Climate change impacts on sediment yield and debris-flow activity at the Illgraben, Switzerland

Mapping Intimacies ◽

10.5194/egusphere-egu2020-17017 ◽

2020 ◽

Author(s):

Jacob Hirschberg ◽

Simone Fatichi ◽

Georgie Bennett ◽

Brian McArdell ◽

Stuart Lane ◽

...

Keyword(s):

Climate Change ◽

Debris Flow ◽

Surface Runoff ◽

Debris Flows ◽

Cascade Model ◽

Weather Generator ◽

Climate Scenarios ◽

Climate Services ◽

The Future ◽

Flow Activity

Debris flows are rapid mass movements composed of a mixture of water and sediments and often pose a danger to humans and infrastructure. In the Alpine environment, they are mostly triggered by intense rainfall, snowmelt or a combination thereof, and conditioned by sediment availability. Their occurrence is expected to increase in a warmer climate due to changes in the hydrological regime (e.g. higher rainfall intensity, lower duration of snow cover). Furthermore, sediment production is likely to accelerate due to permafrost thawing and changes in freeze-thaw cycles, resulting in increased sediment availability. For the purpose of climate change impact assessment on sediment yield and debris-flow activity, interactions and feedbacks of climate and the aforementioned processes need to be considered jointly.In the study presented here, we address this challenge by forcing a sediment cascade model (SedCas1) with precipitation and temperature from a stochastic weather generator (AWE-GEN2) producing ensembles of possible climate in the present and for the future. The chosen study site is the Illgraben, a debris-flow prone catchment in the Swiss Alps which currently produces 3-4 debris flows yearly on average. SedCas conceptualizes a geomorphic system in which hillslopes produce and store sediments from landslides and eventually deliver them to the channels. From there, sediments can be mobilized by concentrated surface runoff and transferred out of the catchment in form of bedload, hypreconcentrated flow, or debris flows, depending on the surface runoff magnitude and the sediment availability. AWE-GEN operates at the hourly scale and is trained for the current climate with observed data and for the future climate using the newest climate change projections for Switzerland CH2018 developed by the National Center for Climate Services3.Preliminary results reveal a likely increase in debris-flow occurrence in the Illgraben in the future. Such an increase can be attributed to an extension in the debris-flow seasonal changes in the discharge regime. Furthermore, the number of landslides filling the sediment storage increases because they are affected by a shorter duration of snow cover and thus greater exposure to freeze-thaw weathering. However, projections are subject to large uncertainties, stemming not only from uncertainty in climate scenarios, but also from internal climate variability. Furthermore, the simplified hillslope weathering and debris-flow triggering mechanisms contribute to the overall uncertainty. Nevertheless, the methodology is thought to be transferable to any sediment-cascade-like catchment where dominant processes are driven by climate. Lastly, this work highlights the importance of considering stochasticity in climate and sediment history for projections of magnitudes and frequencies of relative rare events as debris flows. This allows us to explicitly separate climate change signals in geomorphic processes from fluctuations induced by internal natural variability.REFERENCES1 Bennett, G. L., et al. "A probabilistic sediment cascade model of sediment transfer in the Illgraben." Water Resources Research 50.2 (2014): 1225-1244. doi: 10.1002/2013WR0138062 Fatichi, S., et al. "Simulation of future climate scenarios with a weather generator." Advances in Water Resources 34.4 (2011): 448-467. doi: 10.1016/j.advwatres.2010.12.0133 CH2018 - Climate Scenarios for Switzerland. National Centre for Climate Services (2018): doi: 10.18751/Climate/Scenarios/CH2018/1.0

Debris-flow activity in abandoned channels of the Manival torrent reconstructed with LiDAR and tree-ring data

Natural Hazards and Earth System Science ◽

10.5194/nhess-11-1247-2011 ◽

2011 ◽

Vol 11 (5) ◽

pp. 1247-1257 ◽

Cited By ~ 22

Author(s):

J. Lopez Saez ◽

C. Corona ◽

M. Stoffel ◽

A. Gotteland ◽

F. Berger ◽

...

Keyword(s):

Debris Flow ◽

Tree Ring ◽

Debris Flows ◽

Temporal Distribution ◽

Alluvial Fan ◽

Tree Ring Data ◽

Pine Trees ◽

Spatio Temporal ◽

Flow Activity ◽

Abandoned Channels

Abstract. Hydrogeomorphic processes are a major threat in many parts of the Alps, where they periodically damage infrastructure, disrupt transportation corridors or even cause loss of life. Nonetheless, past torrential activity and the analysis of areas affected during particular events remain often imprecise. It was therefore the purpose of this study to reconstruct spatio-temporal patterns of past debris-flow activity in abandoned channels on the forested cone of the Manival torrent (Massif de la Chartreuse, French Prealps). A Light Detecting and Ranging (LiDAR) generated Digital Elevation Model (DEM) was used to identify five abandoned channels and related depositional forms (lobes, lateral levees) in the proximal alluvial fan of the torrent. A total of 156 Scots pine trees (Pinus sylvestris L.) with clear signs of debris flow events was analyzed and growth disturbances (GD) assessed, such as callus tissue, the onset of compression wood or abrupt growth suppression. In total, 375 GD were identified in the tree-ring samples, pointing to 13 debris-flow events for the period 1931–2008. While debris flows appear to be very common at Manival, they have only rarely propagated outside the main channel over the past 80 years. Furthermore, analysis of the spatial distribution of disturbed trees contributed to the identification of four patterns of debris-flow routing and led to the determination of three preferential breakout locations. Finally, the results of this study demonstrate that the temporal distribution of debris flows did not exhibit significant variations since the beginning of the 20th century.

Debris flows on forested cones – reconstruction and comparison of frequencies in two catchments in Val Ferret, Switzerland

Natural Hazards and Earth System Science ◽

10.5194/nhess-7-207-2007 ◽

2007 ◽

Vol 7 (2) ◽

pp. 207-218 ◽

Cited By ~ 26

Author(s):

M. Bollschweiler ◽

M. Stoffel

Keyword(s):

Debris Flow ◽

Debris Flows ◽

Historical Knowledge ◽

Study Region ◽

Sampling Height ◽

The Alps ◽

Recurrence Intervals ◽

Study Sites ◽

Flow Activity ◽

Different Characteristics

Abstract. Debris flows represent a major threat to infrastructure in many regions of the Alps. Since systematic acquisition of data on debris-flow events in Switzerland only started after the events of 1987, there is a lack of historical knowledge on earlier debris-flow events for most torrents. It is therefore the aim of this study to reconstruct the debris-flow activity for the Reuse de Saleinaz and the La Fouly torrents in Val Ferret (Valais, Switzerland). In total, 556 increment cores from 278 heavily affected Larix decidua Mill., Picea abies (L.) Karst. and Pinus sylvestris L. trees were sampled. Trees on the cone of Reuse de Saleinaz show an average age of 123 years at sampling height, with the oldest tree aged 325 years. Two periods of intense colonization (the 1850s–1880s and the 1930s–1950s) are observed, probably following high-magnitude events that would have eliminated the former forest stand. Trees on the cone of Torrent de la Fouly indicate an average age of 119 years. As a whole, tree-ring analyses allowed assessment of 333 growth disturbances belonging to 69 debris-flow events. While the frequency for the Reuse de Saleinaz study site comprises 39 events between AD 1743 and 2003, 30 events could be reconstructed at the Torrent de la Fouly for the period 1862–2003. Even though the two study sites evince considerably different characteristics in geology, debris-flow material and catchment morphology, they apparently produce debris flows at similar recurrence intervals. We suppose that, in the study region, the triggering and occurrence of events is transport-limited rather than weathering-limited.

Watershed Hydrological Response to Combined Land Use/Land Cover and Climate Change in Highland Ethiopia: Finchaa Catchment

Water ◽

10.3390/w12061801 ◽

2020 ◽

Vol 12 (6) ◽

pp. 1801 ◽

Cited By ~ 1

Author(s):

Wakjira Takala Dibaba ◽

Tamene Adugna Demissie ◽

Konrad Miegel

Keyword(s):

Climate Change ◽

Land Use ◽

Water Resources ◽

Land Cover ◽

Surface Runoff ◽

Regional Climate ◽

Water Yield ◽

Land Use Land Cover ◽

Ensemble Mean ◽

The Future

Land use/land cover (LULC) and climate change affect the availability of water resources by altering the magnitude of surface runoff, aquifer recharge, and river flows. The evaluation helps to identify the level of water resources exposure to the changes that could help to plan for potential adaptive capacity. In this research, Cellular Automata (CA)-Markov in IDRISI software was used to predict the future LULC scenarios and the ensemble mean of four regional climate models (RCMs) in the coordinated regional climate downscaling experiment (CORDEX)-Africa was used for the future climate scenarios. Distribution mapping was used to bias correct the RCMs outputs, with respect to the observed precipitation and temperature. Then, the Soil and Water Assessment Tool (SWAT) model was used to evaluate the watershed hydrological responses of the catchment under separate, and combined, LULC and climate change. The result shows the ensemble mean of the four RCMs reported precipitation decline and increase in future temperature under both representative concentration pathways (RCP4.5 and RCP8.5). The increases in both maximum and minimum temperatures are higher for higher emission scenarios showing that RCP8.5 projection is warmer than RCP4.5. The changes in LULC brings an increase in surface runoff and water yield and a decline in groundwater, while the projected climate change shows a decrease in surface runoff, groundwater and water yield. The combined study of LULC and climate change shows that the effect of the combined scenario is similar to that of climate change only scenario. The overall decline of annual flow is due to the decline in the seasonal flows under combined scenarios. This could bring the reduced availability of water for crop production, which will be a chronic issue of subsistence agriculture. The possibility of surface water and groundwater reduction could also affect the availability of water resources in the catchment and further aggravate water stress in the downstream. The highly rising demands of water, owing to socio-economic progress, population growth and high demand for irrigation water downstream, in addition to the variability temperature and evaporation demands, amplify prolonged water scarcity. Consequently, strong land-use planning and climate-resilient water management policies will be indispensable to manage the risks.

Options and challenges for collaboration on climate service related activities at KNMI and KMI

10.5194/egusphere-egu2020-1532 ◽

2020 ◽

Author(s):

Janette Bessembinder ◽

Rozemien De Troch

Keyword(s):

Climate Change ◽

Service Providers ◽

Climate Modelling ◽

Climatic Data ◽

Climate Scenarios ◽

Climate Services ◽

Climate Conditions ◽

Societal Needs ◽

Climate Service ◽

Meteorological Institute

National meteorological institutes have generally a longstanding scientific expertise in climate research, climatological observations, and state-of-the-art climate modelling. In the context of climate change this expertise and service provision of climatic data, information and knowledge is of crucial importance to meet the societal needs. Furthermore, in each country the provision of climate services is generally arranged differently and strongly determined by governance, the official strategy and tasks of the meteorological institutes, as well as financing.To better align the activities between national climate service providers, the Royal Netherlands Meteorological Institute and the Royal Meteorological Institute of Belgium successfully applied for the ERA4CS action for the exchange of staff, aiming to contribute to the alignment of R&D programmes, tools/instruments and/or climate related agendas of both countries.In the context of climate services, previous interactions between both institutes are mainly related to sporadically contacts between scientists in need of climatological data or information on methods for the definition of e.g. climate scenarios. However, Belgium and the Netherlands are neighbouring, both small countries, and climate change doesn&#8217;t stop at the border. Furthermore, coastal and inland regions along the borders are yet very sensitive to the impacts of climate change, and thus might cause cross-border issues in the future. Therefore, a two-way visit of senior staff responsible for climate services in both institutes is planned for early 2020. The visits aim to identify the differences and similarities on how climate services are currently provided and the broader context in which climate services are developed and delivered (legal mandate, what other organisations deliver climate services, relation with policy e.g. National Adaptation Strategies). More specifically, the services related to both current and future climate conditions (i.e. climate scenarios), the respective impact sectors and users/stakeholders of the climate services and the interaction with them, the used tools and methods for the creation of climate services, and the outreach and communication strategies for climate services will be discussed through informal interactions, meetings and presentations. An overview of these discussions together with conclusions on how climate-service related actions can be aligned and consolidated within future collaborations, will be presented.

Debris-flow activity in five adjacent gullies in a limestone mountain range

Geochronometria ◽

10.1515/geochr-2015-0007 ◽

2015 ◽

Vol 42 (1) ◽

Cited By ~ 10

Author(s):

Klaus Schraml ◽

Markus Oismüller ◽

Markus Stoffel ◽

Johannes Hübl ◽

Roland Kaitna

Keyword(s):

Debris Flow ◽

Debris Flows ◽

National Park ◽

Regional Scale ◽

Field Investigation ◽

Mountain Range ◽

Sediment Sources ◽

Aerial Vehicle ◽

Flow Activity ◽

Local Variability

Abstract Debris-flows are infrequent geomorphic phenomena that shape steep valleys and can repre-sent a severe hazard for human settlements and infrastructure. In this study, a debris-flow event chro-nology has been derived at the regional scale within the Gesäuse National Park (Styria, Austria) using dendrogeomorphic techniques. Sediment sources and deposition areas were mapped by combined field investigation and aerial photography using an Unmanned Aerial Vehicle (UAV). Through the analysis of 384 trees, a total of 47 debris-flows occurring in 19 years between AD 1903 and 2008 were identified in five adjacent gullies. Our results highlight the local variability of debris-flow activi-ty as a result of local thunderstorms and the variable availability of sediment sources.

Periglacial preconditioning of debris flows in the Southern Alps, New Zealand

10.26686/wgtn.17008210 ◽

2021 ◽

Author(s):

◽

Katrin Sattler

Keyword(s):

New Zealand ◽

Debris Flow ◽

Debris Flows ◽

Southern Alps ◽

Ice Growth ◽

Frost Weathering ◽

Flow Formation ◽

Flow Systems ◽

Spatially Distributed ◽

Flow Activity

The lower boundary of alpine permafrost extent is considered to be especially sensitive to climate change. Ice loss within permanently frozen debris and bedrock as a consequence of rising temperature is expected to increase the magnitude and frequency of potentially hazardous mass wasting processes such as debris flows. Previous research in this field has been generally limited by an insufficient understanding of the controls on debris flow formation. A particular area of uncertainty is the role of environmental preconditioning factors in the spatial and temporal distribution of debris flow initiation in high-alpine areas. This thesis aims to contribute by investigating the influence of permafrost and intensive frost weathering on debris flow activity in the New Zealand Southern Alps. By analysing a range of potential factors, this study explores whether debris flow systems subjected to periglacial influence are more active than systems outside of the periglacial domain. A comprehensive debris flow inventory was established for thirteen study areas in the Southern Alps. The inventory comprises 1534 debris flow systems and 404 regolith-supplying contribution areas. Analysis of historical aerial photographs, spanning six decades, identified 240 debris flow events. Frequency ratios and logistic regression models were used to explore the influence of preconditioning factors on the distribution of debris flows as well as their effect on sediment reaccumulation in supply-limited systems. The preconditioning factors considered included slope, aspect, altitude, lithology, Quaternary sediment presence, neo-tectonic uplift rates (as a proxy for bedrock fracturing), permafrost occurrence, and frost-weathering intensity. Topographic and geologic information was available in the form of published datasets or was derived from digital elevation models. The potential extent of contemporary permafrost in the Southern Alps was estimated based on the statistical evaluation of 280 rock glaciers in the Canterbury region. Statistical relationships between permafrost presence, mean annual air temperature, and potential incoming solar radiation were used to calculate the spatially distributed probability of permafrost occurrence. Spatially distributed frost-weathering intensities were estimated by calculating the number of annual freeze-thaw cycles as well as frost-cracking intensities, considering the competing frost-weathering hypotheses of volumetric ice expansion and segregation ice growth. Results suggest that the periglacial influence on debris flow activity is present at high altitudes where intense frost weathering enhances regolith production. Frost-induced debris production appears to be more efficient in sun-avert than sun-facing locations, supporting segregation ice growth as the dominant bedrock-weathering mechanism in alpine environments. No indication was found that permafrost within sediment reservoirs increases slope instability. Similarly, the presence of permanently frozen bedrock within the debris flow contribution areas does not appear to increase regolith production rates and hence debris flow activity. Catchment topography and the availability of unconsolidated Quaternary deposits appeared to be the cardinal non-periglacial controls on debris flow distribution. This thesis contributes towards a better understanding of the controls on debris flow formation by providing empirical evidence in support of the promoting effect of intense frost weathering on debris flow development. It further demonstrates the potential and limitations of debris flow inventories for identifying preconditioning debris flow controls. The informative value of regional-scale datasets was identified as a limitation in this research. Improvement in the spatial parameterisation of potential controls is needed in order to advance understanding of debris flow preconditioning factors.

The City Pack - the co-production of an urban climate service providing local summaries of a city's future climate

10.5194/egusphere-egu21-6236 ◽

2021 ◽

Author(s):

Elizabeth Fuller ◽

Claire Scannell ◽

Victoria Ramsey ◽

Rebecca Parfitt ◽

Nicola Golding

Keyword(s):

Climate Change ◽

Urban Climate ◽

City Council ◽

Future Climate ◽

Future Climate Change ◽

Climate Change Scenarios ◽

Climate Services ◽

The Future ◽

Climate Service ◽

The City

In 2018, the UN estimated that around 55% of the world&#8217;s population currently live within urban areas, with this value projected to rise to 60% by 2030 (United Nations, 2018). High levels of urbanisation, coupled with an increasing trend in extreme weather under future climate change scenarios, combine to create significant challenges to increasing urban resilience for the future (Masson et al., 2020).Urban climate services provide tools to support decision making at a range of scales across the city, from day-to-day operations to informing urban design over longer timescales (Grimmond et al., 2015). Whilst urban climate services may be developed at a range of scales (Grimmond et al., 2020), this presentation looks at a prototype climate service which provides long-term climate change projections at the city-specific scale. The &#8216;City Pack&#8217; was developed through a process of co-production, in which project development aims to move away from a one-way push of scientific information, to a two-way collaborative process of knowledge construction and sharing (Vincent et al., 2019).This &#8216;City Pack&#8217; service was co-developed by the Met Office and Bristol City Council following an assessment of the Council&#8217;s climate information needs. The City Pack comprises of three non-technical factsheets which explain how the climate of Bristol has changed and will continue to change into the 21st Century based on the UKCP climate projections. The City Pack&#8217;s primary aims are to raise awareness of how a cities climate may change in the future and to inform the development of city resilience whilst also providing a tool to be used by city stakeholders to raise awareness of climate change across the council. The audience for the City Pack therefore includes city officials, city planners and the general public. The Bristol City Pack has since provided an evidence base for the Bristol City Council Climate Change Risk Assessment and informed Bristol&#8217;s Climate Strategy. In addition, the City Pack has been used to engage with the council&#8217;s wider stakeholders and also as a communication and training tool. As such, whilst the co-production of a climate service may be time and resource intensive, the process may also be rewarded with the production of a highly tailored and user-relevant tool.Following the success of the prototype &#8216;City Pack&#8217; service for Bristol City Council, the Met Office are continuing to produce City Packs for additional cities across the UK, and also in China. The project is seeking to ascertain if services which are co-produced with and bespoke to one set of stakeholders, may provide an equally valuable service for other cities and if so, how can we make these services scalable.

ASSESSMENT OF FLUCTUATIONS IN THE CASPIAN SEA LEVEL UNDER THE INFLUENCE OF CLIMATE CHANGE FOR THE FUTURE UNTIL 2050

Hydrometeorology and ecology ◽

10.54668/2789-6323-2021-100-1-70-77 ◽

2021 ◽

Vol 100 (1) ◽

pp. 70-77

Author(s):

N.I. Ivkina ◽

◽

A.V. Galayeva ◽

◽

Keyword(s):

Climate Change ◽

Sea Level ◽

Air Temperature ◽

Caspian Sea ◽

Water Surface ◽

Climate Changes ◽

Meteorological Parameters ◽

Climate Scenarios ◽

The Caspian Sea ◽

The Future

The article considers the possible fluctuation of the Caspian Sea level in the future until 2050, taking into an account the climate changes. For this purpose, possible changes in the river inflow to the sea and meteorological parameters (precipitation, air temperature and evaporation from the water surface) were predicted. Changes in the meteorological parameters were estimated according to two climate scenarios RCP4. 5 and RCP8.5.

The geomorphic impact of large landslides: A case-study of the actively moving Alpine Gardens Landslide, Fox Glacier Valley, West Coast, New Zealand.

10.5194/egusphere-egu2020-12411 ◽

2020 ◽

Author(s):

Saskia de Vilder ◽

Chris Massey ◽

Garth Archibald ◽

Regine Morgenstern

Keyword(s):

New Zealand ◽

Debris Flow ◽

West Coast ◽

Debris Flows ◽

Sediment Flux ◽

Valley Floor ◽

Aerial Imagery ◽

Glacier Valley ◽

Flow Activity

Large landslides can result in significant geomorphic impacts to fluvial systems, via increased sediment input and subsequent changes to channel behaviour. We present a case-study of the actively moving&#160; &#820;65 M m&#179; Alpine Gardens Landslide in the Fox Glacier Valley, West Coast, New Zealand, to analyse the ongoing geomorphic impacts within the valley floor. Debris flows, sourced from the toe of the landslide, travel down Mill&#8217;s Creek and deposit sediment on the debris fan at its confluence with the Fox River. This debris flow activity and associated changes in sediment flux and fluvial behaviour have resulted in re-occurring damage to, and current closure of roads and tracks within the Fox Glacier Valley floor, impacting access to the Westland Tai Poutini National Park, the Fox Glacier, associated tourism, and the Fox Glacier township economy.Initial movement of the Alpine Gardens landslide was detected in 2015, with aerial imagery analysis between March 2017 and June 2018 indicating that the landslide may be accelerating. This acceleration may potentially result in increased debris flow activity within the landslide complex and sediment flux into the Fox River. To monitor and understand the controls on movement rate, we installed a continuous GPS monitoring station along with rainfall gauges on the landslide in February 2019. On average, the landslide moves at a rate of 0.12 m/day &#177; 0.13 m/day, however this rate of movement of the landslide is closely correlated to and fluctuates with rainfall. Significant accelerations of 0.5 m/day have occurred after heavy rainfall, with these rainfall events also resulting in large debris flows.We document and investigate the geomorphic impact of the Alpine Gardens landslide on the Mill&#8217;s Creek debris fan and Fox Glacier Valley floor via terrestrial laser scanning, airborne LiDAR, UAV surveys and aerial imagery. From this, we derive a time-series of nine surface change models to document the sediment flux within the Alpine Gardens Landslide and Mill&#8217;s Creek debris fan complex. Our initial results reveal that between March 2017 and June 2019, approximately 14.7 M m&#179; was eroded from the landslide, of which 3.7 M m&#179; was deposited directly on the debris fan. A further 9.6 M m&#179; has been transported downstream into the fluvial system. Upstream aggradation has also occurred, with 1.1 M m&#179; deposited in the river valley immediately upstream of the debris fan between June 2018 and June 2019. Continued monitoring of the Alpine Gardens Landslide and volumetric changes of the landslide complex allows us to understand the controls on the movement and sediment flux within the landslide and the geomorphic impact of large actively moving landslides on the valley floor, particularly within alpine and glacial environments.&#160;

The Influence of Debris Flow Activity on the Sediment of the Lake Plansee over 3.6 ka (Tyrol, Austria)

10.5194/egusphere-egu2020-21300 ◽

2020 ◽

Author(s):

Carolin Kiefer ◽

Michael Krautblatter ◽

Christoph Mayr ◽

Patrick Oswald ◽

Michael Strasser

Keyword(s):

Debris Flow ◽

Debris Flows ◽

Geophysical Methods ◽

Fold Increase ◽

Delivery Ratio ◽

Sedimentation Rates ◽

Autochthonous Organic Matter ◽

Flow Activity ◽

Debris Cone

Debris flows represent a widespread geomorphological hazard in mountainous regions. Understanding the long-term dynamics of debris flow activity in view of climate change is crucial for the prevention and mitigation of future events. The activity of debris flows is evidently linked to the magnitude of rainstorms. Dietrich & Krautblatter (2017) found an increase in debris flow volumes after 1980 by a factor of 2 compared to the period 1947-1980 and by a factor of 3 compared to the mean Lateglacial/Holocene debris flow volumes by investigating aerial photos of the surroundings of lake Plansee (Reutte, Austria) and estimating debris flow cone volumes with geophysical methods.In this study, the terrestrial observations of increasing debris flow volumes were compared with the subaquatic deposits from the deepest basin of the lake. The debris flow volume within a three-month period on a large debris cone was monitored by Terrestrial Laserscanning (TLS) and the debris flow activity over the last 3 600 years was reconstructed using sediment cores. Four short cores of up to 145 cm depth were recovered in a transect from the shallow subaquatic debris cone area to the deepest basin of the lake. The grain size, density, Magnetic Susceptibility as well as the d13-C, d15N- and C/N-ratios of the sediment were analyzed.The Terrestrial Laserscans revealed a sediment delivery ratio of 30% for the steep debris cone bordering the lake. In the four correlated short cores, 52 debris flow events were differentiated within the last 3 600 years of sedimentation. The proportion of event layers in the cores ranges between 34% and 57% of the total section thickness. The sedimentation rates from a dated core confirm the increase of debris flow activity that was observed with terrestrial methods by Dietrich & Krautblatter (2017). The sedimentation rates show an 11-fold increase after 1930 compared to the rates before 1930 and a 5-fold to 12-fold increase compared to the average Holocene sedimentation rates in lake Plansee. Three types of event deposits were distinguished according to sedimentological criteria: flood-triggered debris flows, earthquake-induced subaquatic suspension flows and mega-events. The TOC/TN ratios of the sediment reveal a permanent influence of terrestrial carbon on the lake sediment and a mixed source of allochthonous and autochthonous organic matter. Large debris flow events can be distinguished from background sediments by increased d13C isotope ratios.The results of this study reveal further scientific proof for the increase of debris flow activity in conjunction with increasing rainstorm activity. Here we show one of the first long-term archives of debris flow activity in the Northern Alps spanning the last 3 600 years and revealing cyclic shifts in debris-flow transport volumes by one order of magnitude.