Glucose addition increases the magnitude and decreases the age of soil respired carbon in a long-term permafrost incubation study

Elaine Pegoraro, Marguerite Mauritz, Rosvel Bracho, Chris Ebert, Paul Dijkstra, Bruce A. Hungate, Konstantinos T. Konstantinidis, Yiqi Luo, Christina Schädel, James M. Tiedje, Jizhong Zhou, Edward A.G. Schuur

Research output: Contribution to journalArticlepeer-review

33 Scopus citations

Abstract

Higher temperatures in northern latitudes will increase permafrost thaw and stimulate above- and belowground plant biomass growth in tundra ecosystems. Higher plant productivity increases the input of easily decomposable carbon (C) to soil, which can stimulate microbial activity and increase soil organic matter decomposition rates. This phenomenon, known as the priming effect, is particularly interesting in permafrost because an increase in C supply to deep, previously frozen soil may accelerate decomposition of C stored for hundreds to thousands of years. The sensitivity of old permafrost C to priming is not well known; most incubation studies last less than one year, and so focus on fast-cycling C pools. Furthermore, the age of respired soil C is rarely measured, even though old C may be vulnerable to labile C inputs. We incubated soil from a moist acidic tundra site in Eight Mile Lake, Alaska for 409 days at 15 °C. Soil from surface (0–25 cm), transition (45–55 cm), and permafrost (65–85 cm) layers were amended with three pulses of uniformly 13 C-labeled glucose or cellulose every 152 days. Glucose addition resulted in positive priming in the permafrost layer 7 days after each substrate addition, eliciting a two-fold increase in cumulative soil C loss relative to unamended soils with consistent effects across all three pulses. In the transition and permafrost layers, glucose addition significantly decreased the age of soil-respired CO 2 -C with Δ 14 C values that were 115‰ higher. Previous field studies that measured the age of respired C in permafrost regions have attributed younger Δ 14 C ecosystem respiration values to higher plant contributions. However, the results from this study suggest that positive priming, due to an increase in fresh C supply to deeply thawed soil layers, can also explain the respiration of younger C observed at the ecosystem scale. We must consider priming effects to fully understand permafrost C dynamics, or we risk underestimating the contribution of soil C to ecosystem respiration.

Original languageEnglish (US)
Pages (from-to)201-211
Number of pages11
JournalSoil Biology and Biochemistry
Volume129
DOIs
StatePublished - Feb 2019

Keywords

  • Carbon
  • Organic matter decomposition
  • Permafrost
  • Priming
  • Radiocarbon

ASJC Scopus subject areas

  • Microbiology
  • Soil Science

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