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1960 Valdivia earthquake

Coordinates: 38°14′S 73°03′W / 38.24°S 73.05°W / -38.24; -73.05
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1960 Valdivia earthquake
Collapsed buildings in Valdivia
1960 Valdivia earthquake is located in Chile
Iquique
Iquique
Santiago
Santiago
Temuco
Temuco
1960 Valdivia earthquake
Punta Arenas
Punta Arenas
UTC time1960-05-22 19:11:14
ISC event879136
USGS-ANSSComCat
Local date22 May 1960 (1960-05-22)
Local time15:11:14
Duration10 minutes
Magnitude9.4–9.6 Mw[1]
Depth25 km (16 mi)
Epicenter38°14′S 73°03′W / 38.24°S 73.05°W / -38.24; -73.05
TypeMegathrust
Areas affectedChile, Pacific Rim
Max. intensityMMI XII (Extreme)[2]
Peak acceleration2.93 g[3]
Peak velocity311 cm/s[4]
TsunamiUp to 25 m (82 ft)
LandslidesYes
Casualties1,000–6,000[5]

The 1960 Valdivia earthquake and tsunami (Spanish: Terremoto de Valdivia) or the Great Chilean earthquake (Gran terremoto de Chile) on 22 May 1960 was the most powerful earthquake ever recorded. Most studies have placed it at 9.4–9.6 on the moment magnitude scale,[1] while some studies have placed the magnitude lower than 9.4.[6][7] It occurred in the afternoon (19:11 GMT, 15:11 local time), and lasted 10 minutes. The resulting tsunamis affected southern Chile, Hawaii, Japan, the Philippines, eastern New Zealand, southeast Australia, and the Aleutian Islands.

The epicenter of this megathrust earthquake was near Lumaco, approximately 570 kilometres (350 mi) south of Santiago, with Valdivia being the most affected city. The tremor caused localised tsunamis that severely battered the Chilean coast, with waves up to 25 metres (82 ft). The main tsunami traveled across the Pacific Ocean and devastated Hilo, Hawaii, where waves as high as 10.7 metres (35 ft) were recorded over 10,000 kilometres (6,200 mi) from the epicenter.

The death toll and monetary losses arising from this widespread disaster are not certain.[8] Various estimates of the total number of fatalities from the earthquake and tsunamis have been published, ranging between 1,000 and 6,000 killed.[5] Different sources have estimated the monetary cost ranged from US$400 million to $800 million[9] (or US$4.1 billion to $8.2 billion in 2023, adjusted for inflation).[10]

Geologic context

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Chile is located along the Pacific Ring of Fire, a known zone of high seismicity. The earthquake was a megathrust earthquake resulting from the release of mechanical stress between the subducting Nazca plate and South American plate on the Peru–Chile Trench, off the coast of southern Chile. Because of its geography, Chile remains one of the most seismically active countries in the world.

Chile at the intersection between the Nazca and South American plates, with arrows depicting directionality of plate movements

Tectonic interpretation

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The Valdivia earthquake (light blue at the bottom left of this graph) released almost a quarter of all global seismic energy between 1906 and 2005

The focus of the earthquake was relatively shallow at 33 km (21 mi), considering that earthquakes in northern Chile and Argentina may reach depths of 70 km (43 mi).

A 2019 research paper postulates that the Liquiñe-Ofqui fault had a Mw 9.07 strike-slip subevent along with the Mw 9.37 main thrust sub-event which could help account for how the plate boundary event seemingly "overspent" its tectonic budget. In other words, the previous and current more widely accepted explanation for the earthquake involves the Peru-Chile Trench slipping further than its accumulated slip deficit (the amount of slip available for an earthquake) should allow. The alternative explanation, with two faults slipping nearly simultaneously, could help explain the true mechanism of the earthquake.[11][12]

Subduction zones are known to produce the strongest earthquakes on Earth, as their particular structure allows more stress to build up before energy is released. Geophysicists consider it a matter of time before this earthquake will be surpassed in magnitude by another. The earthquake's rupture zone was ≈ 800 km (500 mi) long, stretching from Arauco (37° S) to below the Chiloé Archipelago (44° S). Rupture velocity, the speed at which a rupture front expands across the surface of the fault, has been estimated as 3.5 km (2.2 mi) per second.[13] The average slip across all 27 Nazca subfaults was estimated to be 11 m, with 25–30 m of slip 200–500 km south of the epicenter on offshore subfaults.[14]

While the Valdivia earthquake was extraordinarily large, the 2016 Chiloé earthquake hints that it did not release all the potential slip in that segment of the plate interface.[15]

Earthquake sequence

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Concepción earthquakes

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The 1960 Chilean earthquakes were a sequence of strong earthquakes that affected Chile between 21 May and 6 June 1960, centered in the Araucanía, Aysén, and Bío Bío regions of the country. The first three quakes, all registering in the planet's top 10 by magnitude for 1960, are grouped together as the 1960 Concepción earthquakes. The first of these was the 8.1 Mw Concepción earthquake at 06:02 UTC-4 on 21 May 1960. Its epicenter was near Curanilahue. Telecommunications to southern Chile were cut off and President Jorge Alessandri cancelled the traditional ceremony of the Battle of Iquique memorial holiday to oversee the emergency assistance efforts.[citation needed] The second and third Concepción earthquakes occurred the next day at 06:32 UTC-4 (7.1 Mw) and 14:55 UTC-4 (7.8 Mw) on 22 May. These earthquakes formed a southward migrating foreshock sequence to the main Valdivia shock, which occurred just 15 minutes after the third event.[16]

The earthquake interrupted and effectively ended a protest by coal miners from Lota, who were attempting to march to Concepción to demand higher salaries.[17]

Valdivia earthquake

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The Valdivia earthquake occurred at 15:11 UTC-4 on 22 May, and affected all of Chile between Talca and Chiloé Island, more than 400,000 square kilometres (150,000 sq mi). Coastal villages, such as Toltén, were struck. At Corral, the main port of Valdivia, the water level rose 4 m (13 ft) before it began to recede. At 16:20 UTC-4, a wave of 8 m (26 ft) struck the Chilean coast, mainly between Concepción and Chiloé. Another wave measuring 10 m (33 ft) was reported ten minutes later.

Hundreds of people were already reported dead by the time the tsunami struck. One ship, Canelo, starting at the mouth of the Valdivia River, sank after being moved 1.5 km (0.93 mi) backward and forward in the river; as of 2005, its mast was still visible from the road to Niebla.[18]

USGS ShakeMap for the mainshock

Soil subsidence also destroyed buildings, deepened local rivers and created wetlands in such places as the Río Cruces and Chorocomayo, a new aquatic park north of the city. Extensive areas of the city were flooded. The electricity and water systems of Valdivia were totally destroyed. Witnesses reported underground water flowing up through the soil. Despite the heavy rains of 21 May, the city was without a water supply. The river turned brown with sediment from landslides and was full of floating debris, including entire houses. The lack of potable water became a serious problem in one of Chile's rainiest regions.[19][20]

The earthquake did not strike all the territory with the same strength; measured with the Mercalli scale, tectonically depressed areas suffered heavier damage. The two most affected areas were Valdivia and Puerto Octay, near the northwest corner of Llanquihue Lake. Puerto Octay was the center of a north–south elliptical area in the Central Valley, where the intensity was at the highest outside the Valdivia Basin.[21] East of Puerto Octay, in a hotel in Todos los Santos Lake, stacked dishes were reported to have remained in place.[21] With the exception of poor building sites, the zone of Mercalli scales intensities of VII or more all lay west of the Andes in a strip running from Lota (37° S) southwards. The area of intensities of VII or more did not penetrate into the Central Valley north of Lleulleu Lake (38° S) and south of Castro (42.5° S).[22] Two days after the earthquake Cordón Caulle, a volcanic vent close to Puyehue volcano, erupted. Other volcanoes may also have erupted, but none were recorded because of the lack of communication in Chile at the time. The relatively low death toll in Chile (5,700) is explained in part by the low population density in the region, and by building practices that took into account the area's high geological activity.

Earthquake lights were reported in Purén.[23]

Aftershocks

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One of the main aftershocks occurred on 6 June in Aysén Region.[24] This magnitude 7.7 earthquake probably occurred along the Liquiñe-Ofqui Fault, meaning that the fault would have moved as a consequence of the 22 May Valdivia earthquake.[24]

Natural disasters

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Tsunamis

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Travel time of the tsunami across the Pacific Ocean at one-hour intervals

Earthquake-induced tsunamis affected southern Chile, Hawaii, Japan, the Philippines, China,[25] eastern New Zealand, southeast Australia, and the Aleutian Islands. Some localized tsunamis severely battered the Chilean coast, with waves up to 25 m (82 ft). The main tsunami crossed the Pacific Ocean at a speed of several hundred km/h and devastated Hilo, Hawaii, killing 61 people.[26] Most of the tsunami-related deaths in Japan occurred in the northeast Sanriku region of Honshu.[15]

The Chilean coast was devastated by a tsunami from Mocha Island (38° S) to Aysén Region (45° S). Across southern Chile, the tsunami caused huge loss of life, damage to port infrastructure, and the loss of many small boats. Further north, the port of Talcahuano did not suffer any major damage, only some flooding. Some tugboats and small sailboats were stranded on Rocuant Island near Talcahuano.[27]

In Valdivia the tsunami swell penetrated along Calle-Calle River as far as Huellelhue putting afloat piles of firewood that lay in the fields.[28]

After the 21 May Concepción earthquake, people in Ancud sought refuge in boats. A carabinero (police) boat, Gloria, was towing a few of these boats when the second earthquake struck on 22 May. As the sea regressed Gloria became stranded between Cerro Guaiguén and Cochinos Island. The stranded boat was wrecked when a tsunami wave engulfed it.[27]

All the new infrastructure of the small port of Bahía Mansa was destroyed by the tsunami, which reached heights of up to 10 metres above sea level there. The boat Isabella in Bahía Mansa quickly left the port but lost its anchors.[27]

Wrecks of Carlos Haverbeck (top) and Canelo (bottom).

In the Valdivia River and Corral Bay, several vessels were wrecked by the earthquake, among them Argentina, Canelo, Carlos Haverbeck, Melita, and the salvaged remnants of Penco. Canelo was anchored at Corral when the quake struck, filling a cargo of wood and other products destined for northern Chile. The engine of Canelo was warmed up after the earthquake. After hours of drifting around in Corral Bay and Valdivia River, the ship was wrecked and subsequently abandoned by its crew at 1800 local time. Two men on board Canelo died in the incident. As of 2000, the remnants of Canelo were still visible.[27]

Santiago, another ship anchored at Corral at the time of the quake, managed to leave Corral in a bad state but was wrecked off the coast of Mocha Island on 24 May.[27] The schooner La Milagrosa departed from Queule on 22 May to load a cargo of Fitzroya wood shingles in a small port south of Corral. La Milagrosa was battered by the currents and waves of the tsunami for four days while moving south. Outside Corral the crew rescued six nearly unconscious and dehydrated children on board two boats. The boats found were used to navigate in Valdivia River and Corral Bay but had drifted into the high sea.[29]

Hilo, Hawaii, after the tsunami

The coastal localities of Mississippi and Mehuín were struck by the tsunami causing the loss of fishing boats.[30] 150 boats, most of them used for fishing are reported to have "disappeared" in Mehuín.[30] Some kilometres north of Mahuín at the coastal town of Queule, a carabinero reported hundreds of people dead or missing some days after the tsunami. Historians Yoselin Jaramillo and Ismael Basso report that people in Queule decades later know about 50 people to have died because of the earthquake and tsunami.[31]

Landslides

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Effect of the tsunami at Kamaishi, Japan

The earthquake triggered numerous landslides, mainly in the steep glacial valleys of the southern Andes. Within the Andes, most landslides occurred on forested mountain slopes around the Liquiñe-Ofqui Fault. Some of these areas remain sparsely vegetated while others have naturally developed more or less pure stands of Nothofagus dombeyi.[32] These landslides did not cause many fatalities nor significant economic losses because most of the areas were uninhabited, with only minor roads.

One landslide caused destruction and alarm following its blockage of the outflow of Riñihue Lake (see below). About 100 km (62 mi) south of Riñihue Lake, landslides in the mountains around Golgol River caused the river to dam up; when it burst through the earthen dam, it created a flood down to Puyehue Lake.[33] The Golgol landslides destroyed parts of international Route 215-CH, which connects to Bariloche in Argentina through Cardenal Antonio Samoré Pass.

While most landslides clustered around north–south strips in the Andes, other areas that were affected by large numbers of landslides were the coast, mainly the foot of the Chilean Coast Range, and the shores of Llanquihue Lake.[21]

Seiches

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A seiche (type of standing wave) of more than 1 meter was observed on Panguipulli Lake following the earthquake.[34] On 22 May, a seiche occurred also in Nahuel Huapi Lake, on the Argentine side of the Andes, more than 200 km away from Valdivia. The wave, most likely produced by an earthquake-triggered sediment slide at the lake bottom, killed two people and destroyed a pier in San Carlos de Bariloche city.[35]

Riñihue Lake's flood

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During the Great Chilean earthquake, several landslides west of Tralcán Mountain blocked the outflow of Riñihue Lake. Riñihue Lake is the lowest of the Seven Lakes chain and receives a constant inflow from the Enco River.[36] The blocked San Pedro River, which drains the lake, passes through several towns before reaching the city of Valdivia near the coast.[37]

As the San Pedro River was blocked, the water level of Riñihue Lake started to rise quickly. Each meter the water level rose was equivalent to 20 million cubic meters, which meant that 480 million cubic meters of water would release into the San Pedro River (easily overpowering its flow capacity of 400 cubic metres (14,000 cu ft) per second if it rose above the final, 24-meter-high dam. This potential disaster would have violently flooded all the settlements along the course of the river in less than five hours, with more dire consequences if the dam suddenly broke.

About 100,000 people lived in the affected zone.[37] Plans were made to evacuate Valdivia, and many people left. To avoid the destruction of the city, several military units and hundreds of workers from ENDESA, CORFO, and MOP started an effort to control the lake.[36] Twenty-seven bulldozers were put into service, but they had severe difficulties moving in the mud near the dams, so dykes had to be constructed with shovels from June onwards.[36] The work was not restricted to the lake; drainages from other parts of the Seven Lakes were dammed to minimize additional flow into Riñihue Lake. These dams were removed later, with the exception of Calafquén Lake, which still retains its dam.

By 23 June, the main dam had been lowered from 24 to 15 m (79 to 49 ft), allowing 3 billion cubic metres of water to leave the lake gradually, but still with considerable destructive power. The team was led by ENDESA engineer Raúl Sáez.

Cordón Caulle eruption

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Eruption of Cordón Caulle following the earthquake

On 24 May, 38 hours after the main shock of the 1960 Valdivia earthquake, the Cordón Caulle volcano erupted.[38] The eruption was believed to have been triggered by the earthquake.[38] Between two sparsely populated and isolated Andean valleys, the eruption had few eyewitnesses and received little attention by local media, which was preoccupied with the severe and widespread damage and losses caused by the earthquake.[39] The eruption was first noticed and reported as an explosion by the crew of a United States Air Force plane that was heading to Santiago from Puerto Montt.[40]

The eruption fed a 5.5 km-long fissure on 135° heading where 21 individual vents have been found. These vents produced an output of about 0.25 km3 DRE both in form of lava flows and tephra. The eruption ended on 22 July 59 days later.[39]

As a result of an evacuation plan, there were no reported human deaths associated with the eruption.[41]

Consequences and response

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Urban impact

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The destroyed center of Corral, Chile

The levels of material damage were relatively low despite the high magnitude of the earthquake. Part of the reason behind this was the limited infrastructure development of the region next to the rupture zone.[22] Structures that had been designed to resist earthquakes performed well during the earthquake, chiefly suffering damage when affected by soil subsidence or small fault movements.[22] Houses built by their owners fared badly. In the regions of Maule and Bío Bío, houses built from adobe and masonry proved weak, while from Araucanía to the south weak houses were mainly those built with inappropriate wood that had decayed over time.[22]

It has been estimated that about 40 percent of the houses in Valdivia were destroyed, leaving 20,000 people homeless.[42] The most affected structures were those built of concrete, which in some cases collapsed completely, because they were not built using modern earthquake engineering. Traditional wooden houses fared better; although many were uninhabitable if they did not collapse. Houses built upon elevated areas suffered considerably less damage compared to those on the lowlands, which absorbed great amounts of energy. Many city blocks with destroyed buildings in the city center remained empty until the 1990s and 2000s, with some of them still used as parking lots. Before the earthquake, some of these blocks had modern concrete buildings built after the Great Valdivia fire of 1909.[43] Around the main city square most buildings collapsed except for Edificio Prales and a few others.[44][45]

The hospital of Valdivia, built in 1939, suffered major damage and patients had to be evacuated.[46] The United States quickly set up a field hospital following the earthquake.[47] Aided by the United States, a geological survey of Valdivia was done following the earthquake and resulted in the city's first geological map. Mexico built and donated the public school Escuela México after the earthquake.[47]

Valdivia's bridges suffered only minor damage. The damage caused to Calle-Calle Bridge led to its temporary closure after the earthquake, with traffic redirected to Teja Island through Caucau River where people crossed it on boats and, reportedly, also a rudimentary and temporary wooden bridge.[48][49]

Land subsidence in Corral Bay improved navigability as shoal banks, produced earlier by sediments from Madre de Dios and other nearby gold mines, sank and were compacted.[21] As the earthquake destroyed Valdivia's flood barriers, general land subsidence exposed new areas to flooding.[50] Parts of the botanical garden of the Austral University of Chile that were next to Cau-Cau River and the city's southern outskirts along Route 206 were permanently flooded.[51][52]

The earthquakes damaged an area that had suffered a long period of economic decline, which began with shifts in trade routes due to the expansion of railroads in southern Chile and the opening of the Panama Canal in 1914.[43]

Unlike Valdivia, Osorno was saved from major destruction. In Osorno only about 20 houses were totally destroyed, although many firewalls and chimneys collapsed.[53]

Puerto Montt, a major city today, had in the early 1960s about 49,500 inhabitants. The bulk of the damage in Puerto Montt was located in the neighborhood of Barrio Modelo and the northern part of Bahía Angelmó, where artificial fills subsided.[54] Angelmó and other coastal areas of Puerto Montt were among the few urban areas that suffered "total destruction" by the earthquake.[22]

After the earthquake a myth related the unusually warm and clear weather conditions prior to the earthquake to its triggering.[55] When compared with the years that followed in the 1960s the autumn of 1960 in southern Chile was not particularly dry nor warm.[56]

Impact in the countryside

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Destroyed infrastructure of Altos Hornos y Acerías de Corral, a steel factory closed a few years before the earthquake.

The tsunami that struck the coast of southern Chile destroyed seaside farms, killing numerous livestock and people.[57] Barns and industrial structures were destroyed by the quake.[34][57] The dairy industry was among the few industries of the affected zone that received subsidies and investment after the earthquake.[58] It received state support through a long-term policy after the earthquake.[58]

As a result of the earthquake, an international technological cooperation programme was established in the dairy sector. More specifically, the German and Danish governments helped to create the Centro Tecnológico de la Leche (the Milk Technological Centre) in the Southern University of Chile.[59] The scholar Erik Dahmén believes that the earthquake resulted in a "creative destruction" for farmers of Southern Chile.[58]

A large area of former pastures and cultivated fields around the lower course of Cruces River was permanently flooded as a result of c. 2 m of subsidence caused by the earthquake.[60] Over the years the new wetlands were colonized chiefly by Egeria densa (Spanish: luchecillo). Egeria densa and other plants created a rich aquatic ecosystem that attracted a permanent bird fauna, notably black-necked swans.[60] The protected area of Carlos Anwandter Nature Sanctuary was created in 1981 to protect the ecosystem.[60]

A whole neighbourhood of Corral, Corral Bajo was wiped by the tsunami, while the nearby upper area, Corral Alto, suffered the loss of about 20 to 30% of its houses.[61] Among the material loses were a series stilt houses between Corral Bajo and Amargos.[61] After the earthquake many families in Corral relocated to the neighbourhood of La Aguada.[62]

The economy of the coastal town of Queule had during the 1950s developed significantly. Its economy based on fishing, agriculture and industry had grown. Queule was connected by road in 1957 to the rest of the country and the town had developed into a balneario (resort town). This era of prosperity ended with the 1960 earthquake.[63]

Further north the earthquake destroyed numerous houses in the coal-mining town of Lebu.[64]

The coal mine of Pupunahue suffered severe damage which led to coal production recovering to "acceptable levels" only by 1963.[65]

Creation of a national emergency management agency

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After the earthquake, the Chilean Ministry of Economics began to develop a comprehensive reconstruction plan. The efforts of President Alessandri led to the creation of a new institutionality in order to facilitate future emergency preparation and to tackle the country's recovery after the earthquake. The then-newly named Ministry of Economics and Reconstruction was given the task of coordinating rebuilding efforts in joint venture with CORFO, an existing Chilean agency for the promotion of economic growth. Concomitantly, a ministerial-level committee, COPERE (Comisión de Planificación de la Economía y de Reconstrucción), was officially named as the government's Planning and Reconstruction Committee. CORFO acted the secretariat of the committee and was entrusted with the preparation of the reconstruction plan and its detailed execution.[66][67] COPERE had also been entrusted with coordinating provincial activities while CORFO remained the technical secretariat of those provincial committees. A comprehensive national plan for emergencies that helped Chile better prepare for future disasters was enacted, in conjunction with legislation that increased the powers of the President in times of national emergency. CORFO also created the National Company of Telecommunications (ENTEL) out of a pressing need to improve and modernize communication efforts in times of disaster.[67]

In 1974, after the 1971 eruption of Villarrica volcano, COPERE was officially succeeded by ONEMI (Ministry of Interior National Emergency Office)—Chile's modern-day emergency management agency—when it was authorized by law as an independent governmental office by President Salvador Allende.[66][68]

Human sacrifice

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In the coastal village Collileufu (La Araucanía Region), native Lafkenches carried out a human sacrifice during the days following the main earthquake. Collileufu is located in the Budi Lake area, south of Puerto Saavedra, which was highly isolated in 1960. The Mapuche spoke primarily Mapudungun. The community had gathered in Cerro La Mesa, while the lowlands were struck by successive tsunamis. Juana Namuncura Añen, a local machi, demanded the sacrifice of the grandson of Juan Painecur, a neighbor, in order to calm the earth and the ocean.[69][70] The victim was 5-year-old José Luis Painecur, an "orphan" (huacho) whose mother had gone to work as a domestic worker in Santiago and left her son under the care of his father.[69]

The sacrifice was learned about by authorities after a boy in the commune of Nueva Imperial denounced to local leaders the theft of two horses; these were allegedly eaten during the sacrifice ritual.[69] Two men were charged with the crime of murder and confessed, but later recanted. They were released from prison after two years. A judge ruled that those involved had "acted without free will, driven by an irresistible natural force of ancestral tradition". The story was mentioned in a Time magazine article, although with little detail.[71]

Previous and subsequent earthquakes

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An earthquake of similar magnitude occurred in this area around 1800 BC, as has been determined by dating charcoal and shells washed into the Atacama Desert by the tsunami. This apparently caused the hunter-gatherers of the area to stop living near the coast for the next thousand years or so.[72][73]

There is evidence that a similar earthquake and landslide occurred in 1575 in Valdivia.[74] This earthquake was of similar strength and also caused a Riñihuazo. According to the chronicle of Mariño de Lobera, corregidor of Valdivia in 1575, a landslide blocked the outflow of the lagoon of Renigua. Several months later in April, it caused a flood.[75] He said that the Spanish settlers had evacuated and waited on high ground until after the dam burst, but many aboriginals died in the flood waters.[75] While the 1575 earthquake is considered the one most similar to that of 1960, it differed in not having caused any tsunami in Japan.[76][15]

Other lesser earthquakes that preceded the 1960 event occurred in 1737 and 1837.[77]

On 27 February 2010 at 03:34 local time, an 8.8 magnitude earthquake occurred just to the north (off the coast of the Maule region of Chile, between Concepción and Santiago).[78] This quake was reported to be centered approximately 35 kilometres (22 mi) deep and several miles off shore. It may have been related or consequential to the 1960 Valdivia quake, the strongest as recorded using modern technology.[79] This 2010 earthquake was the largest to affect Valdivia since the 1960 event. Thirty five houses were severely damaged and some 44 other suffered reparable damage.[80] A survey showed that 434 persons in Valdivia had their homes damaged by the earthquake. The damages were to areas of poor soil quality, chiefly former wetlands and artificial fills. Some sidewalks near the river shore in Valdivia cracked and collapsed much like in the 1960 earthquake. Overall the 2010 damages in Valdivia were few and highly localized.[80]

See also

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References

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  1. ^ a b Satake, K.; Atwater, B. (2007), "Long-Term Perspectives on Giant Earthquakes and Tsunamis at Subduction Zones" (PDF), Annual Review of Earth and Planetary Sciences, 35 (1): 355, Bibcode:2007AREPS..35..349S, doi:10.1146/annurev.earth.35.031306.140302, archived (PDF) from the original on 9 January 2016, retrieved 21 March 2016
  2. ^ "Significant Earthquake Database". United States Geological Survey. Archived from the original on 5 January 2017. Retrieved 19 September 2016.
  3. ^ "M 9.5 - 1960 Great Chilean Earthquake (Valdivia Earthquake)-USGS". USGS ShakeMap. Retrieved 21 September 2023.
  4. ^ "M 9.5 - 1960 Great Chilean Earthquake (Valdivia Earthquake)-USGS". USGS ShakeMap. Retrieved 21 September 2023.
  5. ^ a b PAGER-CAT Earthquake Catalog, Version 2008_06.1, United States Geological Survey, 4 September 2009, archived from the original on 13 March 2020
  6. ^ Fujii, Yushiro; Satake, Kenji (1 September 2013). "Slip Distribution and Seismic Moment of the 2010 and 1960 Chilean Earthquakes Inferred from Tsunami Waveforms and Coastal Geodetic Data". Pure and Applied Geophysics. 170 (9): 1493–1509. Bibcode:2013PApGe.170.1493F. doi:10.1007/s00024-012-0524-2. ISSN 1420-9136.
  7. ^ Ho, Tung-Cheng; Satake, Kenji; Watada, Shingo; Fujii, Yushiro (2019). "Source Estimate for the 1960 Chile Earthquake From Joint Inversion of Geodetic and Transoceanic Tsunami Data". Journal of Geophysical Research: Solid Earth. 124 (3): 2812–2828. Bibcode:2019JGRB..124.2812H. doi:10.1029/2018JB016996. ISSN 2169-9313.
  8. ^ Video: Cataclysm. Volcano, Tidal Waves, Devastate Pacific Area, 1960/05/27 (1960). Universal Newsreel. 1960. Archived from the original on 28 April 2013. Retrieved 22 February 2012.
  9. ^ "The Largest Earthquake in the World – Articles". United States Geological Survey. Archived from the original on 7 January 2007. Retrieved 11 January 2007.
  10. ^ 1634–1699: McCusker, J. J. (1997). How Much Is That in Real Money? A Historical Price Index for Use as a Deflator of Money Values in the Economy of the United States: Addenda et Corrigenda (PDF). American Antiquarian Society. 1700–1799: McCusker, J. J. (1992). How Much Is That in Real Money? A Historical Price Index for Use as a Deflator of Money Values in the Economy of the United States (PDF). American Antiquarian Society. 1800–present: Federal Reserve Bank of Minneapolis. "Consumer Price Index (estimate) 1800–". Retrieved 29 February 2024.
  11. ^ Kanamori, Hiroo (July 2019). "Evidence for a large strike-slip component during the 1960 Chilean earthquake". Geophysical Journal International. 218 (1): 1–32. doi:10.1093/gji/ggz113. Retrieved 9 July 2022.
  12. ^ Cisternas, M.; Carvajal, M.; Wesson, R.; Ely, L. L.; Gorigoitia, N. (1 November 2017). "Exploring the Historical Earthquakes Preceding the Giant 1960 Chile Earthquake in a Time-Dependent Seismogenic Zone". Bulletin of the Seismological Society of America. 107 (6): 2664–2675. Bibcode:2017BuSSA.107.2664C. doi:10.1785/0120170103. Archived from the original on 26 April 2023. Retrieved 25 August 2022.
  13. ^ Kanamori, Hiroo; Cipar, John J. (1974). "Focal Process of the Great Chilean Earthquake May 22, 1960" (PDF). Physics of the Earth and Planetary Interiors. 9 (2): 128. Bibcode:1974PEPI....9..128K. doi:10.1016/0031-9201(74)90029-6. Archived (PDF) from the original on 10 June 2016. Retrieved 20 April 2016.
  14. ^ Fujii, Yushiro; Satake, Kenji (1 September 2013). "Slip Distribution and Seismic Moment of the 2010 and 1960 Chilean Earthquakes Inferred from Tsunami Waveforms and Coastal Geodetic Data". Pure and Applied Geophysics. 170 (9): 1493–1509. Bibcode:2013PApGe.170.1493F. doi:10.1007/s00024-012-0524-2. ISSN 1420-9136.
  15. ^ a b c Cisternas, M.; Carvajal, M.; Wesson, R.; Ely, L.L.; Gorigoitia, N. (2018). "Exploring the Historical Earthquakes Preceding the Giant 1960 Chile Earthquake in a Time-Dependent Seismogenic Zone". Bulletin of the Seismological Society of America. 107 (6): 2664–2675. Bibcode:2017BuSSA.107.2664C. doi:10.1785/0120170103. Archived from the original on 3 November 2020. Retrieved 30 August 2020.
  16. ^ Barrientos S.E.; Ward S.N. (1990). "The 1960 Chile earthquake: inversion for slip distribution from surface deformation". Geophysical Journal International. 103 (3): 589–598. Bibcode:1990GeoJI.103..589B. doi:10.1111/j.1365-246X.1990.tb05673.x.
  17. ^ Reyes Herrera, Sonia E.; Rodríguez Torrent, Juan Carlos; Medina Hernández, Patricio (2014). "El sufrimiento colectivo de una ciudad minera en declinación. El caso de Lota, Chile". Horizontes Antropológicos (in Spanish). 20 (42). Archived from the original on 3 May 2019. Retrieved 9 February 2017.
  18. ^ Barría, Sandra (1 February 2005). "El domingo en que Valdivia sufrió el terremoto más violento del mundo". La Tercera. Archived from the original on 11 March 2008. Retrieved 18 July 2012.
  19. ^ "Chile | Terremoto de Valdivia: cómo fue el poderoso sismo de 1960, el mayor registrado de la historia – Vivienda al Día". infoinvi.uchilefau.cl. Archived from the original on 26 June 2022. Retrieved 26 April 2023.
  20. ^ "A 60 años del terremoto de 1960 | Deutsche Wochenzeitung Cóndor in Chile" (in Spanish). Archived from the original on 27 March 2023. Retrieved 26 April 2023.
  21. ^ a b c d Weischet, W.; Von Huene, R. (December 1963). "Further observations of geologic and geomorphic changes resulting from the catastrophic earthquake of May 1960, in Chile". Bulletin of the Seismological Society of America. 53 (6): 1237–1257. Bibcode:1963BuSSA..53.1237W. doi:10.1785/BSSA0530061237. Archived from the original on 5 May 2015. Retrieved 15 March 2013.
  22. ^ a b c d e Astroza I., M.; Lazo H., R. (2010). Estudio de los daños de los terremotos del 21 y 22 de mayo de 1960. Congreso chileno de sismología e ingeniería antisísmica. X jornadas (in Spanish). Archived from the original on 5 November 2021. Retrieved 10 May 2017.
  23. ^ Navarrete & Carrillo 2020, p. 85.
  24. ^ a b Kanamori, Hiroo; Rivera, Luis (2017). "An Mw =7.7 slow earthquake in 1960 near the Aysén Fjord region, Chile" (PDF). Geophysical Journal International. 211: 93–106. doi:10.1093/gji/ggx292. Archived (PDF) from the original on 18 July 2018. Retrieved 29 March 2019.
  25. ^ "Tsunami Monitoring in Hong Kong". weather.gov.hk. Archived from the original on 14 January 2013. Retrieved 1 February 2018.
  26. ^ Gates, Alexander E.; Ritchie, David. (2009). Encyclopedia of Earthquakes and Volcanoes Archived 24 April 2020 at the Wayback Machine. Ed. Infobase Publishing. ISBN 9780816072705. p. 49
  27. ^ a b c d e Vargas Sáez, Juan Francisco (2000). Historial del Mar de Chile: Algunos Siniestros Marítimos Acaecidos en el Siglo XX (in Spanish). Valparaíso, Chile. pp. 391–398. ISBN 978-956-288-739-7.
  28. ^ Olivares Reyes et al. 2022, p. 78.
  29. ^ Jaramillo & Basso 2013, pp. 61–63.
  30. ^ a b Navarrete & Carrillo 2020, p. 78.
  31. ^ Jaramillo & Basso 2013, pp. 64.
  32. ^ Veblen, Thomas T.; Ashton, David H. (31 March 1978). "Catastrophic influences on the vegetation of the Valdivian Andes, Chile". Vegetatio. 36 (3): 149–167. doi:10.1007/BF02342598. S2CID 32393448.
  33. ^ Chapron, Emmanuel; Ariztegui, Daniel; Mulsow, Sandor; Villarosa, Gustavo; Pino, Mario; Outes, Valeria; Juvignié, Etienne; Crivelli, Ernesto (1 December 2006). "Impact of the 1960 major subduction earthquake in Northern Patagonia (Chile, Argentina)". Quaternary International. 158 (1): 58–71. Bibcode:2006QuInt.158...58C. doi:10.1016/j.quaint.2006.05.017.
  34. ^ a b Rojas Hoppe 2010, p. 67.
  35. ^ Villarosa, G.; et al. (2009). "Origen del tsunami de 1960 en el Lago Nahuel Huapi, Patagonia: Aplicación de técnicas batimétricas y sísmicas de alta resolución". Revista de la Asociación Geológica Argentina. 65: 593–597.
  36. ^ a b c Urrutia & Lanza 1993, p. 294.
  37. ^ a b "El "Riñihuazo" y su lucha contra la naturaleza", Diario Austral (in Spanish), 22 May 2010, archived from the original on 2 December 2013, retrieved 10 August 2013
  38. ^ a b Pallardy, Richard (17 August 2018). "Chile earthquake of 1960". Encyclopaedia Britannica Online. Archived from the original on 15 September 2018. Retrieved 14 September 2018.
  39. ^ a b Lara, L.E.; Naranjo, J.A.; Moreno, H. (1 November 2004). "Rhyodacitic fissure eruption in Southern Andes (Cordón Caulle; 40.5°S) after the 1960 (Mw:9.6) Chilean earthquake: a structural interpretation". Journal of Volcanology and Geothermal Research. 138 (1–2): 127–138. Bibcode:2004JVGR..138..127L. doi:10.1016/j.jvolgeores.2004.06.009. hdl:10533/175011.
  40. ^ Petit-Breuilh Sepúlveda 2004, p. 222.
  41. ^ Petit-Breuilh Sepúlveda 2004, p. 224.
  42. ^ Terremoto de Valdivia Archived 2 February 2011 at the Wayback Machine, Icarito.
  43. ^ a b Figueroa, Victor; Gayoso, Jorge; Oyarzun, Edgardo; Planas, Lenia. "Investigación aplicada sobre Geografía Urbana: Un caso práctico en la ciudad de Valdivia" Archived 25 October 2014 at the Wayback Machine. Gestion Turistica, UACh.
  44. ^ Olivares Reyes et al. 2022, p. 46.
  45. ^ Olivares Reyes et al. 2022, p. 55.
  46. ^ Navarrete & Carrillo 2020, p. 29.
  47. ^ a b López Cárdenas, Patricio. 2009. Las administraciones municipales en la historia de Valdivia. pp. 62–65.
  48. ^ Navarrete & Carrillo 2020, p. 83.
  49. ^ Olivares Reyes et al. 2022, p. 52.
  50. ^ Rojas, C. "Genesis y manifestación de las inundaciones en el sur de Chile" Archived 13 November 2013 at the Wayback Machine, Observatorio Geográfico de América Latina.
  51. ^ "The Ecological Approach to the Conservation of Plants in Botanic Gardens – The Experience of the Botanic Garden in Valdivia, Chile". BGCI. June 1998. Archived from the original on 25 April 2014. Retrieved 7 July 2014.
  52. ^ Burford, Tim (2005). Chile: The Bradt Travel Guide. Bradt Travel Guides. p. 475. ISBN 9781841620763.
  53. ^ Rojas Hoppe 2010, p. 68.
  54. ^ Wolfgang (1960), Contribuciones al estudio de las transformaciones geográficas en la parte septentrional del sur de Chile por efecto del sismo del 22 de mayo de 1960 (in Spanish), Editorial Universitaria, pp. 95–121
  55. ^ Navarrete & Carrillo 2020, p. 79.
  56. ^ Rojas Hoppe 2010, p. 43.
  57. ^ a b Rytkönen, P. "Fruits of Capitalism: Modernization of Chilean Agriculture, 1950–2000". Lund Studies in Economic History. 31: 132.
  58. ^ a b c Rytkönen, P. "Fruits of Capitalism: Modernization of Chilean Agriculture, 1950–2000". Lund Studies in Economic History. 31: 133.
  59. ^ Rytkönen, P. "Fruits of Capitalism: Modernization of Chilean Agriculture, 1950–2000". Lund Studies in Economic History. 31: 139.
  60. ^ a b c Ramirez, C., E. Carrasco, S. Mariani & N. Palacios. 2006. La desaparición del luchecillo (Egeria densa) del Santuario del Rio Cruces (Valdivia, Chile): una hipótesis plausible. Ciencia & Trabajo, 20: 79-86
  61. ^ a b Navarrete & Carrillo 2020, p. 20.
  62. ^ Schwerter Langenbach, Carolina; Basso Zapata, Ismael (2010). Reconstrucción de la memoria histórica del barrio La Aguadam1906-2010 (in Spanish). Unidad de Comunicaciones Consejo de la Cultura y las Artes Región de Los Ríos. p. 36.
  63. ^ Jaramillo & Basso 2013, pp. 52–57.
  64. ^ Davis, Eliodoro Martín (1990). "Breves recuerdos de algunas actividades mineras del carbón". Actas. Segundo Simposio sobre el Terciario de Chile (in Spanish). Santiago, Chile: Departamento de Geociencias, Facultad de Ciencias, Universidad de Concepción. pp. 189–203.
  65. ^ Aliaga Armijo, Paula; Sepúlveda Márquez, Cristian (2009). Memorias Bajo Tierra: (Re)construcción de la Memoria Colectiva en torno a la minería del Cárbon en la Comuna de Máfil (1935-2001) (in Spanish). p. 44.
  66. ^ a b "National Strategy for Research, Development and Innovation for a Chile Resilient to Disasters of Natural Origin" (PDF). Transition Observatory on Science, Technology, Innovation and Entrepreneurship.(Ministry of Science, Technology, Knowledge and Innovation). November 2016. Archived (PDF) from the original on 30 June 2022. Retrieved 25 April 2023.
  67. ^ a b "CONSULTATION REPORT ON ECONOMIC AND SOCIAL DEVELOPMENT PLANNING" (PDF). Digital Repository of the Economic Commission for Latin America and the Caribbean. 3 March 1962. Archived (PDF) from the original on 26 April 2023. Retrieved 25 April 2023.
  68. ^ Petit-Breuilh Sepúlveda 2004, p. 238.
  69. ^ a b c El cristo mapuche se perdió en el mar Archived 7 July 2011 at the Wayback Machine, El Diario Austral de Valdivia. 23 May 2010.
  70. ^ Tierney, Patrick (1989). The Highest Altar: Unveiling the Mystery of Human Sacrifice. Penguin Books. p. 173. ISBN 0140139745.
  71. ^ "CHILE: Asking for Calm". Time. 4 July 1960. Archived from the original on 17 March 2010. Retrieved 8 February 2010.
  72. ^ Michael Marshall (16 April 2022). "Ancient Chilean tsunami scared local people away for 1000 years". New Scientist. Archived from the original on 15 April 2022. Retrieved 15 April 2022.
  73. ^ Diego Salazar; et al. (6 April 2022). "Did a 3800-year-old Mw ~9.5 earthquake trigger major social disruption in the Atacama Desert?". Science Advances. 8 (14): eabm2996. Bibcode:2022SciA....8M2996S. doi:10.1126/sciadv.abm2996. PMC 8985920. PMID 35385303.
  74. ^ Breve Historia de Valdivia. Editorial Francisco de Aguirre. 1971. Archived from the original on 18 February 2007. Retrieved 8 February 2010.
  75. ^ a b Mariño de Lobera, CAPITULO III Archived 19 October 2013 at the Wayback Machine, Reino de Chile.
  76. ^ Watanabe, H. (1998). Comprehensive List of Destructive Tsunamis to Hit the Japanese Islands (in Japanese). Japan: University of Tokyo Press.
  77. ^ Cisternas, Marco; Atwater, Brian; Torrejon, Fernando; Sawai, Yuki; Machuca, Gonzalo; Lagos, Marcelo; Eipert, Annaliese; Youlton, Cristian; Slagado, Ignacio; Kamataki, Takanobu; Shishkura, Masanobu; Rajendran, C.P.; Malik, Javed; Rizal, Yan; Husni, Muhammad (15 September 2005). "Predecessors of the giant 1960 Chile earthquake" (PDF). Nature. 437 (7057): 404–407. Bibcode:2005Natur.437..404C. doi:10.1038/nature03943. PMID 16163355. S2CID 4398549. Archived (PDF) from the original on 26 November 2015. Retrieved 31 January 2018.
  78. ^ "Tsunami After Deadly Earthquake Hits Chile". 27 February 2010. Archived from the original on 1 March 2010. Retrieved 27 February 2010.
  79. ^ Than, Ker (2 March 2010). "Chile Earthquake Altered Earth Axis, Shortened Day". National Geographic News. Archived from the original on 27 May 2018.
  80. ^ a b Rojas Hoppe, Carlos; Díez Lorente, Silvia (2013). "El terremoto chileno del 27 de febrero de 2010: Análisis preliminar de las consecuencias en la ciudad de Valdivia". Investigaciones Geográficas (in Spanish). 60 (60): 139–153. doi:10.14198/INGEO2013.60.08. hdl:10045/34749.

Bibliography

[edit]
  • Jaramillo, Yoselin; Basso, Ismael (2013). Queule, Entre Mar y Tierra 1950–2012 (in Spanish). Valdivia: Arte Sonoro Austral Ediciones. ISBN 978-956-8716-04-2.
  • Olivares Reyes, Héctor; Muñoz, Juan Carlos; Contreras, Carla; Correa, Katherine (2022). Cataclismo: Memorias de la megacatástrofe de 1960 (in Spanish). ISBN 978-956-414-095-7.
  • Navarrete, Daniel; Carrillo, Daniel (2020). Sesenta historias del Terremoto del 60 (in Spanish). Libros Verde Vivo. ISBN 9789560919069.
  • Petit-Breuilh Sepúlveda, María Eugenia (2004). La historia eruptiva de los volcanes hispanoamericanos (Siglos XVI al XX): El modelo chileno (in Spanish). Huelva, Spain: Casa de los volcanes. ISBN 84-95938-32-4.
  • Rojas Hoppe, Carlos Fernando (2010), Valdivia 1960: Entre aguas y escombros (in Spanish), Valdivia, Chile: Ediciones Universidad Austral de Chile
  • Urrutia de Hazbún, Rosa; Lanza Lazcano, Carlos (1993). Catástrofes en Chile 1541–1992 (in Spanish). Santiago: Editorial La Noria.
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