Abstract
Seismic hazard maps are crucial for earthquake mitigation and mostly rely on probabilistic seismic hazard analysis (PSHA). However, the practise and value of PSHA are under debate because objective testing procedures for seismic hazard maps are scarce. We present a lacustrine turbidite record revealing 44 earthquakes over the last ~ 14 ka and use it to test seismic hazard curves in southern Austria. We derive local seismic intensities for paleo-earthquakes by applying scaling relationships between the sedimentary imprint and seismic intensity of well-documented historical earthquakes. The last ~ 2.8 ka of the record agree with a Poissonian recurrence behaviour and therefore a constant hazard rate, which is the modelling choice for standard PSHA. The lacustrine data are consistent with the intensity-frequency relationship of the local seismic hazard curve, confirming the current PSHA approach for this part of Austria. On longer timescales, distinct phases of enhanced regional seismicity occurred, indicating a potential increase of seismic hazard after large earthquakes—a factor hitherto disregarded in the PSHA of the Eastern Alps. Our new method forms an independent procedure to test hazard maps in any setting where suitable lake systems are available.
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Introduction
Seismic hazard maps aim at providing communities with information about earthquake hazards and form the basis to develop appropriate mitigation strategies. Current best-practice seismic hazard maps mainly rely on probabilistic seismic hazard analysis (PSHA). PSHA combines models for the size and location of potential earthquakes and ground-motion models to forecast the shaking strength expected with a certain probability within a given period. The underlying assumption of standard probabilistic hazard modelling is that earthquake occurrence follows a time-independent Poissonian process, which implies a constant hazard rate over time1. On individual fault segments, however, strong earthquakes often occur in a more regular (quasi-periodic) pattern or in clusters with short interevent times separated by long quiescence periods2. PSHA has also been subject to criticism because of the occurrence of large, damaging earthquakes in regions of relatively low hazard according to seismic hazard maps3,4. The 2011 Tohoku earthquake (M 9.0), for instance, severely affected areas where the Japanese hazard map of 2010 predicted a probability of less than 0.1% of shaking with a minimum intensity “6-lower” on the Japan Meteorological Agency seismic intensity scale in the following 30 years5. Mitigation methods therefore were not prepared for an event of this magnitude and the subsequent tsunami, resulting in ~ 19,000 dead or missing persons and a direct damage of ~ $210 billion6. However, due to the probabilistic nature of the seismic hazard maps, individual earthquakes with shaking stronger than mapped do not invalidate a map7,8, but give reason to re-evaluate the PSHA input parameters and methodology, and to develop approaches to thoroughly test the resulting maps.
Assessing the performance of seismic hazard maps mainly resorts to the validation of the individual hazard model components and its input data (see Gerstenberger et al.9 and references therein). On-fault geologic and geomorphic studies have contributed greatly to seismic hazard analysis by providing data about the location, geometry and kinematics of active faults, information about their slip rate as well as the timing and magnitude of previous ruptures10. However, in regions where surface ruptures are absent or hardly accessible (e.g. subduction megathrust faults) or areas where strain is accommodated by complex fault networks (e.g. intraplate regions), the common methods to obtain this geological data (paleoseismic trenching, offset markers) are not applicable. Also, on-fault paleoseismology only informs fault source models and cannot validate the overall adequacy of a seismic hazard map in terms of seismic shaking.
A direct testing of seismic hazard curves has been attempted by using written historical data11. However, these (1) often fail to capture the long (> 500–1000 years) and variable recurrence times of the largest earthquakes in a region, especially in slowly deforming intraplate regions, and (2) often are used as model input data, and therefore cannot be used for model validation9,12. Short individual (paleo-) earthquakes chronologies can produce biased recurrence statistics13,14 and make it hard to assess hazard map performance7. A common approach is therefore to integrate observations from several sites and substitute time for space15,16,17. For this method to be valid, however, spatial dependence of the observations must be ruled out or accounted for18.
Lake sediments can archive seismic shaking with intensities of ~ V or higher19,20,21 as mass-transport deposits (MTDs), turbidites or in-situ deformations. Due to continuous sedimentation, they often provide exceptional age control and sensitively record several thousand years of earthquake shaking occurrence22,23,24,25. In case the sedimentary imprints are properly calibrated with shaking data from historical and/or recent earthquakes20,26, such lacustrine off-fault paleoseismic records can present a long-term archive of seismic ground motion and thus enable direct testing of hazard curves that underly seismic hazard maps.
Here, we use a calibrated lacustrine record spanning 14,000 years to independently test a local seismic hazard curve in Southern Austria. To do so, we verify whether the lake paleoseismic record may reflect a Poissonian process, as this is the underlying assumption of PSHA in Austria. We then compare the intensity-frequency relationships obtained from the lake record with the local seismic hazard curve and discuss how this new method can be used for independent validation and improvement of probabilistic seismic hazard analysis.
Seismotectonic framework and lake setting
The studied lake Wörthersee (See = German for lake) is located in the Austrian federal state of Carinthia, close to the border of Slovenia and Italy (Fig. 1). The crustal structure of this area presents three lithological domains: the European plate, the Adriatic microplate and the Pannonian fragment27 (Fig. 1a). The counterclockwise rotation of the Adriatic microplate that is ongoing since ~ 35 Ma causes a present-day N-S convergence of ~ 2–3 mm/year in the Eastern Alps. This convergence is accommodated by (1) the indentation of the relatively rigid Adriatic microplate (so-called South Alpine indenter) into the European plate, separated at the surface by the Periadriatic fault (PAF); (2) uplift in the Eastern Alps and (3) eastward extrusion of the Pannonian fragment27,28 (Fig. 1a, b). This geodynamic setting is reflected by back-thrusting in the southern Alps and strike-slip faults in the Eastern Alps and the Dinarides (Figs. 1b, 2a).
Carinthia is among the regions with the highest seismic hazard in Austria (Fig. 1b) due to its position close to the highly seismically active areas of Friuli and western Slovenia, seismicity along the Katschberg-, Mölltal- and Periadriatic fault as well as diffuse seismicity29. Historical and instrumental seismicity data attest that the area of Wörthersee has experienced at least five earthquakes of local intensities (IL) > V on the European Macroseismic scale (EMS-9830) over the last ~ 800 years31,32: in 1976 (Mw 6.4; IL V–V½), 1857 (Mw ~ 5.1; IL ~ V½), 1690 (Mw ~ 6.5; IL VII½–VIII½), 1511 (Mw ~ 6.9; IL VI¾–VII¾) and 1348 (Mw ~ 7; IL VIII–IX). The latter presumably constitutes the largest documented historical earthquake in the Alps.
Wörthersee (area = 19 km2, depth = 84 m) is a glacigenic lake fed by rather small inflows (mean discharge of the main inflow Reifnitzbach is 0.63 m3/s), draining a total catchment area of 162 km2. The lake is usually meromictic, i.e. mixing of the water column is limited to a certain depth, but oxygen-rich bottom water has been observed in recent years33. Wörthersee is subdivided into three main parts (western, middle, and eastern), which are in turn divided into physically separated depositional areas (DAs) by bedrock ridges or glacial morphologies (Fig. 2b).
Methods
Seismic hazard analysis in Austria
Earthquake catalogue
The underlying data source of seismic hazard analysis in Austria is the Austrian Earthquake Catalogue (AEC34), which covers the last ~ 1000 years. Outside of Austria, the AEC was harmonized with the catalogue of the International Seismological Centre (ISC). Due to the limited catalogue completeness in Carinthia (determined using the slope methods of Hakimhashemi and Grünthal35 and Stepp36), only the last ~ 200 years were used for the calculation of the magnitude-frequency-relationship in the Wörthersee source zone, thus excluding the strong historical earthquakes of 1690, 1511, and 1348CE. The minimum magnitude considered in PSHA was 3, and the catalogue was declustered following Gardner and Knopoff37, leading to a time window of ~ 1.4 years (for M = 6) within which an event is identified as part of an earthquake cluster.
Seismic hazard map
The current national seismic hazard map of Austria29 (Fig. 1b) is based on standard probabilistic seismic hazard analysis. The PSHA relies on (1) recently developed relationships between local magnitude, moment magnitude (Mw) and epicentral intensity and (2) a set of regional and global ground motion prediction equations (GMPEs), selected by statistical parameters from local seismic recordings. The input model for the hazard analysis is composed of two area source models and a smoothed seismicity model. In addition, a large-scale area source model is used to compensate for insufficient local data. For each source zone, the mean earthquake parameters (e.g. depth-distribution and source-mechanism) are calculated. The seismicity rate (magnitude-frequency distributions) of each source zone is determined using common methods38 and Bayesian penalized maximum likelihood39. Estimations of the maximum magnitude (Mmax) are based on the Electric Power Research Institute (EPRI) approach40, which was developed for areas with moderate seismicity. All models, magnitude frequency distributions, Mmax and GMPEs are combined in a logic tree and PSHA was performed with the software OpenQuake41. The output are hazard curves indicating the probability of exceedance of the maximum horizontal acceleration29.
Lacustrine paleoseismology
Hydro-acoustic methods
High-resolution bathymetric data (1 m) was acquired on Wörthersee using a SeaBat T50-P multibeam echosounder in combination with an AsteRx-U MARINE GNSS Heading System in 2017. Reflection seismic data were acquired using a single-channel 3.5 kHz Kongsberg Geopulse pinger (theoretical vertical resolution ~ 10 cm) and an Innomar SES-2000 light subbottom profiler (100 kHz primary frequency, 8 kHz secondary frequency; theoretical vertical resolution ~ 5 cm; see Fig. 2b for traces of seismic profiles). Seismic interpretation was done in IHS Markit Kingdom Suite version 2020, applying a bandpass filter (2–6 kHz) to the 3.5 kHz seismic data. Mass-transport deposits (MTDs) and their equivalent seismic-stratigraphic horizons were mapped to recognise synchronous—and therefore likely earthquake-triggered25—subaqueous slope failures. Thickness grids of MTDs (Supplementary Figs. 1–4) were calculated using the software Surfer 10 (Golden Software; simple kriging interpolation) by assuming an acoustic velocity of 1500/ms.
Sediment core analyses
In 2017 and 2018, short (~ 1.5 m) sediment cores were acquired in Wörthersee using a gravity corer with a manual percussion system. In 2018, long (up to ~ 11 m) sediment cores were retrieved with a modified Kullenberg gravity piston coring system42 and cut into 1.5 m sections. X-ray computed tomography (CT) scanning was carried out at the Medical University of Innsbruck, using a Siemens SOMATOM Definition AS with a voxel size of 0.2 × 0.2 × 0.3 mm. γ-density (at 0.5 cm resolution) and magnetic susceptibility data (at 0.2 cm resolution) was acquired at the Austrian Core Facility using a GEOTEK Multi-Sensor Core Logger (MSCL) and a Bartington MS2E point sensor. To assess elemental variability, the cores were scanned at a resolution of 0.2 or 1 mm with an ITRAX X-ray fluorescence scanner using a Mo tube (30 kV, 45 mA, 5 s exposure time). A centered-log ratio transformation was applied to the elemental intensities to avoid possible matrix and asymmetry effects43. Based on distinct patterns in the XRF-signal, a detailed core-to-core correlation was achieved.
Chronology
To confirm the core-to-core correlation and to date turbidites, AMS14C dating was carried out on terrestrial macro-remains from long cores WOER18-L5 and WOER18-L9 and short cores WOER17-02 and WOER17-21 (Supplementary Table 1). All ages were calibrated using IntCAL2044 and are reported as calibrated years before present (cal BP). Continuous age-depth models were produced using the Bayesian software BACON v. 2.5.7.45 (Supplementary Fig. 5), excluding all event layers > 1 cm. All dates were projected onto core WOER18-L5, resulting in a combined age-depth-model (Supplementary Fig. 5c). Turbidite ages were obtained from this model using a total of 3586 age-model iterations (Supplementary Table 2).
Earthquake trigger confidence levels and temporal resolution of turbidites
Turbidites were identified based on their homogeneous or fining-upward macroscopic appearance, high counts in Ca or Ti as well as their colour, which contrasts to the finely laminated hemipelagic background sediment20 (Supplementary Figs. 6–15). To infer an earthquake trigger of the turbidites, we rely on the “synchronicity criterion”21,46,47: simultaneously deposited turbidites in physically separated basins (= depositional areas) suggest a regional trigger, i.e. an earthquake. This approach is validated in a previous study by the presence of coeval turbidites related to the historical earthquakes of 1976, 1857, 1690, 1511, and 1348 CE20. Following this reasoning, we assign an earthquake trigger confidence level to each set of time-correlative turbidites (subsequently called “events”; Supplementary Table 3): The event deposits corresponding to historically documented earthquakes are assigned a very high confidence level; events recorded both in the western and eastern basin are assigned a high confidence level; events recorded in at least two long cores are assigned an intermediate confidence level; and events that are only present in a single long core are assigned a low confidence level. For some recent events, an anthropogenic trigger mechanism was inferred as these link to the construction of coastal infrastructure48. These human-induced deposits are discarded as earthquake-triggered, as are events that only show turbidites smaller than 2 mm (very low confidence level).
The deposition of the fine-grained, silty to clayey top of a turbidite takes weeks to months49. Two earthquakes with sufficient local seismic intensities that follow each other in close succession (< 1 year) would therefore lead to an amalgamated turbidite50, which we would interpret as a single earthquake. Therefore, the lake paleoseismic record of Wörthersee only contains mainshocks.
Calculation of local seismic intensities
Based on the historically or instrumentally documented earthquakes of 1976, 1857, 1690, 1511, and 1348 CE that are archived as turbidites and MTDs in the sedimentary record of Wörthersee, Daxer et al.20 established site-specific earthquake-recording thresholds (EQRTs) and scaling relationships between the sedimentary imprint and seismic intensity. To derive the local seismic intensity of an earthquake archived as a turbidite in the pre-historic sedimentary record of Wörthersee, we calculate the mean and standard deviation of the three intensity measures IEQRT, IDA and ICTT, where (1) IEQRT is the intensity derived from the maximum EQRT of coring sites with positive evidence, (2) IDA is the intensity derived from the scaled relative number of depositional areas that show positive evidence, and (3) ICTT is derived from the scaled cumulative turbidite thickness (Fig. 3).
Recurrence statistics
To account for the influence of age uncertainty on the recurrence data, we used all 3586 age-depth-model iterations and calculated the mean interevent times, the memory (M) and the burstiness (B) coefficient51. M ranges from − 1 to 1 and is positive when a long (short) interevent time is tendentially followed by a long (short) interevent time and negative when a long (short) interevent time is followed by a short (long) interevent time. B ranges from − 1 to 1 and provides insights in how regular earthquakes took place, with B = − 1 representing a perfectly periodic recurrence. A Poissonian (“time-independent” or “aperiodic”) process relates to a constant hazard rate and is characterized by an exponential distribution of interevent times for which B = 0. B values larger than 0 indicate a “bursty” recurrence pattern, meaning that the standard deviation of interevent times is larger than their mean. We follow the classification of Kempf and Moernaut13 and use the term “bursty” for B > 0.05, “aperiodic” for − 0.05 < B < + 0.05, “weakly periodic” for − 0.33 < B < − 0.05 and “strongly periodic” for B < − 0.33.
We evaluated whether the recurrence intervals are exponentially distributed—a requisite for a Poissonian process—using two statistical tests: (1) the Lilliefors-corrected Kolmogorov–Smirnov (KS) test (R-package “KScorrect”52) and (2) the two-sided Cox and Oakes test for exponentiality (R-package “exptest”53). The exponential distribution is rejected (at the 95% confidence level) if the p-value of the test is lower than 0.05. We also tested the goodness-of-fit of several other probability density functions often used in paleoseismic research54: gamma, lognormal and Weibull. A lognormal distribution is typical for a bursty recurrence behaviour with a high hazard rate after an event and a monotonic decrease with time. The same is true for gamma and Weibull distributions with α < 1. If α > 1, the gamma and Weibull distributions indicate a seismic cycle with a certain degree of periodicity, exhibiting a near-zero hazard after a large event and increasing with time.
Results
Paleoseismic record
We identified 14 seismostratigraphic event horizons (EH) on which several mass-transport deposits (MTDs) are located, indicating coeval failures of multiple subaqueous slopes (EHs A-O; Fig. 4; Supplementary Figs. 1–4; see also Daxer et al.20). The stratigraphic positions of the lowermost four EHs L-O are not within the studied interval of the sediment cores.
The uppermost ~ 11 m of the sedimentary infill of the western basin in core WOER18-L5, which is representative of the sedimentary succession in all lake basins, mainly consist of (from top to bottom) (1) faintly to non-laminated, calcite-poor, organic-rich silt comprising the last ~ 2.8 ka (herein called unit III; 0–1.75 m); (2) finely laminated calcite-rich silt spanning from ~ 2.8 to 13.7 ka (unit II; 1.75–5.3 m) and (3) grey clayey silt denoting the Late Glacial period older than 13.7 ka48 (unit I, 5.3–11 m; Fig. 4, Supplementary Fig. 6). The base of the cored interval in this study is marked by a several m thick MTD and associated megaturbidite48 (Fig. 4). Turbidites of strongly varying thicknesses (0.2 to ~ 30 cm) are frequently intercalated in the background sediments (Fig. 4, Supplementary Figs. 7–15). Of the event horizons within the studied interval, all but EH-F and EH-I can be reliably correlated to some of the thicker turbidites (Supplementary Fig. 16).
Within the studied interval comprising the last ~ 14,000 years, 90 events are present. Of these, 4 events have a very high, 8 have a high, 32 have an intermediate, 23 have a low and 23 events have a very low confidence level (Fig. 4). Hereinafter, the 44 events with an intermediate or higher confidence level will be referred to as earthquakes, as they meet the synchronicity criterion.
Few earthquakes (19) are recorded during the interval from ~ 2.8 to 14 ka BP, except for two intervals of temporally clustered earthquake occurrence at ca. 12.8 ka BP (high frequency period I; Fig. 5) and ca. 3.5 ka BP (high frequency period II). From ~ 2.8 ka BP onwards, an increased occurrence of earthquake-related event deposits can be observed. Sedimentation rate has been proposed as a main parameter governing subaquatic slope stability and therefore a lakes’ sensitivity to record earthquake shaking as mass-wasting induced turbidites55,56. However, no correlation between changes in sedimentation rate and event frequency can be found in our record. The only major shift in sedimentation rates (from ~ 0.25 to ~ 0.5 mm/year) occurred at about 5 ka BP—well before any rise in event frequency can be noticed. In contrast, the increase in recorded earthquakes coincides with the lithological change from stratigraphic unit II to unit III. Due to their low density and enhanced presence of air pockets (Supplementary Fig. 6), organic-rich sediments are relatively more prone to resuspension and erosion57, whereas increased carbonate content may increase sediment cohesion and strength58. We therefore attribute the increase of recorded earthquakes in the organic-rich unit III to a lowering of the EQRT compared to the calcite-rich unit II, rather than an increase of seismicity.
Of the 44 recorded earthquakes, 21 fall into the intensity range V ≤ I < VI, 12 into VI ≤ I < VII, 7 into VII ≤ I < VIII and 3 into VIII ≤ I < IX. However, as the EQRT is not stable throughout the cored time interval, the estimation of seismic intensities based on calibration with historical earthquake data can only be reliably applied to unit III. The intensities and/or number of recorded earthquakes in unit II are potentially underestimated due to an increased EQRT, leading to an “incomplete” record of moderate (I–V) and strong (I–VI) earthquakes before ~ 2.8 ka BP.
Earthquake recurrence statistics
Statistical analysis was carried out on events with an intermediate or higher earthquake trigger confidence level. Due to the presumed change in EQRT at ~ 2.8 ka BP, we treat units II and III separately and discard unit I because of the insufficient number of events (1).
In unit II, interevent time for I ≥ V averages at 608 ± 755 years (mean ± standard deviation of interevent times) and at 788 ± 1078 years for I ≥ VI (Fig. 6; Supplementary Table 4). The Gamma distribution with a shape parameter α < 1 shows the best fit for both intensity classes and indicates a bursty (clustered) recurrence pattern. Statistical tests suggest rejection of the exponential distribution and thus of a Poissonian process. In unit III, the average interevent time is 114 ± 94 years (I ≥ V) and the statistical tests do not allow rejection of the exponential distribution. Together with the best fitting distribution (Gamma with α = 1.45; see also Supplementary Fig. 17), this suggests an aperiodic (Poissonian) or weakly periodic recurrence pattern.
For the lower intensity classes (I > V and > VI), the 95% confidence intervals of the unit II datasets confirm the bursty character and a positive M. For the intensity class > VII, an aperiodic or bursty behaviour and a slightly negative M can be inferred. The small number of interevent times (N = 6) of this class, however, strongly affects the reliability of the B and M values, which therefore should not be interpreted. For the unit III datasets, an aperiodic or weakly periodic recurrence pattern is confirmed, but due to shorter interevent times, the effect of age uncertainty on B is larger (~ 18% and ~ 31% for the I ≥ V and I ≥ VI subsets, respectively). M is slightly positive for the I ≥ V subset, and scatters around 0 for the I ≥ VI subset, as does the running M (N = 11; Fig. 5). Because the number of interevent times is rather large in unit III (24), age uncertainty plays a smaller role13. The shortest interevent times found in unit III are 8 years, thus supporting the assumption that the lacustrine paleoseismic record only contains mainshocks. Given this and the record’s agreement with a Poissonian behaviour, the well-calibrated unit III, I ≥ V subset is comparable to the input data of PSHA in Austria and thus suited for the testing of the seismic hazard curve at Wörthersee.
Discussion
Testing seismic hazard curves with lacustrine paleoseismic records
To construct a seismic hazard curve based on our lacustrine data, we calculated the exceedance probability in 50 years (PoE50) of a certain intensity Ix by dividing the number of recorded events (I ≥ Ix) by the studied record span and multiplying by 50. The data show that PoE50 decreases exponentially with seismic intensity (Fig. 7). For the well-calibrated unit III, there is a ~ 31% probability of an I ≥ V½ event in a period of 50 years.
To test the seismic hazard curve of the Wörthersee area (site 46.623° N, 14.158° E) provided by ZAMG29, we converted the PGA values of the seismic hazard curve to intensity degrees using the ground motion to intensity conversion formula (GMICE) given by Faenza and Michelini (2010; FM10; using the coefficients of the double-line regression applicable to I ≥ V)59 and compared it with the PoE50 obtained from lake data (Fig. 7). The seismic rates in Carinthia are based on a catalogue of earthquakes which only generated I ≤ ~ V at Wörthersee. The lake data provides information on events with I ~ V–VIII and therefore constitutes an invaluable addition to the instrumental and historical dataset considered by the probabilistic approach. Our data show a very good agreement between both datasets, thus verifying the validity of the probabilistic seismic hazard analysis and the underlying models in the area of Wörthersee.
Potential uncertainties arise from the transformation of PGA (the PSHA outcome) into macroseismic intensities. Applying different GMICEs developed locally for the area of Switzerland60 or based on global compilations61 would move the seismicity-based hazard curve to lower left (lower hazard) and our lake data would suggest a higher hazard than on the seismic hazard map. However, FM1059 is also used to model the impact of large earthquakes in neighbouring countries as shakemaps39 and agrees with instrumentally-recorded PGA and documented macroseismic intensity in Austria for smaller intensity values. Altogether, we consider FM10 the most appropriate choice for our study area. Moreover, local parameters such as the presence of a sedimentary cover, bedrock slope and topographical irregularities can modify the amplitude, duration, and frequency-content of ground motion. For the comparison of lacustrine vs. probabilistic seismic hazard curve, we have used the original outcome of the PSHA which is related to soil class A (rock, VS30 > 800 m/s). As the intensity data points from historical earthquakes used for the calibration of the lacustrine sediments20 stem either from locations on rock or very dense sand or gravel, we consider this a reasonable assumption for our first-order approach. It is important to note that all mentioned intensity values relate to the lake surroundings and do not represent the level of ground motion on the lake bottom or slopes.
Implications for seismic hazard analysis
Lake paleoseismology provides independent data for testing a hazard map at one specific location. Since the output of PSHA is a collection of hazard curves at specific sites without spatial correlation, testing on a site level is the recommended approach by the seismologic community9,18. However, due to the very long time (especially in low-seismicity regions) required to observe a sufficient number of earthquakes at a site58, suitable earthquake records are rarely available. The calibrated paleoseismic record of Wörthersee provides suitable data to—for the first time ever to our knowledge—independently test the performance of seismic hazard analysis by a long-term record of seismic shaking. It confirms the applicability of time-independent probabilistic seismic hazard modelling in the area of Carinthia given the potentially Poissonian earthquake occurrence in the last ~ 2.8 ka of the record. Furthermore, the intensity-frequency relationship of earthquakes recorded in the Wörthersee sediments agrees with the seismic hazard curve, and thus validates the current PSHA approach for this part of Austria. The availability of suitable lake systems for paleoseismology in the European Alps62,63 provides a way forward to test the performance of national seismic hazard maps on multiple sites ranging from low (10% PoE50 of ~ 0.5 m/s2 in the Alpine foreland) to high hazards (10% PoE50 of ~ 2.5 m/s2 in the Friuli/Slovenia region). Together with other types of paleoseismic data, the lacustrine records also help to constrain the timing of specific paleo-earthquakes and to reconstruct plausible combinations of magnitudes and epicentre locations62,63. For instance, the earthquake recorded in Wörthersee at 10,966–9950 BP could potentially correspond to fault slip archived in speleothems of the Obir caves between 10,730 ± 230 and 8610 ± 150 BP64. A Mw of 5.5 and epicentral intensities of VIII to IX were proposed for this event64. Given the seismic intensity of ~ VII (or higher) at Wörthersee and typical intensity attenuation rates in the Alps65, this would imply a Mw of ~ 6–6.5 in case these paleoseismic data correlate. Although the age overlap is small, another speleothem damage dated between 6280 ± 240 and 5700 ± 1200 BP64 might correspond to the earthquake recorded in Wörthersee at 4767–4523 BP.
In other seismotectonic settings, i.e. at plate boundaries, it has been shown that frequency-magnitude data from instrumental seismicity may be offset from those of lake paleoseismic records66, because small-scale recent seismicity may not be representative for the seismic cycle of elastic strain build-up and release on major plate boundary faults. This highlights the importance of comparing (primary and secondary) paleoseismic data with instrumental seismicity data to obtain accurate input parameters for PSHA, by (1) testing the high-magnitude part of Gutenberg-Richter relationships, either for regional seismicity or individual faults, (2) constraining the maximum credible earthquake and (3) assessing the temporal distribution and recurrence pattern of large earthquakes.
Our lacustrine data, for instance, reveal non-stationarity during unit II and the possibility of seismic bursts (Fig. 5). Large positive Memory coefficients (~ 0.5) imply a tendency for short (long) interseismic time following short (long) interseismic time, and thus the bracketing of periods with different paleo-seismicity rate and behaviour. The high-frequency periods lead to exceptionally high values of B during unit II compared to most other lacustrine paleoseismic records worldwide (Moernaut67 and references therein). During the high frequency periods recorded in Wörthersee, the interevent times of two events with I > VI can be as short as ~ 8 years. More recent regional earthquake bursts are reported from the Austrian federal state of Tyrol68, with two events with I0 VIII and VII–VIII in 1670 and 1689, and the Italian region of Friuli69, where three main shocks of Mw 6.4, 6.1 and 5.3 occurred within 16 months in 1976–1977. Together with the identification of low paleo-seismicity periods (e.g. 5–11 ka BP) in the Wörthersee record, this suggests that seismic hazard in the Eastern European Alps might not always be constant, as assumed in classical PSHA, but can episodically increase. Incorporating such non-stationarity in the PSHA framework for Austria and its surrounding regions poses an important challenge to the hazard modelling community.
The causes of bursty lacustrine paleoseismic records can be manyfold. In slowly deforming regions, deformation is typically accommodated within a complex network of interacting faults10. Hence, a large area can be subject to near-critical stress conditions and small perturbations (i.e. earthquakes) have the potential to initiate rupture cascades, leading to regional seismic bursts separated by long, relatively quiescent intervals70. Depending on a lakes’ sensitivity to record seismic shaking, the potential source area of earthquakes that are archived in the lake sediments varies. A relatively high EQRT—as observed in Wörthersee before ~ 2.8 ka—restricts the sources contributing to the paleoseismic record to a few local, potentially interdependent faults, leading to a bursty lacustrine record with a highly positive memory coefficient. The more aperiodic recurrence behaviour and shorter recurrence times since ~ 2.8 ka are explained by the lower EQRT, and thus the inclusion of a larger number of remote fault sources over a larger region that rupture more independently.
Conclusions
We present an innovative method to test the validity of PSHA results using a lacustrine turbidite record. The Wörthersee record reveals 44 earthquakes over the last ~ 14 ka with local seismic intensities spanning ~ V to ~ X. The frequency-intensity curve based on the lacustrine data of the last ~ 2.8 ka validates the hazard curve of standard (time-independent) PSHA in the vicinity of Wörthersee. On longer timescales, however, clustered earthquake occurrence is observed, suggesting the need for a time-dependent component of PSHA in the Eastern Alps.
Our method provides means to evaluate the use of time-independency in hazard models and to test seismic hazard curves at specific map locations (i.e. lake sites). Because a tested magnitude-calibrated intensity prediction equation which covers strong earthquakes is not available in Austria, our approach relies on a GMICE to convert the output of standard PSHA (in PGA) to macroseismic intensity. Where possible, future work should (1) focus on multiple lake sites to assess the regional accuracy of seismic hazard maps and (2) compare the lacustrine paleoseismic data with intensity-based seismic hazard curves to reduce uncertainties. Thus, the quantitative lacustrine paleoseismic approach established in this paper can be an invaluable tool to independently test hazard maps in virtually any tectonic setting.
Data availability
Bathymetric data (1 m) can be downloaded from the dataserver of the Austrian ministry of finances: https://www.data.gv.at/katalog/dataset/106c4955-616d-4b11-97eb-8e4a64169306. All sediment core data as well as the 3.5 kHz reflection seismic data are available on zenodo: https://doi.org/10.5281/zenodo.6479186 and https://doi.org/105281/zenodo.7308844.
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Acknowledgements
This research was funded by the Austrian Science Fund (FWF), project number P30285-N34, the Austrian Academy of Sciences project “S4SLIDE-Austria”, and the European Regional Development Fund Interreg V-A Italy-Austria 2014-2020 (project ITAT3016-Armonia). CD acknowledges financial support from a research grant from the University of Innsbruck (Exzellenzstipendium für Doktoratskollegs) and JJSH is supported by FWF project M2727 and MOST (Ministry of Science and Technology, Taiwan) project 111-2116-M-002-013-MY3. IHS Markit is acknowledged for their educational grant program providing seismic interpretation software. We thank ETH Zurich (Adrian Gilli) for access to the Kullenberg coring system and platform, Irka Hajdas for radiocarbon analysis as well as Markus Erhardt, Gerald Degenhart and Wolfgang Recheis for medical CT measurements at the Medical University of Innsbruck. Ariana Molenaar, Patrick Oswald, Remo Röthlin and Reto Seifert, the Carinthian Institute of Lake Research (KIS) and the Research Department for Limnology (ILIM, Mondsee) are thanked for technical and logistical support during fieldwork. The multibeam data was kindly provided by the state of Carinthia (Land Kärnten, Abteilung Umwelt, Energie und Naturschutz). We thank Kris Vanneste and Helmut Hausmann for their valuable suggestions on an earlier version of the manuscript. We are grateful to three anonymous reviewers who helped to improve the manuscript and thank Neelima Satyam for the editorial handling.
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J.M., M.S. and C.D. designed the study and interpreted the results. C.D., J.M., M.S. and M.H. acquired lacustrine data. J.-J. S. H. acquired XRF scanning data. S. W. provided the probabilistic seismic hazard data of Austria. C.D. wrote the manuscript and produced the figures with input from all co-authors.
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Daxer, C., Huang, JJ.S., Weginger, S. et al. Validation of seismic hazard curves using a calibrated 14 ka lacustrine record in the Eastern Alps, Austria. Sci Rep 12, 19943 (2022). https://doi.org/10.1038/s41598-022-24487-w
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DOI: https://doi.org/10.1038/s41598-022-24487-w
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