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Minoan eruption

December 13, 2023

The Minoan eruption was a catastrophic volcanic eruption that devastated the Aegean island of Thera (also called Santorini) circa 1600 BCE.[2][3] It destroyed the Minoan settlement at Akrotiri, as well as communities and agricultural areas on nearby islands and the coast of Crete with subsequent earthquakes and paleotsunamis.[4] With a VEI magnitude of a 6, resulting in an ejection of approximately 28–41 km3 (6.7–9.8 cu mi) of dense-rock equivalent (DRE),[5][1] the eruption was one of the largest volcanic events in human history.[6][7][8] Since tephra from the Minoan eruption serves as a marker horizon in nearly all archaeological sites in the Eastern Mediterranean,[9] its precise date is of high importance and has been fiercely debated among archaeologists and volcanologists for decades,[10][11] without coming to a definite conclusion.

Minoan eruption of Thera
Satellite image of Thera, November 21, 2000. The bay in the center of the island is the caldera created by the Minoan eruption.
VolcanoThera
Datec. 1600 BCE (see below)
TypeUltra Plinian
LocationSantorini, Cyclades, Aegean Sea
36°24′36″N 25°24′00″E / 36.41000°N 25.40000°E / 36.41000; 25.40000
VEI6[1]
ImpactDevastated the Minoan settlements of Akrotiri, the island of Thera, communities and agricultural areas on nearby islands, and the coast of Crete with related earthquakes and tsunamis.
Thera

Although there are no clear ancient records of the eruption, its plume and volcanic lightning may have been described in the Egyptian Tempest Stele.[12] The Chinese Bamboo Annals reported unusual yellow skies and summer frost at the beginning of the Shang dynasty, which may have been a consequence of volcanic winter (similar to 1816, the Year Without a Summer, after the 1815 eruption of Mount Tambora).[13]

Eruption edit

 
Volcanic craters on Santorini, June 2001

Background edit

Main article: Santorini caldera

Geological evidence shows the Thera volcano erupted numerous times over several hundred thousand years before the Minoan eruption. In a repeating process, the volcano would violently erupt, then eventually collapse into a roughly circular seawater-filled caldera, with numerous small islands forming the circle. The caldera would slowly refill with magma, building a new volcano, which erupted and then collapsed in an ongoing cyclical process.[14]

Immediately before the Minoan eruption, the walls of the caldera formed a nearly continuous ring of islands, with the only entrance between Thera and the tiny island of Aspronisi.[14] This cataclysmic eruption was centered on a small island just north of the existing island of Nea Kameni in the centre of the then-existing caldera. The northern part of the caldera was refilled by the volcanic ash and lava, then collapsed again.

Magnitude edit

The magnitude of the eruption, particularly the submarine pyroclastic flows, has been difficult to estimate because the majority of the erupted products were deposited in the sea. Together, these challenges result in considerable uncertainty regarding the volume of the Minoan eruption, with estimates ranging between 13–86 km3 (3.1–20.6 cu mi) DRE.[15][16]

According to the latest analysis of marine sediments and seismic data gathered during ocean research expeditions from 2015 to 2019, the estimated volume of the material expelled during the volcanic eruption ranges from 28–41 km3 (6.7–9.8 cu mi) DRE.[1]

The study revealed that the initial Plinian eruption was the most voluminous phase, ejecting 14–21 km3 (3.4–5.0 cu mi) magma and accounting for half of total erupted materials. This was followed by 3–4 km3 (0.72–0.96 cu mi) DRE co-ignimbrite fall, 5–9 km3 (1.2–2.2 cu mi) DRE pyroclastic flows and 5–7 km3 (1.2–1.7 cu mi) DRE intra-caldera deposits.[1]

This eruption is comparable with the Mount Tambora volcanic eruption of 1815, Mount Samalas eruption of 1257, Lake Taupo's Hatepe eruption around 230 CE, and the Paektu Mountain eruption of 946 CE, which are among the largest eruptions during the Common Era.[6][7]

Sequence edit

On Santorini, there is a 60 m (200 ft) thick layer of white tephra that overlies the soil clearly delineating the ground level before the eruption. This layer has three distinct bands that indicate the different phases of the eruption.[17] Studies have identified four major eruption phases, and one minor precursory tephra fall. The thinness of the first ash layer, along with the lack of noticeable erosion of that layer by winter rains before the next layer was deposited, indicate that the volcano gave the local population a few months' warning. Since no human remains have been found at the Akrotiri site, this preliminary volcanic activity probably caused the island's population to flee. It is also suggested that several months before the eruption, Santorini experienced one or more earthquakes, which damaged the local settlements.[18][19][20]

 
Early phase of Late-Bronze-Age volcano eruption (~ 1500 BC), southern border of the Caldera island. The lower layer of pumice is finer, almost white and without rock intrusions.

Intense magmatic activity of the first major phase (BO1/Minoan A)[21] of the eruption deposited up to 7 m (23 ft) of pumice and ash, with a minor lithic component, southeast and east. Archaeological evidence indicated burial of man-made structures with limited damage. The second (BO2/Minoan B) and third (BO3/Minoan C) eruption phases involved pyroclastic surges and lava fountaining, as well as the possible generation of tsunamis. Man-made structures not buried during Minoan A were completely destroyed. The third phase was also characterized by the initiation of caldera collapse. The fourth, and last, major phase (BO4/Minoan D) was marked by varied activity: lithic-rich base surge deposits, lava flows, lahar floods, and co-ignimbrite ash-fall deposits. This phase was characterized by the completion of caldera collapse, which produced megatsunamis.[21][22]

Geomorphology edit

 
Mansions and hotels atop steep cliffs.

Although the fracturing process is not yet known, the altitudinal statistical analysis indicates that the caldera had formed just before the eruption. The area of the island was smaller, and the southern and eastern coastlines appeared regressed. During the eruption, the landscape was covered by the pumice sediments. In some places, the coastline vanished under thick tuff depositions. In others, recent coastlines were extended towards the sea. After the eruption, the geomorphology of the island was characterized by an intense erosional phase during which the pumice was progressively removed from the higher altitudes to the lower ones.[23]

Volcanology edit

The eruption was of the Ultra Plinian type, and it resulted in an estimated 30 to 35 km (19 to 22 mi) high eruption column which reached the stratosphere. In addition, the magma underlying the volcano came into contact with the shallow marine embayment, resulting in violent phreatomagmatic blasts.

The eruption also generated 35 to 150 m (115 to 492 ft) high tsunamis that devastated the northern coastline of Crete, 110 km (68 mi) away. The tsunami affected coastal towns such as Amnisos, where building walls were knocked out of alignment. On the island of Anafi, 27 km (17 mi) to the east, ash layers 3 m (10 ft) deep have been found, as well as pumice layers on slopes 250 m (820 ft) above sea level.

Elsewhere in the Mediterranean are pumice deposits that could have been sent by the Thera eruption. Ash layers in cores drilled from the seabed and from lakes in Turkey show that the heaviest ashfall was towards the east and northeast of Santorini. The ash found on Crete is now known to have been from a precursory phase of the eruption, some weeks or months before the main eruptive phases, and it would have had little impact on the island.[24] Santorini ash deposits were at one time claimed to have been found in the Nile delta,[25] but this is now known to be a misidentification.[26][27]

Eruption dating edit

The Minoan eruption is an important marker horizon for the Bronze Age chronology of the Eastern Mediterranean realm. It provides a fixed point for aligning the entire chronology of the second millennium BCE in the Aegean, as evidence of the eruption is found throughout the region. Yet, archaeological dating based on typological sequencing and the Egyptian chronology is significantly younger than the radiocarbon age of Minoan eruption, by roughly a century. This age discrepancy has resulted in a fierce debate about whether there is an upheaval in the archaeological synchronization between the Aegean and Egypt.[28]

Archaeology edit

Archaeologists developed the Late Bronze Age chronologies of eastern Mediterranean cultures by analyzing design styles of artifacts found in each archaeological layer.[29] If the type of artifacts can be accurately assigned, then the layer's position in a chronological order can be determined. This is known as sequence dating or seriation. In Aegean chronology, however, frequent exchange of objects and styles enables relative chronology be compared with absolute chronology of Egypt, so absolute dates could be determined in Aegean.

Since Minoan eruption has been conclusively placed in late/end Late Minoan IA (LM-IA) in the Crete chronology, late/end Late Helladic I (LH-I) in the mainland chronology,[30][31][32] the contention is what Egyptian period was contemporaneous with LM-IA and LM-IB. Decades of intensive archaeological work and seriation on Crete in the last century had confidently correlated the late LM-IA with Dynasty XVIII in Egypt and the end of LM-IA at the start of Thutmose III.[31] Stone vessels discovered in the Shaft Graves in LH-I are also of New Kingdom type. Multiple archaeological sites of Theran pumice workshop used by the local inhabitants are only found in the New Kingdom strata. A milk bowl on Santorini used before volcanic eruption has pottery style of only that of New Kingdom.[28] Egyptian inscription on the Ahmose Tempest Stele recorded an extraordinary cataclysm resembling the Minoan eruption.[33] Taken together, the archaeological evidence points to an eruption date after the accession of Ahmose I. The year of accession based on the conventional Egyptian chronology and radiocarbon-based chronology are 1550 BCE[34] and 1570–1544 BCE (IntCal04)[35] or 1569–1548 BCE (IntCal20).[36] The massive archaeological evidence argues for a Theran eruption date between circa 1550–1480 BCE.[37]

Proponents of earlier date dispute that Aegean-Egypt pottery correlation allows considerable flexibility. Several other archaeological interpretations of LM-IA and LM-IB pottery differ from the "traditional" and could be consistent with a much earlier beginning time for LM-IA and LM-IB.[38][39][40] Pottery synchronisms was also assessed to be less secure before the LM-IIIAI/Amenhotep III period.[41] Pumice in workshop and inscription on Tempest Stele have been argued to only reflect lower bound of eruption age. The date of production of pottery with Santorini milk bowl style in other regions has not been determined and could pre-date Minoan eruption. The chronology of stone vessel styles during this critical period is lacking.[42][43]

Radiocarbon age edit

Raw radiocarbon dates are not accurate calendar years of the event and this has to do with the fact that the level of atmospheric radiocarbon fluctuates. Raw radiocarbon ages can be converted to calendar dates by means of calibration curves which are periodically updated by international researchers. Derived calibrated calendar date ranges are highly dependent on how accurately calibration curve represents radiocarbon levels for the time period. As of 2022, the most updated calibration curve is IntCal20.[44] Early radiocarbon dates in the 1970s with calibration were already showing massive age disagreement and were initially discarded as unreliable by the archaeological community.[39] In the following decades, the range of possible eruption date narrowed significantly with improved calibration, analytical precision, statistical method and sample treatment. Radiocarbon dating has built a strong case for an eruption date in the late 17th century BCE. The table below summarizes the history and results of radiocarbon dating of volcanic destruction layer with pre-2018 calibration curves:

List of radiocarbon dates with calibration curve published before 2018
Source Calibrated date (95% CI) Calibration used Sample context and statistical method
Hammer et. al., 1987[45] 1675–1525 BCE Pearson and Stuiver, 1986 [46] Weighted average of 13 samples from volcanic destruction layer at Akrotiri (VDL)
Ramsey et. al., 2004[47] 1663–1599 BCE INTCAL98[48] Bayesian model of sequence of samples from before, during and after eruption
Manning et. al., 2006[49] 1683–1611 BCE IntCal04[50] Bayesian model of sequence of samples from before, during and after eruption
Friedrich et. al., 2006[51] 1627–1600 BCE IntCal04[50] Wiggle-matching of olive tree buried alive in pumice layer
Manning et. al., 2010[52] 1660–1611 BCE IntCal09[53] Bayesian model of sequence of samples from before, during and after eruption
Höflmayer et. al., 2012[42] 1660–1602 BCE

1630–1600 BCE (2)

IntCal09[53] Tau boundary function on 28 samples from VDL

Wiggle-matching of olive tree buried alive in VDL (2)

Pearson etl. al., 2018[54] 1664–1614 BCE

1646–1606 BCE (2)

1626–1605 BCE (3)

IntCal13[55] Weighted average of 28 samples from VDL

Tau boundary function on the 28 samples from VDL (2)

Wiggle-matching of olive tree buried alive in pumice layer (3)

In 2018, a team led by tree ring scientist reported a possible offset of a few decades in the previous IntCal calibration curves during the period 1660–1540 BCE. The resulted new calibration curve allowed previous raw radiocarbon dates be calibrated to encompass a substantial part of 16th century BCE, making it possible for radiocarbon dates to be compatible with archaeological evidence.[54] The measured offset was then confirmed by other laboratories across the world and incorporated into the most updated calibration curve IntCal20.[56][57][58] In the same year, study of bomb peak further questioned the validity of wiggle-matching of olive branch because the radiocarbon dates of outermost branch layer could differ by up to a few decades caused by growth cessation, then the olive branch could also pre-date Thera by decades.[59]

In 2020, speculation of regional offset specific to Mediterranean context in all calibration curves was reported based on measurements made on juniper wood at Gordion. If the regional offset is genuine, then calibration based on the regional dataset, Hd GOR, would place eruption date back to 17th century BCE.[60] Others have argued that these site-specific offsets are already incorporated into the IntCal20 prediction interval since it is constructed from a much wider range of locations and any locational variation is of similar magnitude to the inter-laboratory variation.[61][62]

While the refined calibration curve IntCal20 does not rule out a 17th century BCE eruption date, it does shift the probable range of eruption date to include the majority of 16th century BCE, offering a way to at least mitigate the long-standing age disagreement. However, the exact year of eruption has not been settled. The table below summarizes the dating results:

List of volcanic destruction layer (VDL) radiocarbon dates with calibration curve published after 2018
Source Calibrated date (posterior probability) Calibration used Sample context and statistical method
Manning et. al., 2020[60] 1663–1612 BCE (87.5%) Hd GOR[36] Bayesian model of sequence of samples from before, during and after eruption
Manning et. al., 2020[36] 1619–1596 BCE (64.7%)

1576–1545 BCE (22.9%)

IntCal20[44] Bayesian model of sequence of samples from before, during and after eruption
Şahoğlu et. al., 2022[63] 1612–1573 BCE (19.4%)

1565–1501 BCE (76.1%)

IntCal20[44] The youngest sample near victims from Theran tsunami layer at Çeşme
Ehrlich et al., 2021[64] 1624–1528 BCE IntCal20[44] Eight scenarios of olive wood growth to account for possible growth cessation
Manning, 2022[65] 1609–1560 BCE (95.4%) IntCal20[44] Bayesian model of sequence of samples from before, during and after eruption but more comprehensive to include samples from VDL, tsunami and distal fallout from across southern Aegean region
Pearson et. al., 2023[66] 1610–1510 BCE (95.4%)

1602–1502 BCE (95.4%)

IntCal20[44] Therasia olive shrub

Ice cores, tree rings and speleothems edit

An eruption of Theran magnitude is expected to leave detectable signal in various environmental records like ice core and tree ring. Petrologic constraints on Minoan magma yields a range of 0.3–35.9 trillion grams of sulfur release. The higher end of the estimate could cause severe climatic change and leave detectable signals in ice cores and tree rings.[67] Notably, tree ring dating allows extremely precise dating to the exact calendar year of each ring with virtually no age uncertainty, and from properties of the annual tree rings local climate record could be reconstructed down to sub-annual precision.

In 1987, a major Greenland sulfate spike in 1644 ± 20 BCE in ice core chronology was hypothesized to be caused by the Minoan eruption based on the early radiocarbon results of Hammer et. al.[45] In 1988, a major environmental disruption and extreme global-cooling/frost-ring in 1627 ± 0 BCE were also revealed through precisely dated frost ring and too were hypothesized to be related to Minoan eruption.[68][69][70]

Archaeologists who preferred late 16th century BCE eruption date were neither convinced by the 1644 ± 20 BCE sulfate spike nor by the 1627 BCE frost ring because evidence of causality between the two events and Minoan eruption was absent.[31]

Since 2003, multiple independent studies of major elements and trace elements of volcanic ash retrieved from the 1644 ± 20 BCE sulfate layer failed to match the ash to that of Santorini[24] but all attributed the ash to another large eruption during this period, Mount Aniakchak, thus ruling out Minoan eruption as the cause of the sulfate spike.[71][72][73][74] In 2019, revision of Greenland ice core chronology was proposed based on synchronization of frost-ring data and major sulfate spike, and the revised date for Aniakchak eruption was shifted to 1628 BCE.[75] The Greenland ice core chronology offset was independently confirmed by other teams[74][76] and adopted into Greenland Ice Core Chronology 2021 (GICC21).[77] The 1627 BCE extreme global cooling was then conveniently explained by the major Aniakchak eruption without invoking Thera. An eruption date of 1627 BCE is also no longer supported by radiocarbon evidence with the most recent calibration curve IntCal20.[74]

In light of much younger radiocarbon dates and revised ice core chronology, several possible ice core and tree ring signals in the 17th and 16th century BCE have been proposed.[74][78][79] The list below summarizes the tree ring and ice core signals that may have been caused by the Minoan eruption:

List of proposed Minoan eruption dates suggested by environmental anomalies
Date Environmental context Records Ref
1681–1673 BCE Tree ring increases of sulfur, calcium, and rare earth elements in Mediterranean tree ring 857, possibly caused by volcanic eruption in this region [80][81]
1654 BCE Ice core and tree ring one of largest sulfate spikes recorded in Greenland in the last 4,000 years, estimated 50 trillion grams of sulfur; frost-damaged ring in 1653 BCE followed by ring-width minima in 1652 BCE [74][79]
1649 BCE Tree ring ring-width minima [79]
1619 BCE Tree ring narrow ring [79]
1611 BCE Ice core sulfate spike, estimated 2–8 trillion grams of sulfur [74]
1597 BCE Tree ring ring-width minima [79]
1561 BCE Ice core and tree ring large sulfate spike, estimated 22 trillion grams of sulfur; ring growth reduced in 1560 BCE; calcium depletion in Mediterranean tree ring in 1560 BCE possibly caused by volcanic eruption in this region [74][54]
1558 BCE Ice core sulfate spike, estimated 10 trillion grams of sulfur [74]
1555 BCE Ice core and tree ring sulfate spike, estimated 6 trillion grams of sulfur; reduced ring growth in 1554 BCE [74]
1546 BCE Tree ring reduced tree ring growth [54]
1544 BCE Tree ring ring-width minima [54]
1539 BCE Ice core sulfate spike, estimated 6 trillion grams of sulfur [74]
1524 BCE Tree ring ring-width minima [79]

The date of Minoan eruption does not necessarily have to be in one of the years listed in the table, because the eruption may not have been environmentally impactful enough to leave any detectable signal.[65]

In addition, a stalagmite from Turkey shows bromine peaks at 1621 ± 25 BCE, molybdenum at 1617 ± 25 BCE and sulfur at 1589 ± 25 BCE. The authors interpreted that all three peaks were caused by a single volcanic eruption in the Mediterranean region and the time difference was related to differences in their retention rates.[82] Others have suggested that the sulfur peak may have been related to the 1561 BCE chemical anomaly recorded in Mediterranean tree rings.[54]

Historical impact edit

Minoan sites edit

 
Excavation of Akrotiri on Thera
 
The only gold object found at the excavation of Akrotiri, a small sculpture of an ibex that was hidden under a floor; a thorough evacuation in advance of the catastrophe must have occurred since few artifacts and no corpses were buried in the ash.

The eruption devastated the nearby Minoan settlement at Akrotiri on Santorini, which was entombed in a layer of pumice.[83] It is believed that the eruption also severely affected the Minoan population on Crete, but the extent of the impact is debated. Early hypotheses proposed that ashfall from Thera on the eastern half of Crete choked off plant life, causing starvation of the local population.[84] After more thorough field examinations, the hypothesis has lost credibility, as it has been determined that no more than 5 mm (0.20 in) of ash fell anywhere on Crete.[85] Other hypotheses have been proposed based on archaeological evidence found on Crete indicating that a tsunami, likely associated with the eruption, impacted the coastal areas of Crete and may have devastated the Minoan coastal settlements.[86][4][87][88] Another hypothesis is that much of the damage done to Minoan sites resulted from a large earthquake and the fires it caused, which preceded the Thera eruption.[89][90]

Significant Minoan remains have been found above the Thera ash layer and tsunami level dating from the Late Minoan I era, and it is unclear whether the effects of the ash and tsunami were enough to trigger the downfall of the Minoan civilization. Some sites were abandoned or settlement systems significantly interrupted in the immediate aftermath of the eruption.[88] Some archaeologists speculate that the eruption caused a crisis in Minoan Crete, opening it to Mycenaean influence or even conquest.[4]

Chinese records edit

A volcanic winter from an eruption in the late 17th century BCE has been claimed by some researchers to correlate with entries in later Chinese records documenting the collapse of the semi-legendary Xia dynasty in China. According to the Bamboo Annals, the collapse of the dynasty and the rise of the Shang dynasty, approximately dated to 1618 BCE, were accompanied by "yellow fog, a dim sun, then three suns, frost in July, famine, and the withering of all five cereals".[13]

Effect on Egyptian history edit

Further information: Ahmose I § Dates and length of reign

Apocalyptic rainstorms, which devastated much of Egypt, and were described on the Tempest Stele of Ahmose I, have been attributed to short-term climatic changes caused by the Theran eruption.[91][92][93] The dates and regnal dates of Ahmose I are in some dispute with Egyptologists (leaving aside alternate chronologies). Proposed reigns range from 1570–1546 BCE to 1539–1514 BCE. A radiocarbon dating of his mummy produced a mean value of 1557 BCE. In any case this would only provide an overlap with the later estimates of eruption date.[94]

Alternatively, if the eruption occurred in the Second Intermediate Period, the absence of Egyptian records of the eruption could be caused by the general disorder in Egypt around that time.

While it has been argued that the damage attributed to these storms may have been caused by an earthquake following the Thera eruption, it has also been suggested that it was caused during a war with the Hyksos, and the storm reference is merely a metaphor for chaos upon which the Pharaoh was attempting to impose order.[95] Documents such as Hatshepsut's Speos Artemidos depict storms, but are clearly figurative, not literal. Research indicates that the Speos Artemidos stele is a reference to her overcoming the powers of chaos and darkness.[95]

Greek traditions edit

See also: Deucalion § Dating by early scholars

The Titanomachy edit

The eruption of Thera and volcanic fallout may have inspired the myths of the Titanomachy in Hesiod's Theogony.[96] The Titanomachy could have picked up elements of western Anatolian folk memory, as the tale spread westward. Hesiod's lines have been compared with volcanic activity, citing Zeus's thunderbolts as volcanic lightning, the boiling earth and sea as a breach of the magma chamber, immense flame and heat as evidence of phreatic explosions, among many other descriptions.[97]

Atlantis edit

Main article: Location hypotheses of Atlantis

Spyridon Marinatos, the discoverer of the Akrotiri archaeological site, suggested that the Minoan eruption is reflected in Plato's story of Atlantis. However, this view is not supported by current scholarship.[98][99][100][101]

Book of Exodus edit

Geologist Barbara J. Sivertsen seeks to establish a link between the eruption of Santorini (c. 1600 BCE) and the Exodus of the Israelites from Egypt in the Bible.[20]

Bicameral mentality edit

In the controversial bicameral mentality hypothesis, Julian Jaynes has argued that the Minoan eruption was a crucial event in the development of human consciousness[102] since the displacements that it caused led to new and important interactions among communities.

See also edit

References edit

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  95. ^ a b Wiener, MH; Allen, JP (1998). "Separate Lives: The Ahmose Tempest Stela and the Theran Eruption". Journal of Near Eastern Studies. University of Chicago Press. 57: 1–28. doi:10.1086/468596. S2CID 162153296.
  96. ^ Greene, MT (2000). Natural Knowledge in Preclassical Antiquity. Johns Hopkins University Press. ISBN 978-0-8018-6371-4.[page needed]
  97. ^ Luce, John Victor (1969). The end of Atlantis: New light on an old legend. New Aspects of Antiquity. London: Thames & Hudson. ISBN 978-0-500-39005-4.[page needed]
  98. ^ Marinatos, Spyridon (1972). Some Words about the Legend at Atlantis (2nd ed.). Athens: C. Papachrysanthou.
  99. ^ Neer, Richard (2012). Art and Archaeology of the Greek World. Thames and Hudson. p. 37. ISBN 978-0-500-05166-5. "...popular associations of the eruption with a legend of Atlantis should be dismissed...nor is there good evidence to suggest that the eruption...brought about the collapse of Minoan Crete
  100. ^ Manning, Stuart (2012). "Eruption of Thera/Santorini". In Cline, Eric (ed.). The Oxford Handbook of the Bronze Age Aegean. Oxford University Press. pp. 457–454. doi:10.1093/oxfordhb/9780199873609.013.0034. ISBN 978-0199873609. Marinatos (1939) famously suggested that the eruption might even have caused the destruction of Minoan Crete (also Page 1970). Although this simple hypothesis has been negated by the findings of excavation and other research since the late 1960s... which demonstrate that the eruption occurred late in the Late Minoan IA ceramic period, whereas the destructions of the Cretan palaces and so on are some time subsequent (late in the following Late Minoan IB ceramic period)
  101. ^ Brouwers, Josho (2021). "Did Atlantis Exist?". Bad Ancient. Retrieved August 30, 2023.
  102. ^ Jaynes, Julian (1976). The Origin of Consciousness in the Breakdown of the Bicameral Mind. Boston, MA: Houghton Mifflin Co. p. 479. ISBN 0547527543.

Further reading edit

  • Bietak, M (2004). "Review – 'A Test of Time' by S. W. Manning (1999)" (PDF). Bibliotheca Orientalis. 61: 199–222. Retrieved 2008-04-21.
  • Callender, G (1999). The Minoans and the Mycenaeans: Aegean Society in the Bronze Age. Oxford University Press. ISBN 0-19-551028-3.
  • Forsyth, PY (1997). Thera in the Bronze Age. Peter Lang Publishing. ISBN 0-8204-4889-3.
  • Friedrich, WL (1999). Fire in the Sea, the Santorini Volcano: Natural History and the Legend of Atlantis. Cambridge University Press. ISBN 0-521-65290-1.
  • [1]Lespez, Laurent, et al., "Discovery of a tsunami deposit from the Bronze Age Santorini eruption at Malia (Crete): impact, chronology, extension", Scientific reports 11.1, 2021
  • Notti, Erika, "The Theran Epigraphic Corpus of Linear A : Geographical and Chronological Implications", Pasiphae, vol. 000, no. 004, pp. 93-96, 2010
  • Notti, Erika, "Writing in Late Bronze Age Thera. Further Observations on the Theran Corpus of Linear A", Pasiphae, vol. 000, no. 015, 2021 ISSN: 2037-738X
  • Page, D. L. (1970). The Santorini Volcano and the Destruction of Minoan Crete. The Society for the Promotion of Hellenic Studies, London.
  • Warren PM (2006). "The date of the Thera eruption". In Czerny E, Hein I, Hunger H, Melman D, Schwab A (eds.). Timelines: Studies in Honour of Manfred Bietak. Orientalia Lovaniensia Analecta 149. Louvain-la-Neuve, Belgium: Peeters. pp. 2: 305–21. ISBN 90-429-1730-X.

External links edit

  • Statistical analysis aims to solve Greek volcano mystery - David Nutt - Phys.org - September 20, 2022
  • Researchers home in on Thera volcano eruption date - Mikayla MacE Kelley - Phys.org May 2, 2022
  • Santorini Decade Volcano – Santorini's geology and volcanic history, the Minoan eruption and the legend of Atlantis.
  • – A WWW companion site to: Sturt W. Manning, A Test of Time: the volcano of Thera and the chronology and history of the Aegean and east Mediterranean in the mid second millennium BC.
  • VolcanoWorld Information about the eruption with photographs
  • – exploration of the submarine deposits and morphology of Santorini volcano
  • – Online doctoral thesis on the eruption, scientific analyses and its environmental effects (by David A. Sewell, 2001)

December 13, 2023
minoan, eruption, catastrophic, volcanic, eruption, that, devastated, aegean, island, thera, also, called, santorini, circa, 1600, destroyed, minoan, settlement, akrotiri, well, communities, agricultural, areas, nearby, islands, coast, crete, with, subsequent,. The Minoan eruption was a catastrophic volcanic eruption that devastated the Aegean island of Thera also called Santorini circa 1600 BCE 2 3 It destroyed the Minoan settlement at Akrotiri as well as communities and agricultural areas on nearby islands and the coast of Crete with subsequent earthquakes and paleotsunamis 4 With a VEI magnitude of a 6 resulting in an ejection of approximately 28 41 km3 6 7 9 8 cu mi of dense rock equivalent DRE 5 1 the eruption was one of the largest volcanic events in human history 6 7 8 Since tephra from the Minoan eruption serves as a marker horizon in nearly all archaeological sites in the Eastern Mediterranean 9 its precise date is of high importance and has been fiercely debated among archaeologists and volcanologists for decades 10 11 without coming to a definite conclusion Minoan eruption of TheraSatellite image of Thera November 21 2000 The bay in the center of the island is the caldera created by the Minoan eruption VolcanoTheraDatec 1600 BCE see below TypeUltra PlinianLocationSantorini Cyclades Aegean Sea36 24 36 N 25 24 00 E 36 41000 N 25 40000 E 36 41000 25 40000VEI6 1 ImpactDevastated the Minoan settlements of Akrotiri the island of Thera communities and agricultural areas on nearby islands and the coast of Crete with related earthquakes and tsunamis TheraAlthough there are no clear ancient records of the eruption its plume and volcanic lightning may have been described in the Egyptian Tempest Stele 12 The Chinese Bamboo Annals reported unusual yellow skies and summer frost at the beginning of the Shang dynasty which may have been a consequence of volcanic winter similar to 1816 the Year Without a Summer after the 1815 eruption of Mount Tambora 13 Contents 1 Eruption 1 1 Background 1 2 Magnitude 1 3 Sequence 2 Geomorphology 3 Volcanology 4 Eruption dating 4 1 Archaeology 4 2 Radiocarbon age 4 3 Ice cores tree rings and speleothems 5 Historical impact 5 1 Minoan sites 5 2 Chinese records 5 3 Effect on Egyptian history 5 4 Greek traditions 5 4 1 The Titanomachy 5 4 2 Atlantis 5 5 Book of Exodus 5 6 Bicameral mentality 6 See also 7 References 8 Further reading 9 External linksEruption edit nbsp Volcanic craters on Santorini June 2001Background edit Main article Santorini caldera Geological evidence shows the Thera volcano erupted numerous times over several hundred thousand years before the Minoan eruption In a repeating process the volcano would violently erupt then eventually collapse into a roughly circular seawater filled caldera with numerous small islands forming the circle The caldera would slowly refill with magma building a new volcano which erupted and then collapsed in an ongoing cyclical process 14 Immediately before the Minoan eruption the walls of the caldera formed a nearly continuous ring of islands with the only entrance between Thera and the tiny island of Aspronisi 14 This cataclysmic eruption was centered on a small island just north of the existing island of Nea Kameni in the centre of the then existing caldera The northern part of the caldera was refilled by the volcanic ash and lava then collapsed again Magnitude edit The magnitude of the eruption particularly the submarine pyroclastic flows has been difficult to estimate because the majority of the erupted products were deposited in the sea Together these challenges result in considerable uncertainty regarding the volume of the Minoan eruption with estimates ranging between 13 86 km3 3 1 20 6 cu mi DRE 15 16 According to the latest analysis of marine sediments and seismic data gathered during ocean research expeditions from 2015 to 2019 the estimated volume of the material expelled during the volcanic eruption ranges from 28 41 km3 6 7 9 8 cu mi DRE 1 The study revealed that the initial Plinian eruption was the most voluminous phase ejecting 14 21 km3 3 4 5 0 cu mi magma and accounting for half of total erupted materials This was followed by 3 4 km3 0 72 0 96 cu mi DRE co ignimbrite fall 5 9 km3 1 2 2 2 cu mi DRE pyroclastic flows and 5 7 km3 1 2 1 7 cu mi DRE intra caldera deposits 1 This eruption is comparable with the Mount Tambora volcanic eruption of 1815 Mount Samalas eruption of 1257 Lake Taupo s Hatepe eruption around 230 CE and the Paektu Mountain eruption of 946 CE which are among the largest eruptions during the Common Era 6 7 Sequence edit On Santorini there is a 60 m 200 ft thick layer of white tephra that overlies the soil clearly delineating the ground level before the eruption This layer has three distinct bands that indicate the different phases of the eruption 17 Studies have identified four major eruption phases and one minor precursory tephra fall The thinness of the first ash layer along with the lack of noticeable erosion of that layer by winter rains before the next layer was deposited indicate that the volcano gave the local population a few months warning Since no human remains have been found at the Akrotiri site this preliminary volcanic activity probably caused the island s population to flee It is also suggested that several months before the eruption Santorini experienced one or more earthquakes which damaged the local settlements 18 19 20 nbsp Early phase of Late Bronze Age volcano eruption 1500 BC southern border of the Caldera island The lower layer of pumice is finer almost white and without rock intrusions Intense magmatic activity of the first major phase BO1 Minoan A 21 of the eruption deposited up to 7 m 23 ft of pumice and ash with a minor lithic component southeast and east Archaeological evidence indicated burial of man made structures with limited damage The second BO2 Minoan B and third BO3 Minoan C eruption phases involved pyroclastic surges and lava fountaining as well as the possible generation of tsunamis Man made structures not buried during Minoan A were completely destroyed The third phase was also characterized by the initiation of caldera collapse The fourth and last major phase BO4 Minoan D was marked by varied activity lithic rich base surge deposits lava flows lahar floods and co ignimbrite ash fall deposits This phase was characterized by the completion of caldera collapse which produced megatsunamis 21 22 Geomorphology edit nbsp Mansions and hotels atop steep cliffs Although the fracturing process is not yet known the altitudinal statistical analysis indicates that the caldera had formed just before the eruption The area of the island was smaller and the southern and eastern coastlines appeared regressed During the eruption the landscape was covered by the pumice sediments In some places the coastline vanished under thick tuff depositions In others recent coastlines were extended towards the sea After the eruption the geomorphology of the island was characterized by an intense erosional phase during which the pumice was progressively removed from the higher altitudes to the lower ones 23 Volcanology editThe eruption was of the Ultra Plinian type and it resulted in an estimated 30 to 35 km 19 to 22 mi high eruption column which reached the stratosphere In addition the magma underlying the volcano came into contact with the shallow marine embayment resulting in violent phreatomagmatic blasts The eruption also generated 35 to 150 m 115 to 492 ft high tsunamis that devastated the northern coastline of Crete 110 km 68 mi away The tsunami affected coastal towns such as Amnisos where building walls were knocked out of alignment On the island of Anafi 27 km 17 mi to the east ash layers 3 m 10 ft deep have been found as well as pumice layers on slopes 250 m 820 ft above sea level Elsewhere in the Mediterranean are pumice deposits that could have been sent by the Thera eruption Ash layers in cores drilled from the seabed and from lakes in Turkey show that the heaviest ashfall was towards the east and northeast of Santorini The ash found on Crete is now known to have been from a precursory phase of the eruption some weeks or months before the main eruptive phases and it would have had little impact on the island 24 Santorini ash deposits were at one time claimed to have been found in the Nile delta 25 but this is now known to be a misidentification 26 27 Eruption dating editThe Minoan eruption is an important marker horizon for the Bronze Age chronology of the Eastern Mediterranean realm It provides a fixed point for aligning the entire chronology of the second millennium BCE in the Aegean as evidence of the eruption is found throughout the region Yet archaeological dating based on typological sequencing and the Egyptian chronology is significantly younger than the radiocarbon age of Minoan eruption by roughly a century This age discrepancy has resulted in a fierce debate about whether there is an upheaval in the archaeological synchronization between the Aegean and Egypt 28 Archaeology edit Archaeologists developed the Late Bronze Age chronologies of eastern Mediterranean cultures by analyzing design styles of artifacts found in each archaeological layer 29 If the type of artifacts can be accurately assigned then the layer s position in a chronological order can be determined This is known as sequence dating or seriation In Aegean chronology however frequent exchange of objects and styles enables relative chronology be compared with absolute chronology of Egypt so absolute dates could be determined in Aegean Since Minoan eruption has been conclusively placed in late end Late Minoan IA LM IA in the Crete chronology late end Late Helladic I LH I in the mainland chronology 30 31 32 the contention is what Egyptian period was contemporaneous with LM IA and LM IB Decades of intensive archaeological work and seriation on Crete in the last century had confidently correlated the late LM IA with Dynasty XVIII in Egypt and the end of LM IA at the start of Thutmose III 31 Stone vessels discovered in the Shaft Graves in LH I are also of New Kingdom type Multiple archaeological sites of Theran pumice workshop used by the local inhabitants are only found in the New Kingdom strata A milk bowl on Santorini used before volcanic eruption has pottery style of only that of New Kingdom 28 Egyptian inscription on the Ahmose Tempest Stele recorded an extraordinary cataclysm resembling the Minoan eruption 33 Taken together the archaeological evidence points to an eruption date after the accession of Ahmose I The year of accession based on the conventional Egyptian chronology and radiocarbon based chronology are 1550 BCE 34 and 1570 1544 BCE IntCal04 35 or 1569 1548 BCE IntCal20 36 The massive archaeological evidence argues for a Theran eruption date between circa 1550 1480 BCE 37 Proponents of earlier date dispute that Aegean Egypt pottery correlation allows considerable flexibility Several other archaeological interpretations of LM IA and LM IB pottery differ from the traditional and could be consistent with a much earlier beginning time for LM IA and LM IB 38 39 40 Pottery synchronisms was also assessed to be less secure before the LM IIIAI Amenhotep III period 41 Pumice in workshop and inscription on Tempest Stele have been argued to only reflect lower bound of eruption age The date of production of pottery with Santorini milk bowl style in other regions has not been determined and could pre date Minoan eruption The chronology of stone vessel styles during this critical period is lacking 42 43 Radiocarbon age edit Raw radiocarbon dates are not accurate calendar years of the event and this has to do with the fact that the level of atmospheric radiocarbon fluctuates Raw radiocarbon ages can be converted to calendar dates by means of calibration curves which are periodically updated by international researchers Derived calibrated calendar date ranges are highly dependent on how accurately calibration curve represents radiocarbon levels for the time period As of 2022 the most updated calibration curve is IntCal20 44 Early radiocarbon dates in the 1970s with calibration were already showing massive age disagreement and were initially discarded as unreliable by the archaeological community 39 In the following decades the range of possible eruption date narrowed significantly with improved calibration analytical precision statistical method and sample treatment Radiocarbon dating has built a strong case for an eruption date in the late 17th century BCE The table below summarizes the history and results of radiocarbon dating of volcanic destruction layer with pre 2018 calibration curves List of radiocarbon dates with calibration curve published before 2018 Source Calibrated date 95 CI Calibration used Sample context and statistical methodHammer et al 1987 45 1675 1525 BCE Pearson and Stuiver 1986 46 Weighted average of 13 samples from volcanic destruction layer at Akrotiri VDL Ramsey et al 2004 47 1663 1599 BCE INTCAL98 48 Bayesian model of sequence of samples from before during and after eruptionManning et al 2006 49 1683 1611 BCE IntCal04 50 Bayesian model of sequence of samples from before during and after eruptionFriedrich et al 2006 51 1627 1600 BCE IntCal04 50 Wiggle matching of olive tree buried alive in pumice layerManning et al 2010 52 1660 1611 BCE IntCal09 53 Bayesian model of sequence of samples from before during and after eruptionHoflmayer et al 2012 42 1660 1602 BCE 1630 1600 BCE 2 IntCal09 53 Tau boundary function on 28 samples from VDL Wiggle matching of olive tree buried alive in VDL 2 Pearson etl al 2018 54 1664 1614 BCE 1646 1606 BCE 2 1626 1605 BCE 3 IntCal13 55 Weighted average of 28 samples from VDL Tau boundary function on the 28 samples from VDL 2 Wiggle matching of olive tree buried alive in pumice layer 3 In 2018 a team led by tree ring scientist reported a possible offset of a few decades in the previous IntCal calibration curves during the period 1660 1540 BCE The resulted new calibration curve allowed previous raw radiocarbon dates be calibrated to encompass a substantial part of 16th century BCE making it possible for radiocarbon dates to be compatible with archaeological evidence 54 The measured offset was then confirmed by other laboratories across the world and incorporated into the most updated calibration curve IntCal20 56 57 58 In the same year study of bomb peak further questioned the validity of wiggle matching of olive branch because the radiocarbon dates of outermost branch layer could differ by up to a few decades caused by growth cessation then the olive branch could also pre date Thera by decades 59 In 2020 speculation of regional offset specific to Mediterranean context in all calibration curves was reported based on measurements made on juniper wood at Gordion If the regional offset is genuine then calibration based on the regional dataset Hd GOR would place eruption date back to 17th century BCE 60 Others have argued that these site specific offsets are already incorporated into the IntCal20 prediction interval since it is constructed from a much wider range of locations and any locational variation is of similar magnitude to the inter laboratory variation 61 62 While the refined calibration curve IntCal20 does not rule out a 17th century BCE eruption date it does shift the probable range of eruption date to include the majority of 16th century BCE offering a way to at least mitigate the long standing age disagreement However the exact year of eruption has not been settled The table below summarizes the dating results List of volcanic destruction layer VDL radiocarbon dates with calibration curve published after 2018 Source Calibrated date posterior probability Calibration used Sample context and statistical methodManning et al 2020 60 1663 1612 BCE 87 5 Hd GOR 36 Bayesian model of sequence of samples from before during and after eruptionManning et al 2020 36 1619 1596 BCE 64 7 1576 1545 BCE 22 9 IntCal20 44 Bayesian model of sequence of samples from before during and after eruptionSahoglu et al 2022 63 1612 1573 BCE 19 4 1565 1501 BCE 76 1 IntCal20 44 The youngest sample near victims from Theran tsunami layer at CesmeEhrlich et al 2021 64 1624 1528 BCE IntCal20 44 Eight scenarios of olive wood growth to account for possible growth cessationManning 2022 65 1609 1560 BCE 95 4 IntCal20 44 Bayesian model of sequence of samples from before during and after eruption but more comprehensive to include samples from VDL tsunami and distal fallout from across southern Aegean regionPearson et al 2023 66 1610 1510 BCE 95 4 1602 1502 BCE 95 4 IntCal20 44 Therasia olive shrubIce cores tree rings and speleothems edit An eruption of Theran magnitude is expected to leave detectable signal in various environmental records like ice core and tree ring Petrologic constraints on Minoan magma yields a range of 0 3 35 9 trillion grams of sulfur release The higher end of the estimate could cause severe climatic change and leave detectable signals in ice cores and tree rings 67 Notably tree ring dating allows extremely precise dating to the exact calendar year of each ring with virtually no age uncertainty and from properties of the annual tree rings local climate record could be reconstructed down to sub annual precision In 1987 a major Greenland sulfate spike in 1644 20 BCE in ice core chronology was hypothesized to be caused by the Minoan eruption based on the early radiocarbon results of Hammer et al 45 In 1988 a major environmental disruption and extreme global cooling frost ring in 1627 0 BCE were also revealed through precisely dated frost ring and too were hypothesized to be related to Minoan eruption 68 69 70 Archaeologists who preferred late 16th century BCE eruption date were neither convinced by the 1644 20 BCE sulfate spike nor by the 1627 BCE frost ring because evidence of causality between the two events and Minoan eruption was absent 31 Since 2003 multiple independent studies of major elements and trace elements of volcanic ash retrieved from the 1644 20 BCE sulfate layer failed to match the ash to that of Santorini 24 but all attributed the ash to another large eruption during this period Mount Aniakchak thus ruling out Minoan eruption as the cause of the sulfate spike 71 72 73 74 In 2019 revision of Greenland ice core chronology was proposed based on synchronization of frost ring data and major sulfate spike and the revised date for Aniakchak eruption was shifted to 1628 BCE 75 The Greenland ice core chronology offset was independently confirmed by other teams 74 76 and adopted into Greenland Ice Core Chronology 2021 GICC21 77 The 1627 BCE extreme global cooling was then conveniently explained by the major Aniakchak eruption without invoking Thera An eruption date of 1627 BCE is also no longer supported by radiocarbon evidence with the most recent calibration curve IntCal20 74 In light of much younger radiocarbon dates and revised ice core chronology several possible ice core and tree ring signals in the 17th and 16th century BCE have been proposed 74 78 79 The list below summarizes the tree ring and ice core signals that may have been caused by the Minoan eruption List of proposed Minoan eruption dates suggested by environmental anomalies Date Environmental context Records Ref1681 1673 BCE Tree ring increases of sulfur calcium and rare earth elements in Mediterranean tree ring 857 possibly caused by volcanic eruption in this region 80 81 1654 BCE Ice core and tree ring one of largest sulfate spikes recorded in Greenland in the last 4 000 years estimated 50 trillion grams of sulfur frost damaged ring in 1653 BCE followed by ring width minima in 1652 BCE 74 79 1649 BCE Tree ring ring width minima 79 1619 BCE Tree ring narrow ring 79 1611 BCE Ice core sulfate spike estimated 2 8 trillion grams of sulfur 74 1597 BCE Tree ring ring width minima 79 1561 BCE Ice core and tree ring large sulfate spike estimated 22 trillion grams of sulfur ring growth reduced in 1560 BCE calcium depletion in Mediterranean tree ring in 1560 BCE possibly caused by volcanic eruption in this region 74 54 1558 BCE Ice core sulfate spike estimated 10 trillion grams of sulfur 74 1555 BCE Ice core and tree ring sulfate spike estimated 6 trillion grams of sulfur reduced ring growth in 1554 BCE 74 1546 BCE Tree ring reduced tree ring growth 54 1544 BCE Tree ring ring width minima 54 1539 BCE Ice core sulfate spike estimated 6 trillion grams of sulfur 74 1524 BCE Tree ring ring width minima 79 The date of Minoan eruption does not necessarily have to be in one of the years listed in the table because the eruption may not have been environmentally impactful enough to leave any detectable signal 65 In addition a stalagmite from Turkey shows bromine peaks at 1621 25 BCE molybdenum at 1617 25 BCE and sulfur at 1589 25 BCE The authors interpreted that all three peaks were caused by a single volcanic eruption in the Mediterranean region and the time difference was related to differences in their retention rates 82 Others have suggested that the sulfur peak may have been related to the 1561 BCE chemical anomaly recorded in Mediterranean tree rings 54 Historical impact editMinoan sites edit nbsp Excavation of Akrotiri on Thera nbsp The only gold object found at the excavation of Akrotiri a small sculpture of an ibex that was hidden under a floor a thorough evacuation in advance of the catastrophe must have occurred since few artifacts and no corpses were buried in the ash The eruption devastated the nearby Minoan settlement at Akrotiri on Santorini which was entombed in a layer of pumice 83 It is believed that the eruption also severely affected the Minoan population on Crete but the extent of the impact is debated Early hypotheses proposed that ashfall from Thera on the eastern half of Crete choked off plant life causing starvation of the local population 84 After more thorough field examinations the hypothesis has lost credibility as it has been determined that no more than 5 mm 0 20 in of ash fell anywhere on Crete 85 Other hypotheses have been proposed based on archaeological evidence found on Crete indicating that a tsunami likely associated with the eruption impacted the coastal areas of Crete and may have devastated the Minoan coastal settlements 86 4 87 88 Another hypothesis is that much of the damage done to Minoan sites resulted from a large earthquake and the fires it caused which preceded the Thera eruption 89 90 Significant Minoan remains have been found above the Thera ash layer and tsunami level dating from the Late Minoan I era and it is unclear whether the effects of the ash and tsunami were enough to trigger the downfall of the Minoan civilization Some sites were abandoned or settlement systems significantly interrupted in the immediate aftermath of the eruption 88 Some archaeologists speculate that the eruption caused a crisis in Minoan Crete opening it to Mycenaean influence or even conquest 4 Chinese records edit A volcanic winter from an eruption in the late 17th century BCE has been claimed by some researchers to correlate with entries in later Chinese records documenting the collapse of the semi legendary Xia dynasty in China According to the Bamboo Annals the collapse of the dynasty and the rise of the Shang dynasty approximately dated to 1618 BCE were accompanied by yellow fog a dim sun then three suns frost in July famine and the withering of all five cereals 13 Effect on Egyptian history edit Further information Ahmose I Dates and length of reign Apocalyptic rainstorms which devastated much of Egypt and were described on the Tempest Stele of Ahmose I have been attributed to short term climatic changes caused by the Theran eruption 91 92 93 The dates and regnal dates of Ahmose I are in some dispute with Egyptologists leaving aside alternate chronologies Proposed reigns range from 1570 1546 BCE to 1539 1514 BCE A radiocarbon dating of his mummy produced a mean value of 1557 BCE In any case this would only provide an overlap with the later estimates of eruption date 94 Alternatively if the eruption occurred in the Second Intermediate Period the absence of Egyptian records of the eruption could be caused by the general disorder in Egypt around that time While it has been argued that the damage attributed to these storms may have been caused by an earthquake following the Thera eruption it has also been suggested that it was caused during a war with the Hyksos and the storm reference is merely a metaphor for chaos upon which the Pharaoh was attempting to impose order 95 Documents such as Hatshepsut s Speos Artemidos depict storms but are clearly figurative not literal Research indicates that the Speos Artemidos stele is a reference to her overcoming the powers of chaos and darkness 95 Greek traditions edit See also Deucalion Dating by early scholars The Titanomachy edit The eruption of Thera and volcanic fallout may have inspired the myths of the Titanomachy in Hesiod s Theogony 96 The Titanomachy could have picked up elements of western Anatolian folk memory as the tale spread westward Hesiod s lines have been compared with volcanic activity citing Zeus s thunderbolts as volcanic lightning the boiling earth and sea as a breach of the magma chamber immense flame and heat as evidence of phreatic explosions among many other descriptions 97 Atlantis edit Main article Location hypotheses of Atlantis Spyridon Marinatos the discoverer of the Akrotiri archaeological site suggested that the Minoan eruption is reflected in Plato s story of Atlantis However this view is not supported by current scholarship 98 99 100 101 Book of Exodus edit Geologist Barbara J Sivertsen seeks to establish a link between the eruption of Santorini c 1600 BCE and the Exodus of the Israelites from Egypt in the Bible 20 Bicameral mentality edit In the controversial bicameral mentality hypothesis Julian Jaynes has argued that the Minoan eruption was a crucial event in the development of human consciousness 102 since the displacements that it caused led to new and important interactions among communities See also editTimeline of volcanism on Earth Chronology of the ancient Near EastReferences edit a b c d Karstens Jens Preine Jonas Crutchley Gareth J Kutterolf Steffen van der Bilt Willem G M Hooft Emilie E E Druitt Timothy H Schmid Florian Cederstrom Jan Magne Hubscher Christian Nomikou Paraskevi Carey Steven Kuhn Michel Elger Judith Berndt Christian 2023 04 29 Revised Minoan eruption volume as benchmark for large volcanic eruptions Nature Communications 14 1 2497 Bibcode 2023NatCo 14 2497K doi 10 1038 s41467 023 38176 3 ISSN 2041 1723 PMC 10148807 PMID 37120623 Hardy DA 1989 Therea and the Aegean World III Volume III Chronology Proceedings of the Third International Congress Hardy DA editor Retrieved 2008 03 16 Paris Raphael et al 2022 A Minoan and a Neolithic tsunami recorded in coastal sediments of Ios Island Aegean Sea Greece in Marine Geology Volume 452 October 2022 Abstract tsunami deposits on the coasts of Ios Island Aegean Sea Greece marine sediments and pumices from the 1600 BCE Minoan eruption of Santorini volcano This 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Larger Eruption than Previously Reported PDF Chapman Conference on Volcanism and the Earth s Atmosphere Thera Greece American Geographical Union Retrieved 2007 05 29 a href Template Cite conference html title Template Cite conference cite conference a CS1 maint multiple names authors list link Sigurdsson H Carey S Alexandri M Vougioukalakis G Croff K Roman C Sakellariou D Anagnostou C Rousakis G Ioakim C Gogou A Ballas D Misaridis T amp Nomikou P 2006 Marine Investigations of Greece s Santorini Volcanic Field Eos 87 34 337 48 Bibcode 2006EOSTr 87 337S doi 10 1029 2006EO340001 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Friedrich Walter L 2013 The Minoan Eruption of Santorini around 1613 B C and its consequences PDF Tagungen des Landesmuseums fur Vorgeschichte Halle 9 37 48 ISSN 1867 4402 Aitken M J 1988 The Thera Eruption Continuing Discussion of the Dating archaeometry 30 1 165 182 doi 10 1111 j 1475 4754 1988 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Archaeological Science 36 6 1206 1214 Bibcode 2009JArSc 36 1206P doi 10 1016 j jas 2009 01 009 ISSN 0305 4403 Badertscher S Borsato A Frisia S Cheng H Edwards R L Tuysuz O Fleitmann D 2014 Speleothems as sensitive recorders of volcanic eruptions the Bronze Age Minoan eruption recorded in a stalagmite from Turkey Earth and Planetary Science Letters 392 58 66 Bibcode 2014E amp PSL 392 58B doi 10 1016 j epsl 2014 01 041 Vergano Dan 2006 08 27 Ye gods Ancient volcano could have blasted Atlantis myth USA Today Retrieved 2008 03 09 Marinatos S 1939 The Volcanic Destruction of Minoan Crete Antiquity 13 52 425 39 doi 10 1017 S0003598X00028088 S2CID 161365405 Callender G 1999 The Minoans and the Mycenaeans Aegean Society in the Bronze Age Oxford University Press ISBN 0 19 551028 3 Lilley Harvey 20 April 2007 The wave that destroyed Atlantis BBC Timewatch Retrieved 2008 03 09 Pareschi MT Favalli M amp Boschi E 2006 Impact of the Minoan tsunami of Santorini Simulated scenarios in the eastern Mediterranean Geophysical Research Letters 33 18 L1860 Bibcode 2006GeoRL 3318607P doi 10 1029 2006GL027205 S2CID 129662039 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link a b B Molloy F McCoy R Megarry and D Govantes Edwards M Pavlacky 2014 Tephra tsunamis and chronology at Priniatikos Pyrgos in B Molloy and C Duckworth eds A Cretan Landscape through Time Priniatikos Pyrgos and Environs Oxford BAR Page D L The Santorini Volcano and the Destruction of Minoan Crete The Society for the Promotion of Hellenic Studies London 1970 Panagiotaki M 2007 The impact of the eruption of Thera in the Central Palace sanctuary at Knossos Crete Mediterranean Archaeology amp Archaeometry 5 2 Archived from the original on 2008 12 29 Retrieved 2008 07 03 Foster KP Ritner RK and Foster BR 1996 Texts Storms and the Thera Eruption Journal of Near Eastern Studies 55 1 1 14 doi 10 1086 373781 S2CID 162024484 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link EN Davis 1990 A Storm in Egypt during the Reign of Ahmose Thera and the Aegean World III Thera Foundation Archived from the original on 14 March 2007 Retrieved 2007 03 10 Goedicke Hans 1995 Chapter 3 Studies about Kamose and Ahmose Baltimore David Brown Book Company ISBN 0 9613805 8 6 Christopher Bronk Ramsey et al Science June 18 2010 Vol 328 no 5985 pp 1554 1557 a b Wiener MH Allen JP 1998 Separate Lives The Ahmose Tempest Stela and the Theran Eruption Journal of Near Eastern Studies University of Chicago Press 57 1 28 doi 10 1086 468596 S2CID 162153296 Greene MT 2000 Natural Knowledge in Preclassical Antiquity Johns Hopkins University Press ISBN 978 0 8018 6371 4 page needed Luce John Victor 1969 The end of Atlantis New light on an old legend New Aspects of Antiquity London Thames amp Hudson ISBN 978 0 500 39005 4 page needed Marinatos Spyridon 1972 Some Words about the Legend at Atlantis 2nd ed Athens C Papachrysanthou Neer Richard 2012 Art and Archaeology of the Greek World Thames and Hudson p 37 ISBN 978 0 500 05166 5 popular associations of the eruption with a legend of Atlantis should be dismissed nor is there good evidence to suggest that the eruption brought about the collapse of Minoan Crete Manning Stuart 2012 Eruption of Thera Santorini In Cline Eric ed The Oxford Handbook of the Bronze Age Aegean Oxford University Press pp 457 454 doi 10 1093 oxfordhb 9780199873609 013 0034 ISBN 978 0199873609 Marinatos 1939 famously suggested that the eruption might even have caused the destruction of Minoan Crete also Page 1970 Although this simple hypothesis has been negated by the findings of excavation and other research since the late 1960s which demonstrate that the eruption occurred late in the Late Minoan IA ceramic period whereas the destructions of the Cretan palaces and so on are some time subsequent late in the following Late Minoan IB ceramic period Brouwers Josho 2021 Did Atlantis Exist Bad Ancient Retrieved August 30 2023 Jaynes Julian 1976 The Origin of Consciousness in the Breakdown of the Bicameral Mind Boston MA Houghton Mifflin Co p 479 ISBN 0547527543 Further reading editBietak M 2004 Review A Test of Time by S W Manning 1999 PDF Bibliotheca Orientalis 61 199 222 Retrieved 2008 04 21 Callender G 1999 The Minoans and the Mycenaeans Aegean Society in the Bronze Age Oxford University Press ISBN 0 19 551028 3 Forsyth PY 1997 Thera in the Bronze Age Peter Lang Publishing ISBN 0 8204 4889 3 Friedrich WL 1999 Fire in the Sea the Santorini Volcano Natural History and the Legend of Atlantis Cambridge University Press ISBN 0 521 65290 1 1 Lespez Laurent et al Discovery of a tsunami deposit from the Bronze Age Santorini eruption at Malia Crete impact chronology extension Scientific reports 11 1 2021 Notti Erika The Theran Epigraphic Corpus of Linear A Geographical and Chronological Implications Pasiphae vol 000 no 004 pp 93 96 2010 Notti Erika Writing in Late Bronze Age Thera Further Observations on the Theran Corpus of Linear A Pasiphae vol 000 no 015 2021 ISSN 2037 738X Page D L 1970 The Santorini Volcano and the Destruction of Minoan Crete The Society for the Promotion of Hellenic Studies London Warren PM 2006 The date of the Thera eruption In Czerny E Hein I Hunger H Melman D Schwab A eds Timelines Studies in Honour of Manfred Bietak Orientalia Lovaniensia Analecta 149 Louvain la Neuve Belgium Peeters pp 2 305 21 ISBN 90 429 1730 X External links editStatistical analysis aims to solve Greek volcano mystery David Nutt Phys org September 20 2022 Researchers home in on Thera volcano eruption date Mikayla MacE Kelley Phys org May 2 2022 Santorini Decade Volcano Santorini s geology and volcanic history the Minoan eruption and the legend of Atlantis The Thera Santorini Volcanic Eruption and the Absolute Chronology of the Aegean Bronze Age A WWW companion site to Sturt W Manning A Test of Time the volcano of Thera and the chronology and history of the Aegean and east Mediterranean in the mid second millennium BC VolcanoWorld Information about the eruption with photographs Thera 2006 Expedition exploration of the submarine deposits and morphology of Santorini volcano The eruption of Santorini in the Late Bronze Age Online doctoral thesis on the eruption scientific analyses and its environmental effects by David A Sewell 2001 Retrieved from https en wikipedia org w index php title Minoan eruption amp oldid 1188145122 Effect on Egyptian history, wikipedia, wiki, book, books, library,

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