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FS 26.121

Alpine carbon and nutrient dynamics

Session includes ...

Carbon, nutrient and water cycling in alpine peatlands and wetlands
Alpine carbon dynamics: measurements, models and processes

Session status: Accepted

Content last updated: 2026-04-16 00:06:26

Online available since: 2026-03-02 08:55:22

Details

Full Title
Alpine carbon and nutrient dynamics
Scheduled
TBA
TBA
Chair
Magnani, Marta
Co-chair(s)
van Grinsven, Sigrid; Vivaldo, Gianna; Platter, Alexander; and Saponaro, Vincenzo
Thematic Focus
Ecosystems, Modeling, Monitoring
Keywords
Alpine carbon dynamics, Soil nutrient cycling, Climate change impacts, Greenhouse gas fluxes

Abstract/Description

The European Alps are undergoing rapid climatic and environmental changes that are strongly affecting regional carbon and nutrient dynamics across a wide range of ecosystems, including peatlands, wetlands, forests, grasslands and glacier forelands. Carbon stocks and fluxes, as well as nutrient cycling, are highly heterogeneous, shaped by steep climatic gradients, complex topography, land-use history, and hydrological controls. For instance, recent findings highlight that alpine peatlands are more widespread than previously assumed and represent important long-term carbon reservoirs, while alpine wetlands may function as dynamic and transitional systems. However, how differing Alpine ecosystems will respond to warming, altered precipitation regimes, cryospheric change, and land-use pressures, remains insufficiently understood.

This session brings together experts working on all facets of carbon and nutrient dynamics in Alpine soils, including both high and low elevation sites. We welcome contributions presenting new estimates of carbon stocks in vegetation and soils, measurements of greenhouse gas fluxes (e.g. CO₂ , CH₄ or N2O), emergent remote-sensing approaches, studies focused on below-ground hydrology, soil biogeochemistry, microbiology or vegetation dynamics. We also encourage submissions presenting monitoring networks, and modelling frameworks aimed at upscaling observations, quantifying uncertainties, and projecting future trajectories under changing climate and land-use scenarios. By integrating observational, experimental, and modelling perspectives, the session aims to foster interdisciplinary exchange and improve understanding of the current and future soil dynamics of the Alpine Region.

Registered Abstracts

ID: 3.46

Declining SOC storage in Swiss mountain grasslands as an effect of declining effective storage capacity?

Matthias Volk
Uvere, Franklin; Huguenin-Elie, Olivier

Abstract/Description

In an earlier experiment above the Engadine valley (2200 m a.s.l., Canton Grisons) we demonstrated the climate sensitivity of subalpine pasture carbon (C) stocks, resulting in a negative net ecosystem C balance of ca. 10 t C ha^-1 in five years with + 3°C warming, despite unaffected plant productivity. A follow-up study, using a long-term (32 yrs.) grassland mineral fertilisation experiment above the Albula valley (1200 m a.s.l., Canton Grisons), indicated that under strongly limiting nitrogen (N) supply, the uniformly low N-availability set allometric limitations for microbial decomposition, leading to uniformly declining soil organic C (SOC) stocks.

In the study presented here, we analysed another long-term grassland fertilisation experiment in the Swiss Jura mountains (920 m a.s.l., Canton Solothurn), providing 22 years of climate, yield and SOC stock data. We attempted to isolate the effects of plant yield gradients (2.8 – 8.3 t dry matter ha^-1 yr^-1) and N-availability (0 – 150 kg N ha^-1 yr^-1) in driving SOC stock change.

We hypothesised that N-fertilisation driven plant productivity affects both organic matter availability for SOC storage and interacts with N availability driven C use efficiency levels to generate different, steady-state SOC stocks. But if SOC stocks would not differ between treatment combinations, we assumed that the climate factor, consisting of a distinct pattern of temperature and precipitation, would act evenly on effective SOC storage capacity and would result in the same SOC stocks in all treatment combinations.

We found that while plant productivity was highly responsive to different mineral fertilisation levels, SOC stocks were not responsive to either plant productivity or N input, even though they usually constitute limiting factors for soil C storage. This led us to assume that we observed, on a decadal scale, the decline from an earlier effective SOC storage capacity to a new, lower effective storage capacity. We deduce that the SOC stock decline is driven by increased temperatures, that have increased OM decomposition rates. This implies, that under the given edaphic conditions and including a wide range of agricultural management options, the warming climate constitutes an increasingly limiting factor for SOC storage.

ID: 3.115

Eddy-covariance CO₂ flux measurements at an alpine forest site

Alexander Platter
Hammerle, Albin; Wohlfahrt, Georg

Abstract/Description

We present eddy-covariance measurements of CO₂ exchange (net ecosystem exchange, NEE) from 2022–2025 from the Forest-Atmosphere-Interaction-Research (FAIR) site on the Mieminger Plateau, Tyrol, Austria, in a Scots pine (Pinus sylvestris) forest. Using observations from a measurement tower above the canopy, we quantify seasonal and interannual variability in ecosystem carbon budgets. Over the study period, the forest acted as a net CO₂ sink with annual NEE on the order of -100 g C m^–². Uptake typically peaks in spring, while frequent warm, dry spells in summer shift the system toward net carbon release, indicating that the timing of extremes is more consequential than mean climatic conditions and helps explain interannual variability.

To identify the dominant drivers of NEE dynamics, we fit Generalized Additive Models (GAMs) using air temperature, relative humidity, soil moisture, and shortwave radiation as predictors. Partial effects reveal a temperature optimum for gross primary production (GPP) around 17–20 °C. Simple scenario analyses based on the fitted GAMs suggest that, considering GPP alone, moderate warming could enhance photosynthetic uptake. However, accounting for ecosystem respiration, which is strongly temperature-sensitive, reduces sink strength and can shift the net balance towards a carbon source under warmer climates.

We further illustrate the role of event timing with simple extreme-event scenarios: a spring heatwave can increase net uptake under high light and favorable water status, whereas a comparable event in summer substantially reduces uptake or induces net release. These results emphasize how seasonal context and the timing of extreme events control alpine forest carbon dynamics.

ID: 3.117

Peatland Stratigraphy and Hydrogeology in Formerly Glaciated Alpine Regions

Marianna Mattiazzi
Hopfinger, Mathias; Salcher, Bernhard; Otto, Jan-Christoph; Flores-Orozco, Adrian; Hilberg, Sylke; Tribsch, Andreas; Watson-Cook, Emily; Wimmer, Xaver

Abstract/Description

Peatlands are ecosystems that comprise the largest terrestrial carbon store on Earth. They play a critical role in climate change mitigation, while also supporting unique biodiversity, regulating water flow and serving as palaeoecological archives. Understanding the history of peatland formation is essential for predicting their future development. The influence of glaciations on postglacial peat-forming processes has received limited attention, even though glaciers exert a first-order control on peatland development in both mountain environments and lowlands.

Glaciers can provide suitable conditions for peatland formation by the ability to i) form local depressions and ii) deliver abundant fine sediments to induce ponding. However, the efficiency of glacial erosion strongly depends on geological factors like rock erodibility or basal topography. Other factors may in turn impede postglacial peat accumulation despite apparently suitable geological and climatic conditions. These include e.g. a high flood frequency, fluvial erosion in alluvial valleys, or, in mountainous environments, high landslide frequency.

We apply a combination of geophysical methods, including ground penetrating radar and electrical resistivity tomography, and core drilling to investigate peatland stratigraphy and hydrogeology. We present characteristic peatland environments in central and perialpine settings and discuss how i) glacial depositional and ii) glacial erosional processes control their formation. In addition, we examine the onset of peat growth and rates of peat accumulation in formerly glaciated regions of the Eastern Alps.

These insights contribute to the understanding of present-day peatland ecosystem functioning, and the interactions between subsurface stratigraphy, hydrological characteristics and vegetation patterns. Such knowledge is essential for predicting their response to future climate change.

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FS 26.121

Alpine carbon and nutrient dynamics

Session includes ...

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Co-chair(s)

Thematic Focus

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Registered Abstracts

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