Earthquake Mythology

Transcription

adapted from the 2014 CUREE Calendar
illustrated essays by Robert Reitherman
© 2013 - All Rights Reserved.
Cover photo: Namazu, the giant catfish who causes earthquakes, from Japanese mythology. (Jan Kozak Collection)
Courtesy of the National Information Service for Earthquake Engineering, PEER, University of California, Berkeley.
CUREE
Consortium of Universities for Research in Earthquake Engineering
1301 South 46th Street, Richmond, CA 94804-4600 tel: 510-665-3529 fax: 510-665-3622
http://www.curee.org
by Robert Reitherman, Executive Director
he modern scientific understanding of earthquakes and the
contemporaneous development of valid engineering techniques to deal
with that hazard mostly evolved since the mid 1800s, with a growth spurt
in the latter half of the twentieth century. That is a small fraction of the
roughly 10,000 years that people have been living in settlements that have
facilitated cultural continuity, and it has been 20,000 years since humans
have constructed simple buildings. The past couple of centuries is an
extremely small fraction of the 200,000-year timespan over which primates
closely resembling us evolved into today’s homo sapiens.
the floodwaters. In an earthquake, everyone and everything is prey to that
invisible attack, regardless of where they try to flee. It is not surprising that
our forebearers, with essentially the same brains as we have, tried to come
up with explanations for this phenomenon, and even if they only came up
with legends and tales, could we have done any better, if we were to be
time-transported back to ancient times?
Consider earthquakes as compared to other natural hazards. In storms, for
example, the wind starts to blow, then it blows harder. The sky darkens. There
is some thunder and lightning, then more. The storm does not pounce on us
all at once, unannounced. A flood is usually preceded by prolonged rainfall.
The wildfire is understandable as a large-scale version of the fires humans
built in their caves and campsites since Paleolithic time. But earthquakes,
unless preceded by a number of small foreshocks (and more often, a small
earthquake leads to nothing larger), come without warning and are easily
conceptualized as something supernatural. How can the very earth be
shaken as far as one can see, and what is big and strong enough to shake
it? How could heavy buildings impervious to any person’s attempt to shove
them sideways be shaken violently? What huge invisible force other than a
supernatural one could cause the earth to shake? Go inside a building and
you are sheltered from the storm. Go to higher ground and you are above
Consider the analogy of Abel Janszoon Tasman (1603–1659), who was
the first to circumnavigate Australia, coming very close to its coastline
but without sighting it. How can one sail around a piece of geography as
large as Australia and never see it? To us, that huge area on the world map
seems impossible to miss, but that is only because many who have gone
before have drawn that world map for us. Science and engineering before
the scientific revolution in Europe were a series of isolated explorations.
Later scientists were able to develop knowledge rapidly by referring to the
overall map of knowledge of earthquakes and their effects, a map that was
steadily filled in, albeit slowly, in the nineteenth century, and more rapidly
through the twentieth.
T
Lacking scientific stepladders on which to stand, people who lived from
200 years ago to 20,000 years ago could not yet accurately see the answers
that any schoolchild today learns as a matter of course. Consider the fact
In that majority of time that people have lived on Earth in the absence that it was only very recently, in the 1960s and later, that earth scientists
of engineering and science that came rather late, there were nonetheless could actually explain where earthquakes came from, that plate tectonic
attempts to understand and deal with earthquakes. It would actually be movements of the earth’s crust, generated by convective forces of magma
surprising if that were not the case, for homo sapiens, the knowing ape, beneath, which in turn caused horizontal seafloor spreading, were the prime
has a strong urge to know about the world and penetrate its mysteries. It mover that shoved and pulled plates of crust and caused localized fracture
would only be surprising if the sudden shaking of the entire region in which lines, or faults, that slipped occasionally and caused earthquakes. The fact
people lived did not bring forth attempts at explaining that frightening and that many 10-year-olds can tell you that explanation today does not mean
bewildering phenomenon. What could be more mysterious? more curious? that the search for that answer was easy or that it could have been done
centuries ago.
more thought-provoking?
While appreciating the basic humanity we share with the ancient peoples,
we need to avoid the pitfall of glorifying the ancient myths as being
accurate insights that predated what civil engineers and earth scientists only
understood centuries later. Care must be taken in examining the frequent
claims that ancient societies precociously developed earthquake-resistant
construction. For example, given the most common material for the biggest
and most important structures of most ancient societies, unreinforced
masonry, one of the best construction techniques to use in the absence of
any engineering know-how is to build thick walls. Fractures still can occur
in walls a meter thick, but fractured upper areas of such walls tend to sit
in a stable manner on lower portions. However, thick masonry walls also
provide greater security against the threat of attacking humans, and in
ancient times towns were invaded many more times by armies and bandits
than by earthquakes. An unreinforced masonry fortress wall is more likely
to survive an earthquake than the thin one of a two-story dwelling, simply
because it has thick walls. The massive brick-walled fort at Fort Point in
San Francisco was the closest building in San Francisco to the San Andreas
Fault that released the earthquake vibrations in 1906, and yet it survived
without significant damage. Precocious earthquake engineering? No, just
unusually thick walls, serving as protection against cannon fire. Thus,
from the historian’s viewpoint, motive becomes an important question. The
question of why people had particular beliefs about earthquakes is relevant,
as well as whether those beliefs were valid from a scientific viewpoint.
The earthquake resistance of the thick walls of Fort Point was provided as an
unintentional byproduct of defending against cannon fire.
As Karl Steinbrugge (1982, p.1) notes, “The supernatural in one form or
another has dominated the explanations of earthquakes and their effects
until the development of the science of seismology.” John Milne (1886, p.7),
from his late nineteenth century perspective, made this conclusion:
Speaking generally, it may be said that the writings of the ancients,
and those of the Middle Ages, down to the commencement of the
nineteenth century, tended to the propagation of superstition and
to theories based on speculations with few and imperfect facts for
their foundation.
Guidoboni (1998 p.197) has reviewed pre-1600 theories about earthquakes,
noting that there “was never a clear dividing line in the ancient world
between religion and the observation of nature.” In the sciences today,
the term “theories” is used to refer to explanations based on the evidence
that must be proved (or withstand evidence that might disprove them) by
recourse to scientific rather than divine laws. In the common usage of
the term, however, there is no doubt that early peoples theorized about
earthquakes: they were curious about them, wondered what caused them,
and struggled to figure out how to mollify their destructiveness. We often
call the earliest cultures primitive, but the minds of those primitive peoples
were recognizably similar to ours.
There are four reasons why prescientific societies did not begin to accurately
understand what caused earthquakes and how to create earthquake-resistant
construction. Lack of technology was one reason, for example, the lack of
seismographs that show us the global distribution of earthquakes and their
size, and the lack of strong motion seismographs that record every lurch
and jolt of the motion of the ground or of structures. Equally important
was a second reason, a lack of a scientific frame of mind. The mythological
explanations for earthquakes described in this chapter were often untestable
beliefs rather than hypotheses. In some cases, premodern explanations
were susceptible to proof or disproof with only ancient knowledgegathering technologies at hand, such as identifying surface fault rupture
and its association with ground shaking, but these explanations were not
investigated in that critical way because the fundamental concept of scientific
methods had yet to evolve.
Thirdly, the lack of earlier progress is partly due to the fact that in a given
region, earthquakes do not happen often, compared to the lifespan of
humans. With sketchy record-keeping – and record-keeping is one of the
hallmarks of science – one could speculate about earthquakes generation
after generation without getting closer to the truth. By contrast, the ad
hoc observational technique worked well with experiments that could be
frequently run. One could try several different fish hooks and compare results
in a single season, but earthquakes do not provide frequent reproducibility
of an experiment.
role of keeping good records and passing them on so that either truths or
falsehoods, workable or unworkable technologies, would be documented for
the next generation to build upon. That continuity of fact-recording over the
past 500 years was not typical of previous history.
Consider this brief listing of accomplishments spanning from Copernicus
to Newton. Isaac Newton (1643–1727) had the work of Galileo Galilei
(1564–1642) to learn from concerning gravity and inertia. Galileo knew the
work of his elder contemporary, Johannes Kepler (1571–1630) on celestial
motions, and although the two differed on theories of orbits and tides, the
Why do biologists conduct so many genetic experiments using the fruit fly competition between them helped stimulate that field of early astronomy
(Drosophila)? One desirable attribute is the large size of its chromosomes, and physics. Kepler studied under and built on the data accumulated by his
but another is its rapid development through its life cycle, a fruit fly senior mentor, Tycho Brahe (1546–1601), who organized an astronomy
developing from egg to adult in as little as a week. To study evolution as it observatory that was to collect data for many years. Nicolaus Copernicus
occurs in humans, one waits about a quarter of a century for offspring of (1473–1543) produced De Revolutionibus, titled because it dealt with the
one generation to develop to maturity; to study that genetic process in fruit revolutions of celestial objects, but it was also a revolution in the history
of science and scientists. Between the publication of De Revolutionibus of
flies, the biologist can study dozens of generations in one year.
Copernicus in 1543 and Principia by Newton in 1687 is a span of almost
Relying on ad hoc observations of damage or lack thereof to construction 150 years, over which there was an unbroken transmission of scientific
in earthquakes, even if the observations had been systematically recorded work among Europeans working in what today are Italy, Austria, Germany,
over the centuries, is an extremely slow process. And while ancient Czech Republic, Sweden, Denmark, and England. Individual brilliant
chronologies of earthquakes do exist in some places such as China, Japan, accomplishments could have merely been short travels down culs-de-sac,
and the Middle East, as Ambraseys (1971) pointed out, the original sources without the highway of knowledge maintained for centuries that made the
are often frustratingly vague and usually only record very approximate scientific revolution possible.
intensity data. Today, engineers subject multiple specimens in the structures
or geotechnical laboratory to tests, or run hundreds of computer analyses, Going back to the premise stated earlier that we moderns share basic aspects
which is analogous to studying dozens of generations of fruit flies. Today of humanity with the ancients, let us ask the question: are we sophisticates
we also have the luxury of knowing almost instantly of the occurrence of today free of nonscientific ideas about earthquakes? Are there still
earthquakes anywhere in the world and dispatching teams to study them, earthquake myths? Ask the “person on the street” in the United States, and
and their data are broadly disseminated and preserved. It is understandable perhaps in other countries as well, to name one designer and one building
why prescientific societies, especially those passing down knowledge that has something to do with earthquakes, and a very common answer is
via oral traditions, made so little progress toward today’s earthquake “Frank Lloyd Wright and the Imperial Hotel.” Why? The answer I have
heard many times when I pose this question to audiences is “because it stood
engineering.
up in the great Tokyo earthquake while most of the rest of the buildings
There was a fourth reason for lack of progress. Part of the success of science fell down,” and people will also say, in layman’s terms, that the building
and engineering in Europe from the Renaissance through the Enlightenment was seismically isolated. This myth, these two false statements, are often
through the Industrial Revolution to today was the seemingly unheroic repeated. To quote the way the mass circulation newsstand edition of Great
Buildings of the World (Knauer 2010, p.52) by Time magazine states it: “the
Imperial Hotel in Tokyo, whose ingenious system of structural supports kept
the hotel intact during a devastating 1923 earthquake that flattened almost
all the buildings around it.”
Back in the 1970s when I did research on the seismic design of the Imperial
Hotel (Reitherman 1980a, 1980b), I found that other, larger buildings in
Tokyo on average did as well or better in the earthquake, and that Tachu
Naito and Riki Sano had by then developed the essence of the equivalent
static lateral force method, which was the forward-looking technique of
earthquake engineering. The feature Wright most promoted as the advanced
seismic design feature of his building, the foundation, was in fact one of its
greatest weaknesses, and it was not a seismically isolated structure, as the
legend today has it. It was very conventionally rooted in the ground with a
typical concrete spread footing on short piles.
feet of settlement in the 1923 earthquake, with continuing distress over
the years from a total of three feet eight inches of settlement. What Wright
does get full credit for was the tremendous aesthetic power of his Imperial
Hotel, which at once had an ancient and modern quality to it. Without the
Imperial Hotel seismic myth, Wright would still stand out as one of the best
and most famous architects in history. When traveling to Tokyo, one should
visit the nearby Meiji Mura outdoor architectural heritage park where a
portion of the old Imperial Hotel has been moved and preserved (the original
being demolished in 1968 to make way for a new highrise Imperial Hotel).
But the seismic myth concerning the building lives on in our supposedly
scientific era, not only in the minds of laypersons but also in architecture
and engineering publications. Ancients were susceptible to believing myths,
but so are we moderns.
A sign of a successful myth is that it is a good story. People today love a
good story as much as the ancient Mesopotamians, who after the death of
Sargon the Great in the 23rd century BC kept alive for 2,000 years the myth
of his magical upbringing by gods. The Greeks of Homer’s day in the eighth
or ninth century BC also loved a good story, and many of them (for example
the historian Herodotus, who came four centuries after Homer) believed in
the supernatural as well as the historical aspects of the Homeric tales. A
successful myth has some element of reality in it to make it more believable.
Sargon the Great actually was a powerful king, Troy actually did exist, and
Wright’s Imperial Hotel did in fact avoid collapse in the 1923 earthquake
(though buildings several times as tall did so as well, with less damage.)
Cross section of Wright’s Imperial Hotel.
Ancient understanding about earthquakes was more often misunderstanding,
Wright’s theory that founding the building on shallow piles isolated the as illustrated in the following examples, but if you had lived in one of those
structure from ground motions emanating beneath the 30 meters of soft soil cultures and eras, (and keeping in mind that even today we sometimes believe
on the site was simply not true, no matter how often the myth that the building in myths and rumors that turn out to be false), could you have done any
was isolated is retold. From our current perspective, with a knowledge of better? And don’t you sense a kinship with these people who were motivated
amplification of soft soils, we can see that he misunderstood ground motion by a fundamental human trait still with us today, the urge to look beneath the
(as most did as of the 1920s): “Because of the wave movements, deep surface of phenomena and seek out causes, to know how the world works?
foundations like long piles would oscillate and rock the structure…That mud
References are located at the back of the calendar.
seemed a merciful provision – a good cushion to relieve the terrible shocks.”
(Wright 1955, p.150) The foundation, rather than some sort of precocious This essay is largely derived from Chapter 3, Ancient Understanding and Misunderstanding, in
seismic design innovation, allowed the building to experience up to two Earthquakes and Engineers: An International History (Robert Reitherman, ASCE Press, 2012),
available through the American Society of Civil Engineers (ASCE) website at: www.asce.org
A Chinese stamp picturing Zhang Heng's seismoscope.
The collection of David J. Leeds
Zhang Heng (79-139 A.D.) was a noted Chinese
astronomer, mathematician, poet, and scientist.
This sketch is one reconstructed version of
the instrument (technically a seismoscope,
not a seismograph) of Zhang Heng. Shaking
was supposed to have dislodged one of
the metal balls poised in a dragon's mouth,
making it fall into the waiting mouth of one
of the frogs, indicating the direction of a
distant earthquake. (Milne 1886)
China Post 1955
Especially for distant sources, the waves are
affected by different paths and geology so that
a predominant direction is difficult to predict.
Also note that Zhang Heng's invention
recorded only the first motion sufficient to
dislodge a ball, not the peak motions.
Zhang Heng's Seismoscope
CUREE
Zhang Heng deserves credit for engineering a device intended to measure an aspect of earthquakes, to
determine the direction from the instrument where the ground motions of an earthquake originated. In
all of the pre-scientific annals of history, he stands out for his original thought and inventiveness and his
avoidance of supernatural speculation. However, the instrument could not have actually deconstructed
the complex vibrations at a site to determine the direction of a distant source. Type in "seismograph" in
a web browser, however, and you will find a multitude of misstatements that have kept this myth alive.
CONSORTIUM of UNIVERSITIES for RESEARCH in EARTHQUAKE ENGINEERING
2014
Statue of Garuda holding Nāgas.
©iStock.com/Alexander Gatsenko
Thailand stamp illustrating
Garuda and the Nāga.
© iStock/traveler1116
The Iron Pillar of Delhi
Robert Reitherman
Wooden Balinese statue of Garuda.
Reitherman Family Collection
The Iron Pillar of Delhi
CUREE
In the Hindu tradition and also some Buddhist sects, the Nāgas are giant snakes, sometimes looked
upon with reverence, but also thought to cause earthquakes by their subterranean movements. The great
antagonist of the Nāgas is the bird-king Garuda, who serves Vishnu as his mount. The famous iron pillar
of Delhi, in a courtyard of what is now the Quwwat-ul-Islam Mosque, was erected in pre-Islamic time
about 400 AD in the reign of Chandragupta II. Some attribute the purpose of the pillar to be the symbolic
anchoring of the underlying Nāga spirit, to restrain its motions and thereby prevent earthquakes.
2014
The Sambaso dancer opens a Kabuki performance
by hopping on one foot to ward off earthquakes. He
is pictured here as a netsuke, a small ivory carving.
Peabody Essex Museum
According to Japanese legend, earthquakes were
caused by the movements of a monster catfish that
lived under Japan. Following the Ansei earthquake
of October 2, 1855, woodblock prints called
Namazu-e ("catfish pictures") appeared in Edo
(now Tokyo). Here in a woodblock print, the people
who suffered from the effects of the earthquake are
trying to punish two Namazu.
Housner Collection, Courtesy of the Archives,
California Institute of Technology
A fighter restrains Namazu with an emormous stone.
Jan Kozak Collection, National Information Service for Earthquake
Engineering, PEER, University of California, Berkeley
Namazu, the logo of the 9th World
Conference on Earthquake Engineering,
held in Tokyo and Kyoto in 1988.
Namazu and Sambaso
CUREE
When traveling in Japan, one may come upon a picture of a catfish in a poster in a subway or train station.
It is not an advertisement about a fish restaurant, but rather an earthquake safety poster. Namazu in Japanese
mythology is the giant catfish who occasionally wriggles and causes the earth to shake. If attending a
Kabuki performance, the Sambaso dancer is the one you will see who enters at the beginning, hopping
on one foot, the tradition being that it will prevent an earthquake from interrupting the performance.
2014
Karl Steinbrugge was a U. C. Berkeley professor
and earthquake engineering expert who
commissioned a carving of Rūaumoko for
the IAEE. It was adopted as the association’s
symbol and was displayed at each of following
World Conferences on Earthquake Engineering
(WCEE). In 2008 it was stolen during the 14th
WCEE conference in Beijing, China, and has
been replaced with a replica.
Charles Tuarau with the tekoteko, a protective figure
mounted on Maori buildings. Tuarau was the master
carver at the national museum, Te Papa Tongarewa,
whom Karl Steinbrugge commissioned to make the
IAEE's Rūaumoko icon. (Evening Post 1959)
In 2009, a replica carving of Rūaumoko was
officially welcomed to its new home at the
University of Canterbury’s Engineering
Library where it will reside between World
Conferences on Earthquake Engineering.
(Canterbury.ac.nz 2009)
The original Rūaumoko statue of the International
Association of Earthquake Engineering (IAEE).
Rūaumoko
CUREE
The Māori belief concerning the origin of Rūaumoko has to do with his birth by an Earth mother god who
rolled over on him, pressing him into the ground. This explains his association with the active geological
signs such as earthquakes and hot springs that the Māori observed in New Zealand. Rūaumoko has become
more well-known today in the earthquake engineering field than any other symbol discussed here with the
exception of Japan's catfish, Namazu, because of the adoption of Rūaumoko as the logo of the International
Association for Earthquake Engineering and the New Zealand Society for Earthquake Engineering.
2014
Aristotle thought that "the earth is essentially
dry, but rain fills it with moisture. Then the
sun and its own fire warm it and give rise to
a quantity of wind both outside and inside
it...." (Barnes 1984, Bekker #365b22). Thus, the
movement of air in underground caverns was
the cause of earthquakes. Many later opinions
were similar:
Athanasius Kircher (1601-1680): underground
passageways were the sites of "subterrestrial
combustions."
Robert Hooke (1635-1703), in his book Lectures
and Discourses of Earthquakes and Subterraneous
Eruptions (1705): underground materials similar
to gunpowder caused explosions.
Robert Mallet (1810-1881) and John Milne (18501913): explosions under the seafloor, where
water seeped into hot cavities, analogous to
boiler explosions.
Aristotle (384 - 322 BC)
© iStock/PanosKarapanagiotis
Bronze statue of Poseidon (or Zeus) in the National
Archaeological Museum in Athens. In his right hand
the statue would originally have held a trident (if
Poseidon) or thunderbolt (if Zeus).
Robert Reitherman
Greek Mythology
CUREE
In Greek mythology, Poseidon was the god of the sea and was usually depicted carrying a trident or fish spear.
One of his nicknames is Earthshaker. With his trident he could strike the ground, causing earthquakes. The
areas inhabited by the ancient Greeks, including regions in what are today southern Italy and western Turkey,
are seismically active. In the Iliad (book XX), Poseidon joins a battle in the Trojan War on the side of the Greeks
(Achaians) as they attack the fortified city of Troy (Ilios): "Poseidon made the solid earth quake beneath, and the
tall summits of the hills; Mount Ida shook from head to foot, and the citadel of Ilios trembled." (Rouse 1938, p. 237).
2014
2.
3.
1.
Stamp from the Philippines.
Phil.Post.Gov
1. Samoa
Mafui'e was the god of earthquakes and
also fire until Maui fought him and carried
fire to humans.
2. New Guinea
Marruni was the god of earthquakes, with
a human-like upper body and the tail of a
snake.
3. Fiji
Negendei was the earth balancer; when he
moved, earthquakes occurred.
4.
4. Hawai'i
Kane-lulu-moku is called the god of
earthquakes, but Pele is better known as the
cause of volcanoes and also earthquakes.
In Fiji legends Negendei was the Earth-balancer, on whose head rested the surface
of the earth. When he moved, earthquakes occurred. One need not visit Fiji to see an
effigy of this god; one can be found outside the Enchanted Tiki Room at Disneyland.
His strength and his struggle to be
free has gained Bernardo Carpio a
folk hero status among the Philippine
people, resulting in stamps, comic
books, and movies.
Sampaguita Pictures
Islands in the Pacific
CUREE
In Philippine mythology, a god named Panlinugun is the Ruler of the underworld and the god of
earthquakes. Some say a giant named Bernardo Carpio is trapped between two great rocks in the Mountains
of Montalban where he uses his enormous strength to either hold up the sky, keep the mountains from
crashing together, or is simply trying to break free. It is his movements that causes earthquakes. In
Oceania, different islands have different but related humanlike gods who cause earthquakes.
2014
The Aztecs who lived
in the Valley of Mexico
personified the source of
earthquakes in Tepeyollotl,
a mountain god, who took
the form of a jaguar leaping
toward the sun.
Bibliotheque Nationale de France
Cizin, also spelled Kisin, was a Mayan god of
the underworld and of earthquakes. He was
often illustrated in pre-Columbian books called
codices in the form of a dancing skeleton holding
a smoking cigarette.
Maarten Hesselt van Dinter
The Mayan calendar is made up of several separate calendars such as the
Long Count, the Tzolkin (divine calendar), and the Haab (civil calendar).
Used together they measured the passing of time in cycles.
©iStock.com/frentusha
Legends of Latin America
CUREE
Much of what we know of early Mesoamerican civilization was found in codices. These folding books
from the pre-Columbian Maya civilization, written in Maya hieroglyphic script, described both Aztec
and Mayan earthquake gods. Some said the Mayan calendar can be matched to destructive earthquake
events, with the last cycle of civilization to end December 21, 2012, a date that came and passed with no
disaster.
2014
USGS geologist Brian Atwater was chiefly responsible for the geological
detective work to relate coastal subsidence along the Washington and
Oregon coasts caused by the subduction earthquake in 1700 that was
recorded in the form of tsunami waves in Japan. Subsidence caused
flooding of trees (allowing for tree-ring dating of their year of death).
Brian Atwater
Chief Maquinna, wearing a thunderbird headdress, welcomes British
Columbia Lieutenant Governor Walter Nichol to Yuquot in 1924. On right,
a Native American monument depicting Mount Conuma (home of the
thunderbird) and thunderbird with whale.
In highly seismic British Columbia, the Haida Indians explained earthquakes as the conflicts between
a thunderbird and a whale. The thunderbird dropped the whale in the water, causing earthquakes
and tsunamis.
Image RBCM PN05054 and RBCM PN11478-a courtesy of Royal BC Museum, BC Archives
Image RBCM CPN14429 courtesy of Royal BC Museum, BC Archives
The Thunderbird and the Whale
CUREE
Preserved in the oral tradition of northwest coast native peoples is the story of a huge wave, a mythological
account that has turned out to have a factual basis (Ludwin 2002). Three centuries ago, a massive subduction
zone earthquake offshore of that coast caused dramatic tsunami effects locally and also sent tsunami
waves to faraway Japan. Written records in Japan (there were none among the Native Americans then)
along with geological evidence have pinpointed the date and time: 9 pm, January 26, 1700.
2014
This sketch is of an oarfish (originally described as a sea serpent) that washed
ashore on a Bermuda beach in 1860. In Japanese folklore the oarfish acts as a
messenger of warning from the Sea God’s Palace. When they appear on the
beaches of Japan, an earthquake is imminent.
Harper's Weekly, 3 March 1860
This oarfish, measuring 18 feet in length, was found off the coast of Southern
California in October 2013.
Catalina Marine Institute
The new Bay Bridge troll, seen in front of the new East Span opened in 2013. The
inset shows an earlier troll attached to the repaired original bridge sections after
the 1989 Loma Prieta Earthquake.
Metropolitan Transportation Commission, Oakland, CA
Omens and Superstitions
CUREE
It is understandable that people look for signs and charms to ward off disaster. In 1989, during the Loma
Prieta Earthquake that struck the San Francisco Bay Area, a section of the Bay Bridge collapsed. During
repairs, the ironworkers welded a small metal troll figure to the Bay Bridge as a protective symbol (inset).
When this span of the Bridge was replaced in 2013, a new troll was created and secured to the Bridge in
an undisclosed location.
2014
TomCat Films, LLC
Global Asylum, Inc. © 2009
Universal Studios Licensing, LLC
Movie Myths About Earthquakes
CUREE
Movies often over-dramatize reality, and earthquake movies are not exceptions. There are scenes of
skyscrapers collapsing, (while usually low- and mid-rise buildings perform worse); people and buildings
are swallowed up in huge surface cracks (instead, localized landslides and liquefaction are what can
occur); earthquakes are predicted (earthquakes are still unpredictable); an earthquake is caused by a
nuclear explosion, flooding a fault with water, or positions of the planets (rather than the strain from
tectonic deformation).
2014
60th FLOOR
844' - 8"
57th FLOOR
795' - 2"
54th FLOOR
743' - 8"
51st FLOOR
50th FLOOR
693' - 2"
676' - 4"
48th FLOOR
640' - 6"
42nd FLOOR
559' - 6"
36th FLOOR
478' - 6"
30th FLOOR
397' - 6"
27 FLOOR
357' - 0"
24th FLOOR
316' -6"
18th FLOOR
235' -6"
12th FLOOR
154' -6"
th
Five-story Toshogu Shrine, Nikko, Japan
BEAMS VARY
FROM W 14
TO W 30
BEAMS
W 36
TYP, BEAMS
W 27
BUILT-UP
GIRDER
19' -4"
Robert Reitherman
5th FLOOR
60' -0"
LOBBY OR 0' -0"
PLAZA LEVEL
14' -6"
BEAMS W 36
19' -6"
W 27 & W 36
- 42' -0"
9' -0"
SOIL
174' -0"
EAST ELEVATION
Imperial Hotel in Tokyo, Japan
Robert Reitherman
Section through the Pyramid building in San Francisco
Stephen et al., 1974
Thomas Irvine (USGS)
Many people believe the Transamerica Pyramid building
in San Francisco is seismically isolated by mounting it
on ball bearings. Actually, with its three basement levels
and nine-foot-thick reinforced concrete mat foundation,
it is like a fencepost embedded in the ground.
Building Construction Myths of Today
CUREE
Even today, earthquake myths live on. Frank Lloyd Wright's Imperial Hotel in Japan was not seismically
isolated, nor is the Pyramid Building in San Francisco. Good performance of timber pagodas in Japan
"has been attributed to the pendulum action of the heavy central post, but this is not tenable, since in
many cases the central column rests on a stone base (Muto 1930, p. 16)." Muto and Berg (1976) provide
the less catchy but more accurate reason: these structures just happen to have very high damping and
long periods of vibration.
2014
It will be a magnitude 6.6...no, make that 6.7.
Epicenter 15 kilometers south-southwest.
Tomorrow at 5:45 pm.
Darn, that's going to interrupt my dinner.
Endangered Bird Said To
Predict Earthquakes
The Great Argus, a type of pheasant found
in Sumatra, known locally as a Kuwau,
is claimed to have the ability to predict
earthquakes. Some say the bird was noted
as acting strangely, singing often and
loudly, prior to the Sumatra quake on
Sept. 30, 2009.
A theory popularized in Santa Clara County, California in the 1980s asserted that when dogs ran away from home it
was a premonitory sign of an earthquake. However, a study of 41,717 reports of missing pets and 224 earthquakes in
the region (Schaal 1988) found that "the data show there is no correlation."
Sandy Cole
Robert Reitherman
Can Animals Predict Earthquakes?
CUREE
This myth enjoys continued popularity, despite studies refuting it. The 1976 Haicheng Earthquake in
China was said to have been successfully predicted, which may have been the case, but the primary
reason the seismologists made a forecast was because of an increasingly intense earthquake swarm, and
not animal behavior. Unfortunately for the effort to predict earthquakes, most small earthquakes are not
foreshocks -- no large earthquake follows.
2014
References Cited
Ambraseys, Nicolas N. (1971). “Value of historical records of earthquakes.” Nature,
232(5310), 375–379, August 6.
Barnes, J., ed. (1984). The complete works of Aristotle, the revised Oxford translation,
Bollingen Series LXXI-2, Princeton University Press, Princeton, NJ.
Berg, Glen. (1976). “Historical review of earthquakes, damage and building codes,”
Proceedings of the National Structural Engineering Conference, Vol. I, American
Society of Civil Engineers, New York, NY.
Canterbury.as.nz. (2009).
http://www.earthweek.com/2009/ew091030/ew091030d.html (earthweek 2009).
Evening post (1959). Photographic negatives and prints of the Evening Post newspaper.
Ref: PAColl-8557-50. Alexander Turnbull Library, Wellington, New Zealand.
http://natlib.govt.nz/records/23168329
Guidoboni, Emanuela. (1998). “Earthquakes, theories from antiquity to 1600.” Sciences
of the Earth: An encyclopedia of events, people, and phenomena, Gregory Good, ed.,
Garland, New York, NY.
Knauer, Kelly, ed. (2010). Great buildings of the world, TIME Home Entertainment
Inc., New York, NY.
Muto, Kiyoshi. (1930). “Gejunoto and earthquake,” Proceedings of the 1930 Meeting of
the Eastern Section of the Seismological Society of America, U.S. Bureau of Standards,
Washington, D.C.
Reitherman, Robert. (1980a). “Frank Lloyd Wright’s Imperial Hotel: A seismic
re-evaluation.” Proceedings of the Seventh World Conference on Earthquake
Engineering, Türkiye Deprem Vakfi (Turkish Earthquake Foundation), Istanbul, Turkey.
Reitherman, Robert. (1980b). “The seismic legend of the Imperial Hotel.” Architecture,
June.
Reitherman, Robert (2012). Earthquakes and engineers: An international history. ASCE
Press, Reston, VA.
Rouse, W. H. D. (1938). The Iliad: The Story of Achilles. Nelson, London, United
Kingdom.
Schaal, Rand B. (1988). “An evaluation of animal behavior theory for earthquake
prediction,” California Geology, 41(2).
Steinbrugge, Karl V. (1982). Earthquakes, volcanoes, and tsunamis: An anatomy of
hazards, Skandia America Group, New York, NY.
Ludwin, Ruth S. (2002). “Cascadia megathrust earthquakes in Pacific Northwest Indian
myths and legends.” Tsuinfo Alert, 4(2), April.
Stephen, R.M., Hollings, J. P., and Bouwkamp, J. G. (1974). “Dynamic behavior of
a multistory pyramid-shaped building,” University of California at Berkeley, EERC
73-17.
Milne, John. (1886). Earthquakes and other earth movements, Kegan Paul, Trench &
Co., London, 1st Ed., 1884.
Wright, Frank Lloyd (1955). An American architecture. Bramhall House, New York,
NY.

Earthquake Mythology

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