Changing sub-Arctic tundra vegetation upon permafrost degradation: impact on foliar mineral element cycling

Mauclet, Elisabeth; Agnan, Yannick; Hirst, Catherine; Monhonval, Arthur; Pereira, Benoît; Vandeuren, Aubry; Villani, Maëlle; Ledman, Justin; Taylor, M.; Jasinski, Briana L.; Schuur, Edward A. G.; Opfergelt, Sophie

doi:10.5194/bg-2021-263

Cited by 2 publications

(2 citation statements)

References 22 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Betula nana was found to increase near-surface long-lived fine root biomass in a fertilization experiment (Sullivan et al, 2007), which could partially explain its successful eventual replacement of E. vaginatum (which has an annual root system) in long-term Arctic fertilization experiments (Shaver and Chapin, 1995;Shaver et al, 2001). Recent studies have suggested that initial uptake of nutrients by fast-growing graminoids and other deeply rooted forbs may move nutrients above-ground in the form of more quickly decomposing litter, where shrubs may then access it over longer time-scales (Wookey et al, 2009;Hewitt et al, 2019;Mauclet, Agnan, et al, 2021).…”

Section: A Natural Thermokarst Gradient Versus a Warming Experimentsmentioning

confidence: 99%

Plant foliar nutrient response to active layer and water table depth in warming permafrost soils

et al. 2022

Self Cite

View full text Add to dashboard Cite

1. Thawing permafrost in northern latitudes has led to deepening active soil layers and fluctuating water tables. This could increase plant access to permafrostderived nitrogen (N), phosphorus (P) and other nutrients such as calcium (Ca) and magnesium (Mg), and subsequently increase plant productivity and ecosystem carbon storage and nutrient cycling. We hypothesized that deepening permafrost thaw and water table fluctuations would alter species-specific foliar N:P ratios. Since there is often more P, Ca and Mg available in the deeper mineral soil layers and more N available in the shallow organic layers, we expected that deeply rooted species would decrease foliar N:P ratios due to root proximity to thawing mineral soil, and plants with shallower rooting systems mostly in the organic layer would increase foliar N:P ratios.2. We assessed foliar and canopy nutrient responses of seven vascular plant species in moist acidic tussock tundra vegetation in the northern foothills of the Alaska Range to variable soil thaw depths and water table levels induced by either a natural thermokarst gradient or a winter warming snow fence experiment.3. In both the natural thermokarst gradient and the warming experiment, wet or deeply thawed areas generally led to an increase in foliar nutrient concentrations and greater canopy mass and canopy nutrients. For the majority of species, foliar N:P ratios remained proportional or decreased in deciduous species in wet sites, with the exception of one shallowly rooted species that increased foliar N:P ratio in deeply thawed sites. Overall, plant acquisition of P was more related to water table level than to thaw depth, and water table modulated the canopy biomass response of the species at the warming experiment. 4. Synthesis. Foliar N:P ratios suggest that plant species in this tussock tundra ecosystem are either remaining or becoming more N-limited as thaw depth deepens and water table level rises, indicating that P is not likely to become the primary limiting nutrient with the progression of permafrost thaw. However, the amount of deeply thawed, wet areas that develop on the landscape as permafrost thaws will be important contributors in the total movement of nutrients above-ground.

show abstract

Section: A Natural Thermokarst Gradient Versus a Warming Experimentsmentioning

confidence: 99%

Plant foliar nutrient response to active layer and water table depth in warming permafrost soils

et al. 2022

Self Cite

View full text Add to dashboard Cite

show abstract

“…Non-vascular plant cover is dominated by mosses (mainly Sphagnum spp., Dicranum spp., and feather mosses including Hylocomium splendens and Pleurozium schreberi) and lichen species (e.g., Nephroma spp., Cladonia spp., and Flavocetraria cucullata) (Deane-Coe et al, 2015;Natali et al, 2012;Schuur et al, 2007). Since the start of the thermokarst development, vegetation cover changed with the evergreen and deciduous shrubs (as V. uliginosum and R. tomentosum), and forbs (as R. chamaemorus) being dominant at the expense of the sedges (Jasinski et al, 2018;Mauclet et al, 2021;Schuur et al, 2007;Villani et al, 2022).…”

Section: Study Area and Samplingmentioning

confidence: 99%

Quantifying stocks in exchangeable base cations in permafrost: a reserve of nutrients about to thaw

Mauclet

Villani

Monhonval

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

Abstract. Permafrost ecosystems are limited in nutrients for vegetation development and constrain the biological activity to the active layer. Upon Arctic warming, permafrost degradation exposes large amounts of soil organic carbon (SOC) to decomposition and minerals to weathering, but also releases organic and mineral soil material that may directly influence the soil exchange properties (cation exchange capacity and base saturation). The soil exchange properties are key for nutrient base cation supply (Ca2+, K+, Mg2+) for vegetation growth and development. In this study, we investigate the distribution of soil exchange properties within typical Arctic tundra permafrost soils at Eight Mile Lake (Interior Alaska, USA) because they will dictate the potential reservoir of newly thawed nutrients and thereby influence soil biological activity and vegetation nutrient sources. Our results highlight a difference in the SOC distribution within soil profiles according to the permafrost thaw. The poorly thawed permafrost soils (active layer thickness; ALT ≤ 60 cm) present more organic material in surface (i.e., organic layer thickness; OLT ≥ 40 cm) than the highly thawed permafrost soil (i.e., ALT > 60 cm and OLT < 40 cm). In turn, this difference in SOC distribution directly affects the soil exchange complex properties. However, the low bulk density of organic-rich soil layers leads to much lower CEC density in surface (~9 400 cmolc m-3) than in the mineral horizons of the active layer (~16 000 cmolc m-3) and in permafrost soil horizons (~12 000 cmolc m-3). As a result of the overall increase in CEC density with depth and the overall increase in base saturation with depth (from ~20 % in organic surface to 65 % in permafrost soil horizons), the average total stock in exchangeable base cations (Ca2+, K+, Mg2+ and Na+ in g m-3) is more than 2-times higher in the permafrost than in the active layer. More specifically, the stocks in base cations in the upper part of permafrost about to thaw in the following are ~ 860 g m-3 for Caexch, 45 g m-3 for Kexch, 200 g m-3 for Mgexch and 150 g m-3 for Naexch. This first order estimate is a needed step for future ecosystem prediction models to provide constraint on the size of the reservoir in exchangeable nutrients (Ca, K, Mg) about to thaw.

show abstract

Changing sub-Arctic tundra vegetation upon permafrost degradation: impact on foliar mineral element cycling

Cited by 2 publications

References 22 publications

Plant foliar nutrient response to active layer and water table depth in warming permafrost soils

Plant foliar nutrient response to active layer and water table depth in warming permafrost soils

Quantifying stocks in exchangeable base cations in permafrost: a reserve of nutrients about to thaw

Contact Info

Product

Resources

About