Patterns and drivers of anaerobic nitrogen transformations in sediments of thermokarst lakes

Denitrification, anaerobic ammonium oxidation (anammox), and dissimilatory nitrate reduction to ammonium (DNRA) are three competing processes of microbial nitrate reduction that determine the degree of ecosystem nitrogen (N) loss versus recycling. However, the global patterns and drivers of relative contributions of these N cycling processes to soil or sediment nitrate reduction remain unknown, limiting our understanding of the global N balance and management. Here, we compiled a global dataset of 1570 observations from a wide range of terrestrial and aquatic ecosystems. We found that denitrification contributed up to 66.1% of total nitrate reduction globally, being significantly greater in estuarine and coastal ecosystems. Anammox and DNRA could account for 12.7% and 21.2% of total nitrate reduction, respectively. The contribution of denitrification to nitrate reduction increased with longitude, while the contribution of anammox and DNRA decreased. The local environmental factors controlling the relative contributions of the three N cycling processes to nitrate reduction included the concentrations of soil organic carbon, ammonium, nitrate, and ferrous iron. Our results underline the dominant role of denitrification over anammox and DNRA in ecosystem nitrate transformation, which is crucial to improving the current global soil N cycle model and achieving sustainable N management.

Section: Discussionmentioning

confidence: 99%

Denitrification dominates dissimilatory nitrate reduction across global natural ecosystems

Deng,

He,

Ding

et al. 2024

“…The organic C pool in 0–3 m of soils is ~15.3–46.2 Pg (Ding et al, 2016; Wang et al, 2021). Due to the continuous climate warming, the alpine permafrost is rapidly degrading, characterized by the thickening of the active layer (~2 cm year −1 ; Wang et al, 2022) and the widespread occurrence of thermokarst landscape such as thermo‐erosion gully (Yang et al, 2021) and thermokarst lake (Mao et al, 2023; Wei et al, 2021). The permafrost degradation was predicted to result in ~122 Tg (1 Tg = 10 12 g; under Representative Concentration Pathway 4.5, a moderate scenario) and ~300 Tg (under Representative Concentration Pathway 8.5, a worst‐case scenario) of permafrost C release across the plateau by 2099 (Liu et al, 2022).…”

Section: Methodsmentioning

confidence: 99%

“…The organic C pool in 0-3 m of soils is ~15.3-46.2 Pg (Ding et al, 2016;Wang et al, 2021). Due to the continuous climate warming, the alpine permafrost is rapidly degrading, characterized by the thickening of the active layer (~2 cm year −1 ; Wang et al, 2022) and the widespread occurrence of thermokarst landscape such as thermo-erosion gully (Yang et al, 2021) and thermokarst lake (Mao et al, 2023;Wei et al, 2021). The permafrost…”

Section: Study Areamentioning

confidence: 99%

Microbial nitrogen and phosphorus co‐limitation across permafrost region

Zhang

Wang

Qin

et al. 2023

Self Cite

The status of plant and microbial nutrient limitation have profound impacts on ecosystem carbon cycle in permafrost areas, which store large amounts of carbon and experience pronounced climatic warming. Despite the long‐term standing paradigm assumes that cold ecosystems primarily have nitrogen deficiency, large‐scale empirical tests of microbial nutrient limitation are lacking. Here we assessed the potential microbial nutrient limitation across the Tibetan alpine permafrost region, using the combination of enzymatic and elemental stoichiometry, genes abundance and fertilization method. In contrast with the traditional view, the four independent approaches congruently detected widespread microbial nitrogen and phosphorus co‐limitation in both the surface soil and deep permafrost deposits, with stronger limitation in the topsoil. Further analysis revealed that soil resources stoichiometry and microbial community composition were the two best predictors of the magnitude of microbial nutrient limitation. High ratio of available soil carbon to nutrient and low fungal/bacterial ratio corresponded to strong microbial nutrient limitation. These findings suggest that warming‐induced enhancement in soil nutrient availability could stimulate microbial activity, and probably amplify soil carbon losses from permafrost areas.

“…The dominant permafrost types on the Tibetan Plateau are discontinuous (50%–90%) and sporadic (10%–50%) permafrost (Wang et al, 2022; Zhang et al, 2008), which account for 55.4% and 41.4%, respectively, of the total permafrost area of the region (Figure S1). Over recent decades, the plateau has undergone accelerated soil warming (Ran et al, 2018) and extensive permafrost degradation (Mao et al, 2023; Ni et al, 2021; Xu et al, 2023). Permafrost temperature at a depth of 10 m has increased at an average rate of 0.02–0.78°C decade −1 from 2004 to 2018 (Zhao et al, 2021).…”

Section: Methodsmentioning

confidence: 99%

Priming effect stimulates carbon release from thawed permafrost

Chen

et al. 2023

Self Cite

Climate warming leads to widespread permafrost thaw with a fraction of the thawed permafrost carbon (C) being released as carbon dioxide (CO 2 ), thus triggering a positive permafrost C-climate feedback. However, large uncertainty exists in the size of this model-projected feedback, partly owing to the limited understanding of permafrost CO 2 release through the priming effect (i.e., the stimulation of soil organic matter decomposition by external C inputs) upon thaw. By combining permafrost sampling from 24 sites on the Tibetan Plateau and laboratory incubation, we detected an overall positive priming effect (an increase in soil C decomposition by up to 31%) upon permafrost thaw, which increased with permafrost C density (C storage per area). We then assessed the magnitude of thawed permafrost C under future climate scenarios by coupling increases in active layer thickness over half a century with spatial and vertical distributions of soil C density. The thawed C stocks in the top 3 m of soils from the present (2000)(2001)(2002)(2003)(2004)(2005)(2006)(2007)(2008)(2009)(2010)(2011)(2012)(2013)(2014)(2015) to the future period (2061-2080) were estimated at 1.0 (95% confidence interval (CI): 0.8-1.2) and 1.3 (95% CI: 1.0-1.7) Pg (1 Pg = 10 15 g) C under moderate and high Representative Concentration Pathway (RCP) scenarios 4.5 and 8.5, respectively. We further predicted permafrost priming effect potential (priming intensity under optimal conditions) based on the thawed C and the empirical relationship between the priming effect and permafrost C density. By the period 2061-2080, the regional priming potentials could be 8.8 (95%