, surface soil, and deep soil respiration. In addition, a 2-year-old vegetation removal treatment (No Veg) was used to isolate surface and deep SOC decomposition contributions to Reco. In No Veg, seasonal Recoδ 13 C indicated that deep SOC loss increased as the soil column thawed, while in vegetated areas, root contributions appeared to dominate Reco. The Recoδ 13 C differences between Shallow-Dry and Deep-Dry were significant but surprisingly small. This most likely suggests that, under dry conditions, soil warming stimulates root and surface SOC respiration with a negative 13 C signature that opposes the more positive 13 C signal from increased deep SOC respiration. In Deep-Wet conditions, Recoδ 13 C suggests reduced deep SOC loss but could also reflect altered diffusion or methane (CH 4 ) dynamics. Together, these results demonstrate that frequent Recoδ 13 C measurements can detect deep SOC loss and that plants confound the signal. In future studies, soil profile δ 13 C measurements, vegetation removal across thaw gradients, and isotopic effects of CH 4 dynamics could further deconvolute deep SOC loss via surface Reco.

AB - High latitude warming and permafrost thaw will expose vast stores of deep soil organic carbon (SOC) to decomposition. Thaw also changes water movement causing either wetter or drier soil. The fate of deep SOC under different thaw and moisture conditions is unclear. We measured weekly growing-season δ 13 C of ecosystem respiration (Recoδ 13 C) across thaw and moisture conditions (Shallow-Dry; Deep-Dry; Deep-Wet) in a soil warming manipulation. Deep SOC loss was inferred from known δ 13 C signatures of plant shoot, root, surface soil, and deep soil respiration. In addition, a 2-year-old vegetation removal treatment (No Veg) was used to isolate surface and deep SOC decomposition contributions to Reco. In No Veg, seasonal Recoδ 13 C indicated that deep SOC loss increased as the soil column thawed, while in vegetated areas, root contributions appeared to dominate Reco. The Recoδ 13 C differences between Shallow-Dry and Deep-Dry were significant but surprisingly small. This most likely suggests that, under dry conditions, soil warming stimulates root and surface SOC respiration with a negative 13 C signature that opposes the more positive 13 C signal from increased deep SOC respiration. In Deep-Wet conditions, Recoδ 13 C suggests reduced deep SOC loss but could also reflect altered diffusion or methane (CH 4 ) dynamics. Together, these results demonstrate that frequent Recoδ 13 C measurements can detect deep SOC loss and that plants confound the signal. In future studies, soil profile δ 13 C measurements, vegetation removal across thaw gradients, and isotopic effects of CH 4 dynamics could further deconvolute deep SOC loss via surface Reco.

KW - carbon

KW - isotope partitioning

KW - permafrost

KW - respiration

KW - thaw

KW - warming

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VL - 124

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EP - 60

JO - Journal of Geophysical Research: Biogeosciences

JF - Journal of Geophysical Research: Biogeosciences

IS - 1

ER -

Using Stable Carbon Isotopes of Seasonal Ecosystem Respiration to Determine Permafrost Carbon Loss

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