Opposing Effects of Plant-Community Assembly Maintain Constant Litter Decomposition over Grasslands Aged from 1 to 25 Years

Barbe, Lou; Prinzing, Andreas; Mony, Cendrine; Abbott, Benjamin W.; Santonja, Mathieu; Hoeffner, Kevin; Guillocheau, Sarah; Cluzeau, Daniel; Francez, André-Jean; Bris, Nathalie Le; Jung, Vincent

doi:10.1007/s10021-019-00392-8

Cited by 4 publications

(4 citation statements)

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“…Additionally, it remains unknown how long this newly accumulated reservoir of silica in terrestrial biomass will persist on site before dissolution or export to downstream systems occur; plant decomposition rates will likely differ with burn succession and shifting plant community composition (Barbe et al, 2019;Hobbie et al, 2000;Turetsky et al, 2010;Wickland et al, 2007), impacting lateral silica export rates from terrestrial systems over the long term. However, substantial uncertainties remain about how the silica cycle will respond to changes in wildfire in the tundra biome, as this is the first study on this subject, to our knowledge.…”

Section: Complex and Persistent Effects Of Wildfire On Tundra Silicamentioning

confidence: 99%

“…Whether an initial lateral pulse of silica was exported following a burn, as well as the magnitude and duration of such a pulse, directly influences the 10.1029/2019EF001149 Earth's Future mass balance of silica. Additionally, it remains unknown how long this newly accumulated reservoir of silica in terrestrial biomass will persist on site before dissolution or export to downstream systems occur; plant decomposition rates will likely differ with burn succession and shifting plant community composition (Barbe et al, 2019;Hobbie et al, 2000;Turetsky et al, 2010;Wickland et al, 2007), impacting lateral silica export rates from terrestrial systems over the long term.…”

Section: Complex and Persistent Effects Of Wildfire On Tundra Silicamentioning

confidence: 99%

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Plant Uptake Offsets Silica Release From a Large Arctic Tundra Wildfire

2019

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Rapid climate change at high latitudes is projected to increase wildfire extent in tundra ecosystems by up to fivefold by the end of the century. Tundra wildfire could alter terrestrial silica (SiO 2 ) cycling by restructuring surface vegetation and by deepening the seasonally thawed active layer. These changes could influence the availability of silica in terrestrial permafrost ecosystems and alter lateral exports to downstream marine waters, where silica is often a limiting nutrient. In this context, we investigated the effects of the largest Arctic tundra fire in recent times on plant and peat amorphous silica content and dissolved silica concentration in streams. Ten years after the fire, vegetation in burned areas had 73% more silica in aboveground biomass compared to adjacent, unburned areas. This increase in plant silica was attributable to significantly higher plant silica concentration in bryophytes and increased prevalence of silica-rich gramminoids in burned areas. Tundra fire redistributed peat silica, with burned areas containing significantly higher amorphous silica concentrations in the O-layer, but 29% less silica in peat overall due to shallower peat depth post burn. Despite these dramatic differences in terrestrial silica dynamics, dissolved silica concentration in tributaries draining burned catchments did not differ from unburned catchments, potentially due to the increased uptake by terrestrial vegetation. Together, these results suggest that tundra wildfire enhances terrestrial availability of silica via permafrost degradation and associated weathering, but that changes in lateral silica export may depend on vegetation uptake during the first decade of postwildfire succession. Plain Language SummaryClimate change in the Arctic is leading to more frequent and severe wildfire in Arctic tundra ecosystems. Studying the silica (SiO2) cycle in Arctic ecosystems is important because the amount of silica exported from land to sea can control uptake by marine primary producers in Arctic coastal waters. We investigated how tundra wildfire affects silica cycling by returning to a large Arctic wildfire 10 years after the burn to collect samples of stream water, vegetation, and peat. We found that plants growing on burned landscapes contained 73% more silica in their aboveground biomass compared to unburned areas nearby. While the fire thawed permafrost underneath it, we did not observe increased levels of silica in streams draining burned areas. This pattern indicates that elevated rates of silica uptake via plants may prevent increased silica export to marine waters following tundra wildfire. We conclude that the effect of tundra fire on silica cycling depends on the recovery trajectories of terrestrial and aquatic ecosystems in the Arctic.

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Section: Complex and Persistent Effects Of Wildfire On Tundra Silicamentioning

confidence: 99%

Section: Complex and Persistent Effects Of Wildfire On Tundra Silicamentioning

confidence: 99%

Plant Uptake Offsets Silica Release From a Large Arctic Tundra Wildfire

2019

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“…Though land use in specific parcels of the catchment has varied substantially in the past (Barbe et al 2020), crop rotations have created a reasonably uniform N input time series at the catchment scale (Kolbe et al 2019). Because this method only accounts for NO3removed after the water lost contact with the atmosphere (i.e., in the saturated zone), it accounts implicitly for biogeochemical removal or retention in the unsaturated zone (Thomas and Abbott 2018, Basu et al 2022.…”

Section: Estimating Nitrate Removalmentioning

confidence: 99%

Deep denitrification: Stream and groundwater biogeochemistry reveal contrasted but connected worlds above and below

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Errigo

Proteau

et al. 2023

Science of The Total Environment

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“…Because aquifers contain two orders of magnitude more water than all rivers and lakes (Abbott et al 2019), groundwater nitrogen can be stored for decades before reaching the surface (Fenton et al 2011;Wendland et al 2002). However, because the major form of groundwater nitrogen is nitrate (NO 3 -), microbial activity during groundwater storage and J o u r n a l P r e -p r o o f Journal Pre-proof transport can reduce nitrogen stocks via anaerobic catabolism (denitrification), which eventually transforms NO 3 into N 2 gas (Green et al 2016;Kolbe et al 2019;Korom 1992).…”

Section: Introductionmentioning

confidence: 99%