Background

What is the goal of this WebApp?

Target audience

Scientifically sound, easy to understand, and with a pinch of humour: this WebApp is aimed at those with a personal or professional interest, at teachers and school classes, and at the curious and brave who want to learn more about the impacts of climate change on Switzerland.

In particular, it speaks to the impatient, who prefer their facts in small, digestible portions; to the intrepid, who aren’t afraid of complexity; and to those who want to take the future into their own hands – today.

What is presented?

Using three different extreme climate scenarios of increasing severity, the WebApp shows what impacts heatwaves, prolonged droughts, and extreme rainfall could have on the environment and society in Switzerland; what interactions and chain reactions these impacts can trigger; and what measures and solutions already exist – or are currently being developed by researchers – to deal with extreme events.

What isn't presented?

A handful of topics, such as peatlands and grasslands, as well as changes in energy production, or the impact of adaptation measures – on agriculture, for example and many other possible solutions and measures.
Some of the connections between the areas presented, so users don’t get lost in the complexity.

This is just a first selection!

What’s behind the climate scenarios?

The Extremes WebApp considers three levels of climate extremes. All three levels describe the near future – the next 20 years. The more extreme the 'extreme', the lower the probability of the scenario. Nevertheless it is physically consistent for levels 1 to 3 and therefore well within the realm of possibility. Levels 0 and 4 are not physical scenarios and are included purely for entertainment purposes.

Level 1:

The extremes shown in Level 1 broadly correspond to the extreme events of the past 10-15 years, such as the severe droughts of 2003 or 2018-2020. In other words, these are extremes that are no longer all that extreme, because they have occurred repeatedly or with increasing frequency in recent years.

Level 2:

At this level, extreme events are shown as they appear in the official climate scenarios for Switzerland (CH2018) up to around 2040. These scenarios therefore do not describe average conditions, but rather the more extreme climate that occurs occasionally in several models in the near future. The impacts of such climate events have been calculated or derived in numerous studies. They are summarised at this level.

Level 3:

The most extreme level is represented by scenarios that are relatively unlikely, but physically plausible. These are calculated using climate models that are deliberately pushed towards extreme conditions. This generates scenarios that broadly correspond to the once-in-a-century events that occurred in California between 2011 and 2015, or in Chile over the past 10–15 years. Such events do occur, but not very often – their consequences, however, can be severe. Due to a lack of suitable data, the impacts of these climate events have not yet been fully modelled. Progress is currently being made in this area. The impacts described here have been extrapolated to Switzerland based on observations and studies from other regions. As a result, they are less certain than the impacts described in Level 2.

How are future extreme events studied?

Two different methods are commonly used to study extreme events.

The first is known as “space-for-time substitution”. Instead of waiting locally – for example in Switzerland – for extreme events to occur frequently enough to build sufficiently large datasets for analysis, researchers study extreme events elsewhere. Around the world, extreme events such as prolonged droughts occur repeatedly and with increasing frequency. By studying these events where they occur, many extreme events can be compiled and analysed in a short period of time, and general rules can be derived (Chen et al. 2025). Not all events identified in this way are typical for Switzerland. However, there are many events in other regions of the world that are similar, and therefore relevant, to Switzerland.


The second approach is based on model simulations. To be realistic, these simulations must correctly represent the chain of effects from cause to impact. Science has developed many suitable models, ranging from global to regional climate models, which can produce different projections of future climate conditions. A further step is taken by impact models, which simulate the effects of such climatic extremes on the environment and society and therefore require extreme input data. Generating plausible datasets for climate extremes in specific regions is highly challenging, as these datasets must be physically consistent and include an approximate probability of occurrence. Such datasets can, for example, be extracted from the vast archives of climate model data used as the basis for IPCC reports (e.g. IPCC 2023). Because these archives do not always provide the extremes typical for a given region, it has recently become possible to simulate extreme climate events in a targeted way (Gessner et al. 2022, 2023; Fischer et al. 2023). These simulated extreme events can then be used in models to calculate their impacts.

References:
Chen L., Brun P., Buri P., Fatichi S., Gessler A., McCarthy M.J., Pellicciotti F., Stocker B., Karger D.N. (2025) Global increase in the occurrence and impact of multiyear droughts. Science Vol. 387 (6731): 278-284. DOI: 10.1126/science.ado4245
Fischer E.M., Beyerle U., Bloin-Wibe L., Gessner C., Humphrey V., Lehner F., Pendergrass A.G., Sippel S., Zeder J., Knutti R. (2023). Storylines for unprecedented heatwaves based on ensemble boosting. Nature Communications 14(1):4643.
Gessner C., Fischer E.M., Beyerle U., Knutti R. (2023) Developing Low‐Likelihood Climate Storylines for Extreme Precipitation Over Central Europe. Earth's Future 11(9): e2023EF003628.
Gessner C., Fischer E.M., Beyerle U., Knutti R. (2022) Multi-year drought storylines for Europe and North America from an iteratively perturbed global climate model. Weather and Climate Extremes 1;38:100512.
Intergovernmental Panel on Climate Change IPCC (2023). Summary for Policymakers. In: Climate Change 2023: Synthesis Report. Contribution of Working Groups I, II and III to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. IPCC, Geneva, Switzerland, pp. 1-34, doi: 10.59327/IPCC/AR6-9789291691647.001

What’s behind the WebApp?

The Extremes WebApp was developed as part of the Swiss Federal Institute for Forest, Snow and Landscape Research (WSL) Extremes Research Programme (2020–2025). The Extremes Research Programme focuses on extreme events and the development of solution-oriented approaches in collaboration with non-academic partners.

The EMERGE project characterises mega-droughts worldwide in order to identify trends and delineate how prolonged, multi-year droughts could develop in Europe and Switzerland.

The ExtremeThaw project investigates the impact of climate warming on the distribution of permafrost in Switzerland, and looks at the associated potential release of pollutants, as well as the effects on high-alpine vegetation and the carbon balance in mountainous regions.

The MountEx project develops digital decision-support tools for forward-looking forest management in mountain regions. In these regions, protection forests safeguard against natural hazards – but are themselves increasingly affected by climate change.

Building on an existing drought-warning platform, the MaLeFiX project is developing additional 30-day forecasts for bark beetle populations, forest fire risk, watercourse temperatures, groundwater levels, and more. Such forecasts support decision-making and planning.

In collaboration with a local energy provider, the ALANex project investigates the effects of light pollution on nocturnal insects in order to derive recommendations for public lighting.

Who contributed to the WebApp?

The WebApp was made possible through the financial support of the Swiss Federal Institute for Forest, Snow and Landscape Research (WSL). In addition to the Extremes Research Programme and its project collaborators, the following contributors were responsible for developing the content:

Astrid Björnsen
Niklaus Zimmermann

Kontakt: extremesprogram@wsl.ch

Concept development, visual design, programming, and translating scientific content into digestible chunks was the work of Zense GmbH

Marion Deichmann, Projectlead and Animation
Madleina Dörig, Illustration and Screendesign
Sven Langone, Animation
Mirko Lemme, Programming
Yves Erne, Art Direction
with the support of the Zense-Team.

Technical Support:
Christian Wessalowski and Wei Li, WSL IT.

Reference:
Astrid Björnsen, Marion Deichmann, Madleina Dörig, Peter Bebi, Pierluigi Calanca, Martin Gossner, Dirk N. Karger, Petia Nikolova, Tobias Wechsler, Massimiliano Zappa, Niklaus E. Zimmermann (2025). How Will Switzerland’s Climate Look in Future? WebApp.

The WebApp is Open Access. All texts and illustrations are licensed under the Creative Commons Attribution 4.0 International (CC BY 4.0) licence. They may be freely reproduced, distributed, and adapted, provided the source is acknowledged.

WSL accepts no liability for any damage resulting from the application or use of the WebApp.

topics pages

  1. Climate Change

    .+4 °C and beyond: Swiss landscapes under climate change. Link

    References:

    Climate impact of CO₂:
    Etminan M. et al. (2016) Radiative forcing of carbon dioxide, methane, and nitrous oxide: A significant revision of the methane radiative forcing. Geophysical Research Letters 43(24): 12614-12623. Link

    Relationship between CO₂ and temperature
    Arrhenius, S. (1896). On the Influence of Carbonic Acid in the Air upon the Temperature of the Ground. Philosophical Magazine and Journal of Science, 41, 237–276.
    Callendar G.S. (1938). The artificial production of carbon dioxide and its influence on temperature. Quarterly Journal of the Royal Meteorological Society. Link

    Temperature rise and industrialisation:
    Hansen J et al (2006) Global temperature change. PNAS 103(39): 14288-14293. Link

    Impacts of global temperature rise:
    IPCC, 2022. Climate Change 2022: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press. Link

    Regional impacts:
    IPCC (2022) Summary for Policymakers. Pörtner H.O. et al.(eds.)]. In: Climate Change 2022: Impacts, Adaptation, and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 3-33, doi:10.1017/9781009325844.001. Link
    Federal Office for the Environment (2025). Climate Risk Analysis for Switzerland: Basis for Adaptation to Climate Change. Umwelt-Wissen series, Bern. Link

    Temperature change and economic production:
    Burke, M. et al. (2015) Global non-linear effect of temperature on economic production. Nature 527, 235–239. Link

    Climate change in Switzerland
    https://www.meteoswiss.admin.ch/climate/climate-change.html

    Kyoto Protocol reduction targets (Switzerland’s target in Annex B): Link

    Feedbacks and tipping points:
    Steffen W. et al. (2018) Trajectories of the Earth System in the Anthropocene. PNAS 115(33): 8252-8259. Link

    Climate Change

  2. Heavy Precipitation

    Swiss Climate Scenarios CH2018: Heavy precipitation Link

    Reference:
    Peleg, N., Koukoula, M., Marra F. (2025). A 2°C warming can double the frequency of extreme summer downpours in the Alps. npj Climate and Atmospheric Science 8: 216. Link

    Heavy Precipitation

  3. Drought

    Since the wake-up call of the hot and dry summer of 2003, Switzerland has engaged intensively with the issue of drought. More than 20 years later, research – and subsequent events – have confirmed that even the 'water tower of Europe,' the Alps, can be affected by extreme drought. Global studies also point to the growing risk of multi-year droughts, which could have consequences for the environment and society that are still difficult to imagine today. Switzerland is not unprepared, however: since 2012, research institutions and public authorities have been working closely together to improve preparedness for future drought events.

    Further information: Conference proceedings, pp. 13, 73, 87

    Reference:
    Zappa M., Karger D.N., Hüsler F. (2025) Extreme drought in Switzerland: Regional and local perspectives of a global challenge. In: Björnsen A. (Ed.) Forum for Knowledge 2025: Extremes. WSL Ber. 164, 13-21. Link

    Drought

  4. Heat

    Heatwaves pose a major global challenge, not least because these extreme events have serious impacts on human health. Due to climate change, the intensity, duration, and frequency of heatwaves have increased significantly in most regions of the world. Climate model simulations project that further increases in greenhouse gas concentrations in the atmosphere will make such extremes even more likely. Forecasting can help to warn vulnerable groups and affected sectors at an early stage, allowing appropriate measures to be taken.

    Further information: Conference proceedings, pp. 23 and 31

    More about research:
    Domeisen, D.I.V. (2025). Heatwaves in a changing climate: How well prepared are we? In: Björnsen, A., Zimmermann, N. (Eds.), Forum for Knowledge 2025: Extremes. WSL Reports 164, 23–30. Link

    More about practise:
    Huber, N. (2025). Impacts of Heat on Health. In: Björnsen, A. (Ed.), Forum for Knowledge 2025: Extremes. WSL Reports 164, 31–34. Link

    Heat

  5. Glacier Retreat

    Why Glaciers Matter – And What Research Is Doing. Video with Daniel Farinotti, WSL

    Glaciers in Switzerland (2025): Factsheet (PDF)

    References:

    Ayala, A., Farinotti, D., Stoffel, M., & Huss, M. (2020). Glaciers: Hydro-CH2018 synthesis report chapters:“future changes in hydrology “. ETH Zurich. 
    Farinotti, D., Pistocchi, A., & Huss, M. (2016). From dwindling ice to headwater lakes: could dams replace glaciers in the European Alps?. Environmental Research Letters11(5), 054022. Link
    Huss, M., & Hock, R. (2018). Global-scale hydrological response to future glacier mass loss. Nature Climate Change8(2), 135-140. Link
    Linsbauer, A., Huss, M., Hodel, E., Bauder, A., Fischer, M., Weidmann, Y., ... & Schmassmann, E. (2021). The New Swiss Glacier Inventory SGI2016: from a topographical to a glaciological dataset. Frontiers in Earth Science9, 704189. Link
    Stahl K., Weiler M., Kohn I., Freudiger D., Seibert J., Vis M., Gerlinger K. 2017: The snow and glacier melt components of streamflow of the river Rhine and its tributaries considering the influence of climate change. Final report to the International Commission for the Hydrology of the Rhine basin (CHR). English version. Report CHR 00-03 2017. Link
    Zekollari, H., Huss, M., & Farinotti, D. (2019). Modelling the future evolution of glaciers in the European Alps under the EURO-CORDEX RCM ensemble. The Cryosphere13(4), 1125-1146. Link

    Glacier Retreat

  6. Permafrost

    Changes in alpine permafrost usually occur out of sight, yet they have important consequences for mountain regions. Over the past decade, permafrost temperatures in the Swiss Alps have risen by up to 1 °C, and the thaw layers have thickened by several metres. At the same time, the ice content in the ground has decreased, and rock glaciers have been moving downslope faster than at the beginning of monitoring more than 20 years ago. These substantial changes below the surface threaten high-mountain infrastructure and lead to an increase in natural hazards such as rockfalls and debris flows.

    Further information: Conference proceedings, p. 35

    Reference:
    Nötzli, J., Peter, A., Hählen, N., & Phillips, M. (2025). Hidden ice in the Swiss Alps: Permafrost is thawing ever faster. In: Björnsen, A. (Ed.), Forum for Knowledge 2025: Extremes. WSL Reports 164, 35–47. Link

    Permafrost

  7. Gravitational Natural Hazards

    WSL Magazine DIAGONAL 1/25 on Climate Change and Natural Hazards: Link

    WSL Research Programme Climate Change and Alpine Mass Movements (CCAMM) 2018–2025: Link and News WSL

    References:

    Bettzieche, J. (2024). More wet, less dry: The avalanches of the future. WSL News, 6 November 2024. Link
    Bettzieche, J. (2024). Climate change leads to more alpine hazards. WSL News, 31 October 2024. Link
    Swiss Federal Institute for Forest, Snow and Landscape Research WSL (2025). Stop! Danger! Climate change and natural hazards. WSL Magazine Diagonal, 2025/1: 36 pp. Link
    Jacquemart M., Weber S., Chiarle M., Chmiel M., … & Markus Stoffel (2024). Detecting the impact of climate change on alpine mass movements in observational records from the European Alps. Earth-Science Reviews 258:104886. Link
    Naturgefahrenportal des Bundes: https://www.naturgefahren.ch
    Walter et al. (2020) Direct observations of a three million cubic meter rock-slope collapse with almost immediate initiation of ensuing debris flows. Gemorphology 351, 1069333. Link

    Gravitational Natural Hazards

  8. Water Balance

    References:

    Swiss Federal Office for the Environment (FOEN) (2021). Impacts of climate change on Swiss waters. NCCS Hydro-CH2018. Environmental Knowledge Series. 134 pp. Synthesis report and brochure. Synthesebericht und Broschüre.
    Federal Office for the Environment (FOEN) (2023). Heat and drought in summer 2022. Dossier
    Brunner et al. (2019). Contribution of water reservoirs to reducing future water scarcity? Wasser Energie Luft, 111(3), 145–152. Link
    Compagno et al. (2021). Brief communication: Do 1.0, 1.5, or 2.0 °C matter for the future evolution of Alpine glaciers? The Cryosphere 15(6). https://tc.copernicus.org/articles/15/2593/2021/
    Lanz et al. (2021). Impacts of climate change on water management in Switzerland. Beiträge zur Hydrologie der Schweiz, Bern. Link
    Padrón, R. S., Zappa, M., Bernhard, L., & Bogner, K. (2025). Extended-range forecasting of stream water temperature with deep-learning models. Hydrology and Earth System Sciences, 29(6), 1685-1702. Link

    Water Balance

  9. Tree Vitality

    Drought & beech. Video on WSL research.

    Tree Vitality

  10. Agriculture

    References:

    Recommendations for climate adaptation:
    Agroscope dossier “Climate change challenge" Link
    Wuyts et al. (2023). Climate-resilient arable farming 2035. Agroscope Science 177, 197 pp. Link
    Heinz et al. (2024) How to find alternative crops for climate-resilient regional food production. Agricultural Systems 213 (103793). Link

    Impacts of drought and CO₂:
    Holzkaemper, A., & Calanca, P. (2022). Impacts of the drought years 1947, 2003 and 2018 on agriculture. In: Hot and dry summers in Switzerland. Geographica Bernensia, Bern, 16–17. Link
    Webber et al. (2018). Diverging importance of drought stress for maize and winter wheat in Europe. Nature Communications 9 (4249). Link

    Soil moisture: measurements and forecasts
    www.bodenmessnetz.ch
    www.bodenfeuchte-ostschweiz.ch (Eastern Switzerland)
    www.oasi.ti.ch/web/dati/suolo.html (Southern Alps)

    Agriculture

  11. Biodiversity

    Biodiversity

  12. Fish Mortality and Species Extinction

    Why is heat problematic for fish? SRF Kids News video Link

    Reference

    Bonaglia A, Shen C, Padrón R, Bogner K, Fopp F, Rubin A, Rubin JF, Adde A, Guisan A, Albouy C, Pellissier L (2025). Sub-seasonal forecasting of thermal stress for Swiss river fishes during heatwaves. Ecological Modelling 507, 111171. Link

    Fish Mortality and Species Extinction

  13. Energy Production

    References:

    Federal Department of the Environment, Transport, Energy and Communications (DETEC) (2021). Joint declaration of the Round Table on Hydropower. Minutes of 21 June 2021. Link
    Micocci, D., Bragalli, C., Toth, E., Wechsler, T., Zappa., M. (2025). Hybridization of an Alpine pumped-storage hydropower plant with floating solar photovoltaics: a study from the water resource perspective. Renewable Energy. Link
    Otero et al. (2023). Impacts of hot-dry conditions on hydropower production in Switzerland. Env. Res. Letters 18(6): 064038. Link
    Stecher G, Herrnegger M (2022) Impact of hydropower reservoirs on floods: evidence from large river basins in Austria. Hydrological Sciences Journal 67(14). Link

    Energy Production

  14. Loss of Protection Forests

    The increasing frequency of extreme disturbance events such as bark beetle infestations and windthrow in the context of climate change poses major challenges for forest management in Switzerland. Particularly affected are spruce-dominated mountain forests, which are widespread and often fulfil a key protective function against natural hazards. WSL is working together with practitioners to develop a basis for prioritising the management of these forests under the influence of extreme disturbances. To this end, spatial data on forest structure, site conditions, disturbance susceptibility, and natural hazards are linked at landscape scale with silvicultural, planning, and economic aspects, and visualised in an interactive dashboard.

    References:
    Bont LG, Blatter C, Rath L, Schweier J (2025). Automatic detection of forest management units to optimally coordinate planning and operations in forest enterprises. Journal of Environmental Management 372: 123276. Link
    Hobi, M., Brandes, T., Bebi, P., Helzel, K., Bottero, A., Bührle, L., … (2025). Management of spruce-dominated mountain forests in the context of extreme disturbances. In: Björnsen, A., Zimmermann, N. (Eds.), Forum for Knowledge 2025: Extremes. WSL Reports 164, 49–59. Link
    WSL (2023). Interim results of the 5th National Forest Inventory (NFI). Swiss forests are suffering under weather extremes. Media release, 30 May 2023. Link

    Loss of Protection Forests

  15. Forest Fires

    When, where, how often, why, and how intensely forests burn depends on many factors. In the short term, forest fire risk is primarily influenced by extreme drought, often combined with high temperatures or strong winds that make combustible material more flammable. In the long term, land use and population pressure are decisive factors alongside climate change. The decline of traditional agriculture in rural regions and the more frequent occurrence of prolonged droughts in recent years point to a possible intensification of the phenomenon.

    Referenz:

    Pezzatti, G.B., Conedera, M., Ferriroli, D., Ghiringhelli, A., Ballmer, M., & Beyeler, S. (2025). Forest fires under climate change: Is Switzerland prepared? In: Björnsen, A., Zimmermann, N. (Eds.), Forum for Knowledge 2025: Extremes. WSL Reports 164, 61–72. Link

    Carbon release after forest fires:
    Santín C. et al. (2016) Towards a global assessment of pyrogenic carbon from vegetation fires. Global Change Biology 22(1): 76-91. Link

    Forest Fires

  16. Bark Beetle

    Bark Beetle at WSL (Website)

    Bark Beetle

  17. CO₂ Balance

    CO₂ Balance