The Kaali Impact as Trigger of a Mega-Tsunami Event and Violent Seismotectonics in Sweden

A meteorite impacted the ground in Estonia forming the Kaali Crater dated at 1183 - 1162 BC. It set up a Baltic-wide mega-tsunami dated at 1171 absolute varve years BC. It also triggered violent seismotectonic effect in Sweden. Ancient legends testify of direct observations of the sky phenomena and per-sonal experiences of the ground shaking and tsunami flooding, which makes the Kaali Crater the oldest impact event documented by humans. The Ragnarök apocalypse is likely to lead its origin from the violent geodynamic activity along the Swedish east coast.


Introduction
At about 1200 cal. yrs BC something quite unique occurred in the Baltic region: a meteorite impacted the ground on Saaremaa Island in Estonia giving rise to the Kaali Crater and 8 minor impact marks. At the same time along the Swedish east coast, we record high-magnitude paleoseismic activity, ground shaking with power of fracturing the bedrock, intensive methane venting tectonics, and the occurrence of a mega-tsunami with a run-up on the order of 15 m. In this paper, we propose that all the events occurred at the same time, and that the geodynamic events along the Swedish east coast were all triggered by the Kaali impact.

The Kaali Impact Crater
The Kaali Crater is located on the Silurian dolomite bedrock surface of Saaremaa Island in Estonia. The impact consists of a main crater and 8 minor impact marks. The main crater has a diameter of 60 m and a depth of 16 m, although the bedrock is deformed down to about 44 m ( Figure 1). The age of the Kaali crater has been debated and given either at around 7500 BP [2] [3] [4] or at 3500 -2500 BP [5] [6] [7].
The size of the impacting meteorite was estimated at around 450 tons hitting the ground with a velocity of about 15 km·s −1 and an energy release of about 4 × 10 12 J, corresponding to an explosion of 4 -20 kilotons of trotyl [7]. The trajectory has also been interpreted quite differently, viz. from the ENE [6] or from the SSE [3]. Nevertheless, the impact must have set up quite a severe shock-wave in the bedrock.
The light phenomenon in the sky, the sound at impact and the ground shaking must have struck the people with both fear and fascination. In fact, the Kaali impact coincides closely with an exceptional peak ( Figure 2) in geodynamic activity recorded at 13 sites along the Swedish east coast [8] [9] [10]. Ancient local legends vividly record both sky phenomena and violent ground shaking, which suggest that the Kaali Crater may be the oldest impact event recorded by humans [11], and potentially the best meteorite impact hazard event anywhere.
There is a clear relationship between the rate of glacial isostatic uplift and the  number of paleoseismic events [8] [12]. Figure 2 gives a histogram of the number of events per millennia for the last 13,000 years. There is a peak of paleoseismic events coinciding with the peak of glacial isostatic uplift at about 10,000 BP, after which there seems to be a generally decreasing trend with time (red line in Figure 2), except for a very surprising and abnormal second peak of 13 events at around 3000 BP. This peak calls for an explanation in other terms than normal seismotectonics of the area (grey field in Figure 2). In fact, it calls for a point event.  Figure 2) and the Kaali impact crater with proposed trajectories from the ENE [6] or the SSE [3]. The working hypothesis is that the Kaali impact triggered the seismotectonic effects recorded in Sites 1 -13.
The second peak at about 3000 BP refers to 13 sites consisting of four types of seismotectonic data ( Figure 2 and Figure 3), viz. earthquakes (orange), bedrock deformations from ground shaking (yellow), methane venting tectonics (purple) and tsunami records (blue).
The 13 sites (plus Sites 14 and 15, which seem to belong to the zone of "normal" paleosismic activity in Sweden; marked grey in Figure   Sites 14 and 15 in southern Sweden also refer to typical paleoseismic records. Those sites were regarded as "normal" paleoseismic events (belonging to the grey field in Figure 2), and were left out of the analysis of the 3000 BP peak in geodynamic events here discussed.
Heavy ground shaking with capacity of bedrock deformation was observed in Sites 2 and 3 [17] [18]. These events were interpreted as being generated by rapid phase-transitions of methane hydrate (accumulated in voids and fractures in the bedrock) into methane gas. This gave rise to explosive methane venting tectonics or MVT events. The Sites 5 and 12 MVT events are estimated to correspond to M 8.0 ground shaking events [16].
It is hereby proposed that the 3000 BP peak of seismotectonic events in Sweden and the Baltic-wide mega-tsunami event were all triggered by the Kaali Impact. The geographical distribution of events in Sweden is given in Figure 3.

Ancient Legends
The traumatic experiences of violent natural phenomena shaking the Earth and being observed in the sky are recorded in the Icelandic Edda [24] [25] and in the Finnish Kalevala Epos [26] [27]. Below follow a few quotations highlighting the vivid messages from the ancient oral tradition.
In Váluspá of the Edda, it is stated that: The sun blackens, the earth sinks into sea // Bright stars fall from heaven // Flames lash against life's support (Yggdrasil) // High gorges the heat against heaven itself. In Hyndla of the Edda, the sea flooding is spelled out: The sea storms against the heaven // Floods over the land. In Gylfaginning of the Edda, the earthquake shaking is well presented: The whole earth and the mountains quake // The trees are un-rooted and the mountains collapse // All bounds are broken and torn apart. International Journal of Astronomy and Astrophysics The Kalevala Epos is strongly focused on the extraordinary sky-phenomena.
In Song 47, we get the picture of what had happened: The high skies opened, the whole sky broke // Fire rushes through the sky, it shoots like a star shot // Lightens all across the skies, rushes through the clouds, and the wise old Väinämöinen spoke: Noble brother Ilmarinen // Let us go to find out, let us go and see // What sort of fire that occurred, what sort of spark that was seen // Gliding fast from the high skies, all the way down into the ground.

Ragnarök
With the new geological data here presented, there now seems to be logical rea-  Figure 4).

Discussion
The time coincidence, geodynamic coupling, tsunami dimension and legend background need some additional discussion.
The exact age of the Kaali Crater has been a matter of debate [2] [3] [5] [6] [7] [35]. The span of uncertainty is from about 1000 to 1700 cal. yrs BC (or about 2850 to 3300 BP). Secondly, the mode of sedimentary infill of the crater basin needs reconsideration. According to Veski et al. [6], the crater was "an empty hole" after the impact, into which "loose material was gradually washed to the bottom of the cra- ter". The Baltic-wide tsunami documented in Sweden, is likely also to have invaded the crater and deposited a mixed material at its base, which seems to fit well with the description by Veski et al. [6] of the basal sediments: a "dolomite diamicton (unsorted sediment that contains a wide range of particle sizes from clay to gravel)" and calcareous gyttja with eroded diatoms. At the base of core 1, there is a peat [35] dated at 3390 ± 35 BP or 1680 ± 60 cal. yrs BP. It seems quite strange to have "peat" at the base of the crater-lake. Rather does it indicate the inflow from re-deposited peaty material of pre-impact age. If so, the age of the impact post-dates the age of the peat. Only 3 dates come from the base of core 2 ( Figure 1); sample 1 (1600 ± 90 cal. yrs BC) comes from the top of the carbonate rich diamicton, sample 2 (1025 ± 105 cal. yrs BC) was taken 3 cm up in the lake gyttja, sample 3 (915 ± 85 cal. yrs BC) is from the detrital gyttja and must be too young.
In order to provide a better dating analysis, Duffy kindly constructed an Ox-Cal Poissonian depositional sequence model (P_sequence). This model ( This value is in perfect agreement with the absolute varve date of 1171 BC, obtained of the tsunami event in Site 4. It also agrees well with the zone of dates referring to "at about" the event ranging from 1300 to 1060 cal. yrs BC or 1180 ± 120 cal. yrs BC (above). Figure 5 illustrates the excellent agreement between the date of the Kaali Crater and the tsunami dates in Sweden, where the absolute varve date of 1171 BC stands out as exceptional. By this, the time coincidence between the impact and the geodynamic effects in Sweden seems settled. The geodynamic coupling between impact forces and seismotectonic effects in Sweden (a distance of up to 400 km to Site 1 and 160 km to Site 11) is another prime issue.
Earthquakes and ground shaking have been recorded at far distances from historical impact events. The Tunguska event in 1908 generated an M 4.7 earthquake [36] with a seismic wave over 5300 km [37]. At the Chelyabinsk impact event in 2013, the seismic ground shaking was recorded "at least up to 4000 km away" [37], and the authors concluded that "distant seismic recording can agree remarkably well with local meteor observations".
Methane venting tectonics (MVT) seem sometimes to have been generated over very long distances [9]; at the Saguenay M 5.9 earthquake in Canada in 1988, violent methane venting was observed 800 km to the SW, and at the M 7.7 earthquake in Pakistan in 2013, methane venting tectonics occurred 400 km to the south. In both these cases, it seems to have been the seismic shock waves in the crust that set up the MVT events [9]. A recent MVT event seems to have been recorded in Timor in 2018 [38]: the locals heard a strong explosion, found a former bedrock fractured into pieces and gas venting from the ground ( Figure  6). The gas was burning (obviously set on fire by sparks from the colliding bedrock fragments (cf. [18]). Figure 6. View of the Timor 2018 event with fractured bedrock and burning methane degassing [38], a recent example of methane venting tectonics [9] and burning gas [18].
Actual MVT was only observed in Sites 5, 7, 11, 12. The ground-shaking effect of the MVT-event at Sites 5 and 12 were estimated at M 8.0 [16]. Such a high ground shaking may well explain the deformational effects observed in Sites 1, 2, 3, 7, 10, and 11.
The tsunami events are observed in 11 of the 13 sites. The tsunami wave-height or run-up height is now established at values ranging from 10 to 16.5 m (above). This rules out a sequence of local events, in favour of one big Baltic-wide event.
Either we may be dealing with an atmospheric shock wave (meteo-tsunami; [37] [39]) induced by the impact, or a normal tsunami generation of an impact hitting the Baltic Sea. The dimension of the Kaali Crater (60 -100 m wide and 16 m deep) and its elevation (+22 m) shed some doubt that this impact would be strong enough to generate the mega-tsunami and the seismotectonic effects observed in Sweden. Therefore, it seems probable that a hitherto unknown larger meteor fragment fell directly into the Baltic Sea somewhere between Estonia and Sweden ([1] Figures 25-26).
For the history of impact events [11], it seems important that the Kaali impact event may now be considered the oldest event observed and recorded by humans. Previously, the oldest events were the 616 BC and 645 BC events in China [11].

Conclusions
The ice cover in the European Arctic Seas affects the biologic productivity and the Kaali crater represents an important event. Available radiocarbon dates were reinterpreted according to the OxCal Poissonian depositional sequence model providing an age of 1183 -1162 cal. yrs BC for the onset of sedimentation in the crater ([1] p. 2). This is co-incidental with the date of the mega-tsunami in Sweden, absolutely dated by varves at 1171 varves BC.
The 13 sites in Sweden bear witness of severe ground shaking, seismotectonics and methane venting tectonics. They all occur at the same time as the mega-tsunami, and can hence be directly coupled to the Kaali impact.
It is concluded that the Kaali impact ( Figure 1) triggered the 13 deformational events recorded in Sweden ( Figure 2) at 1171 absolute years BC (1183 -1162 cal. yrs BC for the Kaali crater), and that all this became mixed into ancient legends because it terrified and fascinated the local people. Hence, the Kaali impact event may be considered the oldest event observed and recorded by humans.