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Research article2024Peer reviewedOpen access

Radiocarbon Isotopic Disequilibrium Shows Little Incorporation of New Carbon in Mineral Soils of a Boreal Forest Ecosystem

Tangarife-Escobar, Andres; Guggenberger, Georg; Feng, Xiaojuan; Munoz, Estefania; Chanca, Ingrid; Peichl, Matthias; Smith, Paul; Sierra, Carlos A.

Abstract

Boreal forests fix substantial amounts of atmospheric carbon (C). However, the timescales at which this C is cycled through the ecosystem are not yet well understood. To elucidate the temporal dynamics between photosynthesis, allocation and respiration, we assessed the radiocarbon (C14 ${}<^>{14}\mathrm{C}$) disequilibrium (D) between different C pools and the current atmosphere to understand the fate of C in a boreal forest ecosystem. Samples of vegetation, fungi, soil and atmospheric CO2 ${\mathrm{C}\mathrm{O}}_{2}$ were collected at the Integrated Carbon Observation System station Svartberget in northern Sweden. Additionally, we analyzed the Delta 14 ${{\Delta }}<^>{14}$C-CO2 ${\mathrm{C}\mathrm{O}}_{2}$ from incubated topsoil and forest floor soil respiration (FFSR) collected over a 24-hr cycle, and calculated the Delta 14 ${{\Delta }}<^>{14}$C signature of the total ecosystem respiration (Re) using the Miller-Tans method. We found that vegetation pools presented a positive D enriched with bomb C14 ${}<^>{14}\mathrm{C}$, suggesting a fast-cycling rate (months to years) for living biomass and intermediate (years to decades) for dead biomass. In contrast, mineral soils showed a negative D, indicating minimal incorporation of bomb C14 ${}<^>{14}\mathrm{C}$. FFSR showed diurnal Delta 14 ${{\Delta }}<^>{14}$C variability (mean = 8.5 parts per thousand), suggesting predominance of autotrophic respiration of recently fixed labile C. Calculations for Delta 14 ${{\Delta }}<^>{14}$C in Re (median = 12.7 parts per thousand) demonstrate the predominance of C fixed from days to decades. Although the boreal forest stores significant amounts of C, most of it is in the soil organic layer and the vegetation, where it is cycled relatively fast. Only minimal amounts of recent C are incorporated into the mineral soil over long timescales despite the current stocks in soils being relatively old.Boreal forests play a key role as an alternative to sequester carbon dioxide (CO2 ${\mathrm{C}\mathrm{O}}_{2}$) from the atmosphere and mitigate climate change. However, there is uncertainty on where this CO2 ${\mathrm{C}\mathrm{O}}_{2}$ is stored and the timescales at which it remains. To understand this, we studied the fate of the atmospheric CO2 ${\mathrm{C}\mathrm{O}}_{2}$ since the beginning of the nuclear era (1950s) by measuring the radiocarbon content of vegetation, fungi, soil, forest floor soil respiration and atmospheric air from a boreal forest stand in northern Sweden. We found that vegetation stores carbon from months (in leaves and moss) to decades (in litter layer and wood debris), while the soil organic layer presented carbon even older than a century. In contrast, mineral soils contained little recent carbon along with low content of organic carbon. The analysis of FFSR revealed that carbon comes mainly from recently fixed carbon, while the overall ecosystem respiration reflected a mix of carbon sources, ranging from days to decades. Overall, the boreal forest stores substantial amounts of carbon, but most of it moves relatively fast through the ecosystem. Only a small amount of new carbon is added to the mineral soil where it remains for long timescales.The isotopic disequilibrium of 14C in ecosystem pools was used to infer the fate and temporal dynamics of C cycling in a boreal forest Ecosystem respiration reflected a mix of CO2 respired from various pools, dominated by autotrophic respiration of recently fixed C Bomb 14C is stored mainly in roots, wood, dead biomass, and the topsoil organic layer; minimal new C is incorporated in the mineral soil

Keywords

radiocarbon isotopic disequilibrium; carbon cycle timescales; boreal forest ecosystem; total ecosystem respiration; carbon storage; soil respiration

Published in

Journal of Geophysical Research: Biogeosciences
2024, Volume: 129, number: 9, article number: e2024JG008191Publisher: AMER GEOPHYSICAL UNION