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ANNALS OF GEOPHYSICS, 60, 6, S0660, 2017; doi: 10.4401/ag-7437

Reliability of  first-hand accounts on the study of  historical
tsunamis in northeastern Venezuela (southeastern Caribbean Sea)

Franck A. Audemard M.1,* and Alejandra F. Leal Guzmán1

1  Earth Sciences Dpt., Venezuelan Foundation for Seismological Research -FUNVISIS-, Caracas, Venezuela

Article history
Received April 29, 2017; accepted July 29, 2017.
Subject classification:
Tsunami hazard; Inundation; Run-up; Strike-slip faults; Sliding; Caribbean.

S0660

ABSTRACT

The occurrence of tsunami waves on the eastern Caribbean Venezuelan
coasts during 5 Venezuelan (local) earthquakes (01-IX-1530, 15-VII-
1853, 29-X-1900, 17-I-1929 and 9-VII-1997), have been confirmed
through the search and evaluation of written accounts by primary
sources (eye witnesses) of tsunami inundation during these events.
Among the outcomes of this new assessment are: 1) the run-up heights
of several of those tsunamis have been substantially reduced. In fact,
maximum run-up heights for the 5 tsunamis are: 5-7 m at Cumaná for
the 1530 event, 5 m at Barlovento and 3 m at the Neverí mouth for the
1900 tsunami, 3 m at western Cumaná for the 1853 and 1929 events
and about 1 m for the 1997 earthquake. 2) These new estimates on wave
heights for local earthquakes restrict the search for tsunamites by
trenching and coring to mainly the first 500-m-wide strip from the
coastline in low-lying flatlands. The source of these tsunami waves may
be complex. Some are the result of coastal-submarine sliding (1929 AD,
1997 AD), tectonic slip on active strike-slip (or normal oblique slip)
faults (1530 AD, 1900 AD) or combination of tectonic slip and sliding
(1853 AD). Appropriate numerical modeling of tsunami wave genera-
tion, migration and inundation are urgently in need to understand
these tsunami mechanics.

1. Introduction
The 1983 National Inventory of Geologic Hazards

[Singer et al. 1983] and the 1999 Catalog of Felt/De-
structive Venezuelan Earthquakes (1530-1998); [Grases
et al. 1999] reliably report the occurrence of tsunami
waves on the Caribbean Venezuelan coasts, or phenom-
ena that might be interpreted as substantial sea level
modifications in the region, during local, regional and
extra-regional earthquakes, as well as related to other
natural phenomena. In this research, we narrow down
the focus of this investigation in 4 ways: 1) the tsunami
source is an earthquake (tsunamigenic earthquake); 2)
the earthquake has happened on a local (Venezuelan)

tectonic source; 3) Eyewitness (first-hand) accounts pro-
vide characteristics (actual occurrence, location, time,
inundation height, run-up and so on) of the tsunami; and
4) the tsunamis must have affected the eastern coasts of
Venezuela. The last constraint responds to the area ob-
jective of Project FONACIT 2013000361, which funds
the current research. This geographical constraint an-
swers to the potential favorable conditions of preserva-
tion of tsunamites along the low-lying coasts of the
Ensenada de Barcelona (Barcelona Embayment; from
Cabo Codera to Araya) envisaged from the early stages
of this investigation, as already proven by few pioneering
tsunamite studies [Leal and Scremin 2011, Audemard
2012, 2014, Oropeza et al. 2013 2015, Leal et al. 2014],
where most tsunami affectation in Venezuela in last cen-
turies is reported in both abovementioned catalogs (in-
ventories) [Audemard and Leal 2012, 2013, 2014, 2015].
In such research project, search of tsunamite by short
(over a 1 m long) coring and shallow-pit hand digging is
the geologic approach implemented to corroborate the
occurrence of past tsunamis in association with its local
tsunamigenic source. Last but not least, the use of first-
hand accounts seeks to optimizing reliability on occur-
rence and characteristics of individual tsunamis. This
research then is mainly substantiated by a documentary
assessment, which also includes last century pertinent
photographs to contextualize the event in time and
space, all supported with fieldwork observations on to-
pography, coastal geomorphology, river morphology
and hydrology, geological and natural coastal environ-
ments, and anthropogenic (cultural) aspects. All this is
carried out as to recreate the prevailing conditions at the
time of occurrence of each of the 5 events, to which
we would apply the ITIS 2012 [Lekkas et al. 2013] and
Imamura-Iida magnitude scale [Iida, 1963].



2. Offshore active faults of Venezuela
Northeastern Venezuela at present is the most seis-

mically active area nationwide, as documented by the
instrumental seismicity catalog of the Venezuelan Foun-
dation for Seismological Research -FUNVISIS- for the
period 1910-present (www.funvisis.gob.ve). In historical
times, the seismic activity was not much different, as in-
dicated by historical reports on damage in this region
by earthquakes and tsunamis from the dawn of the
Spanish conquest [Centeno-Graü 1940, 1969, Gómez
1990, Grases 1990, Grases et al. 1999]. Such colonization
started at the beginning of the 16th century with Nueva
Toledo in 1515, known today as Cumaná -the oldest
Spanish settlement on continental America-. In fact, this
city has been repeatedly destroyed to some extent dur-
ing historical earthquakes [Audemard 2007], such as in
1530, 1629, 1684, 1766, 1797 and 1853, as well as during
two events in the 20th century (1929 and 1997). 

All these events have been associated by different
authors to the El Pilar fault (EPF) that is considered to
be the second major seismic source in eastern
Venezuela after the southern end of the NW-dipping
slab of the Lesser Antilles Subduction zone that lies
under Trinidad and partly under the Paria Gulf and
Peninsula (Figure 1). The EPF, along with the right-lat-
eral strike-slip Boconó and San Sebastián faults, appears
to accommodate a large fraction of the dextral tran-
scurrent motion (Figure 1); [Molnar and Sykes 1969,
Minster and Jordan 1978, Pérez and Aggarwal 1981,
Stephan 1982, Aggarwal 1983, Schubert 1984, Soulas
1986, Beltrán and Giraldo 1989, Speed et al. 1991,
Singer and Audemard 1997, Pérez et al. 2001, Weber et
al. 2001, Audemard and Audemard 2002, Audemard et
al. 2005, Audemard 2006, Jouanne et al. 2011, Reinoza
et al. 2015, among many others] within the over a 100-
km-wide transcurrent-compressive plate-boundary
zone between the Caribbean and South America plates.
It is worth mentioning that the EPF active fault trace
to which this paper refers, corresponds to the fault
mapped by Beltrán et al. [1996]. This mapping is more
easily accessible from Audemard et al. [2000; Figure 2].
Audemard [1999, 2007, 2011], Altez and Audemard
[2008] and Audemard et al. [2007] have associated most
of the offshore historical destructive earthquakes in
eastern Venezuela (1530, 1629, 1684, 1797, 1853, 1929
and 1997) with EPF. Moreover, each of these events has
been associated with a particular segment of the fault.
For instance, the Mw 6+ earthquakes of 1629 [Altez
and Audemard 2008] and 1797 and 1929 [Audemard
1999, 2007, Audemard et al. 2007] have all broken in-
side the Cariaco Gulf, just east of Cumaná. Except for
the 1929 event, they seem not to have generated

tsunami waves in the Cariaco Gulf, which has signifi-
cant implications on the source mechanism for the 1929
tsunami waves. Likewise, the 1812 and 1900 large off-
shore earthquakes in North-Central Venezuela have
been associated to segments of the San Sebastián fault
(SSF), [Audemard 2002, Colón et al. 2015].

3. Tsunamigenic earthquakes
From a recent chronology of tsunami reports in

Venezuela compiled by Oropeza and Audemard [2016]
from published data, which essentially gathers only
tsunami data from 6 catalogs [Centeno-Graü 1940,
Singer et al. 1983, Grases 1990, Grases et al. 1999,
O’Loughlin and Lander 2003, Altez and Rodríguez
2009] and a published paper [Schubert 1987], just five
local earthquakes out of 24 events with clear reports of
sea surface perturbations, have affected the Eastern
Venezuela coasts, which are, in sequence: 1-IX-1530, 15-
VII-1853, 29-X-1900, 17-I-1929 and 9-VII-1997 (Figure
3). Although the 1766 event is the largest earthquake in
Eastern Venezuela, it has dubious evidence of
tsunamis; probably related to the fact that it is an in-
termediate depth event [Audemard 2007, Mocquet

AUDEMARD AND LEAL GUZMÁN

2

Figure 1. Simplified geodynamic framework of Northern South
America (from Audemard et al. 2000]. Abbreviations: BF Boconó
fault; EPF El Pilar fault; LBF Los Bajos-El Soldado fault system;
OAF Oca-Ancón fault system; SSF San Sebastián fault.

Figure 2. Quaternary fault map of northeastern Venezuela [after
Audemard et al. 2000]. VE-13 identifies the El Pilar fault (EPF) and
the suffixes (a through d) label the different individual fault portions
or segments. Epicenters of the 1929 and 1997 earthquakes are
shown as solid circles. Faults in red have had fault surface ruptures,
or portions of it, mapped.



3

RELIABILITY OF TESTIMONIES ON VENEZUELAN HISTORICAL TSUNAMIS

2007]. All but the 1900 event, whose several proposals
of epicenter locations all lies in North-Central
Venezuela, have been generated by the EPF. Instead,
the 1812 tsunami, also generated by the San Sebastían
fault (SSF) offshore North-Central Venezuela, is not
herein treated, because its hypocenter lies too far west
and seems not have affected Eastern Venezuela. The
1900 AD event is the second largest earthquake (Ms 7.6)
[Pacheco and Sykes 1992] in magnitude in the Venezue-
lan seismic catalog, after the 1766 event (Mw 7.8),
whose felt area is twice as large as the surface of the en-
tire country, but the 1900 AD event is the largest earth-
quake of all times at crustal depth. All five
tsunamigenic earthquakes are considered to be crustal
events [e.g., Audemard 2007, Colón et al. 2015].

The 1900 AD tsunami waves were reported along
most of the Ensenada de Barcelona coast (Barcelona
Embayment, W of Cumaná) and Los Roques
Archipelago (Figure 3 and inset), being this quake at-
tributed to the SSF segment running offshore Cabo
Codera by Colón et al. [2015], based on fresh seafloor
scarps detected by high resolution shallow reflection
seismics in 2007. After Audemard [1999, 2007], the 1530
and 1853 earthquakes were produced by the Cariaco
Trough segment of the EPF west of Cumaná, within a
restricted over-1000-m-deep marine pull-apart basin on
the SSF-EPF right-lateral releasing step-over (Figures 2

and 3), whereas the 1929 and 1997 events occurred on
the EPF segment east of Cumaná, inside the <100-m-
deep Cariaco Gulf (Figure 2). Several authors have in-
terpreted all those four tsunamis as the result of major
submarine sliding inside the steep-walled trough. First-
hand accounts by locals about the abnormal waves dur-
ing the Cariaco 1997 event, as well as the identification
of coastal sliding at the Manzanares River mouth at
Cumaná [González et al. 2004], support this hypothesis
at least for the two latest events, because of the small
size of the tsunami-affected area (Figure 3). In addition,
recent seafloor monitoring [CARIACO Project; e.g.,
Thunell et al. 1999, Lorenzoni et al. 2012] has recorded
turbidite currents in the Cariaco Trough and the Man-
zanares Canyon -the latter connecting the Manzanares
River mouth to the eastern deep basin of the Cariaco
Trough-, during the Cariaco Mw 6.9 earthquake, and
also with a smaller, Mw. 5.2, August 2008 event. How-
ever, the 1900 tsunami, and the 1530 and 1853 tsunamis
by extension, appears to result from right-lateral tec-
tonic slip along the Cariaco Trough walls [Audemard
and Leal 2012, 2013]. However, Aguilar et al. [2016], in
order to explain an improved water exchange between
the Cariaco Gulf and open sea since around 1850 AD,
which has made the gulf waters more salty in more re-
cent times, propose that the submarine Salazar Sill slid
during the 1853 earthquake, thus deepening and en-

Figure 3. Map of eastern Venezuela extracted from Google Earth showing the different localities with confident eye-witness reports of
tsunami inundations, or sea surface oscillations, during local historical and instrumental earthquakes. Epicenters of historical and 1929
earthquakes are indicated by stars, whose epicentral coordinates are provided in Table 1. Relative location of Figure 11 is also depicted.



larging the gulf entrance north of Cumaná, and in-
creasing open sea water inflow. In such a case, the
tsunami waves during this event could have resulted
from an enhanced combination of tectonic slip and
submarine sliding.

4. Description of historical tsunamis from first-hand
accounts 

As mentioned earlier, this study intends to explore
how first-hand or eyewitness accounts can be used to
better constraining tsunami inundation and tsunami
height and run-up elevation for the five earthquakes that
are known from earthquake (and/or tsunami) catalogs
to have inundated a locality or several of them along the
Barcelona Embayment coasts. To do this, we have
started this assessment by looking into the most recent
historical event (the January 17th, 1929 earthquake) that
should logically have the largest number of and more
detailed accounts, which happens to be the case.

4.1 The January 17th, 1929 tsunami 
For this earthquake, the occurrence of tsunami

waves at the city of Cumaná is repeatedly reported. For
instance, Centeno Graü [1940] indicates:“El mar se retiró
de la playa como 200 mts y vino después a la costa una ola
como de 6 metros de altura que barrió parte de las casas de la
playa.” (The sea retreated some 200 m and came back
to shore as a 6 m high wave that washed down houses
on the beach; Free translation by authors -FTBA-).
Paige [1930] reports “A tidal wave followed the earth-
quake causing much damage.” The front page of the
Caracas newspaper La Esfera on January 19th 1929 says
“…embarcaciones de caleta que se encontraba en el muelle de
Puerto Sucre fueron alejados al mar; éste, embravecido, lanzó
sus aguas hacia la población, en sentido inverso a una tromba
de lo que envolvió completamente al “Commewynne” y otras
embarcaciones, de las cuales algunas naufragaron. El men-
cionado vapor holandés se vio juguete de olas y sólo, gracias
a la entereza de su capitán que ordenó hábiles maniobras, a
posibles contingencias”. The FTBA is as follows: “An-
chored boats at Puerto Sucre -Cumaná seaport- were
pulled offshore; the sea returned with strong surfs to
the village, wrapping completely the steam vessel
Commewynne and other boats, of which some sunk.
The Dutch steam vessel (Figure 4) seemed like a toy
and only skillful manoeuveurs of its capitain saved it”.
This is confirmed by another Caracas newspaper on the
same day January 19 (El Nuevo Diario), which ex-
presses “…en Puerto Sucre, donde los daños fueron menores,
hubo un violento mar de eleva. El vapor holandés por esta
causa, tuvo que retirarse varias veces hacia alta mar,
volviendo luego a la Costa. ….Los botes amarrados al costado

del muelle se anegaron por completo.”The translation goes:
“In Puerto Sucre (Figures 5 and 6), where damage was
minor, there was a violent tsunami wave. The Dutch
steamboat, due to the tsunami waves, had to sail to
open sea several times, later returning to shore. …Boats
tied to the pier sides were completely drowned”. Three
days later, the same newspaper publishes the following:
“Dos detalles impresionantes del terremoto fueron el desbor-
damiento del río Manzanares, que en su curso atraviesa la
ciudad, cuyas aguas arrastraron cuanto encontraron a su
paso, causando enormes daños. Fue el otro la invasión del
mar que, elevándose en una marejada de nueve pies sobre su
nivel ordinario, se lanzó sobre “El Salado”, inundándolo to-
talmente. Este caserío sufrió considerablemente. La mayoría

AUDEMARD AND LEAL GUZMÁN

4

Figure 4. Typical Dutch vessel, named El Holandés, that came to
Pto Sucre seaport, Cumaná, in the first half of the 20th Century
(Anonymous photographer).

Figure 5. Ground view of the Puerto Sucre seaport, Cumaná, in
1925, 4 years before the 1929 earthquake. The wooden pier and
shelter structures appear rather slim. In the far background, a typ-
ical steam boat of the time is anchored, as well as a sailing boat of
the sloop type. On the foreground, “piragua” type boats, which are
much different from the freshwater canoe or pirogue boats carved
by Indians into a single trunk.



5

RELIABILITY OF TESTIMONIES ON VENEZUELAN HISTORICAL TSUNAMIS

de sus viviendas, todas gente pobre y trabajadora, quedaron
casi destruidas.” (Two impressive facts of the earth-
quake were the overflowing of the Manzanares River
that crosses the city, whose waters destroyed every-
thing, causing much damage. And the other was the sea
invasion, which with an abnormal height of 9 feet
struck El Salado -a small fishermen settlement on the
southern bank of the Manzanares mouth (Figure 7);
now being part of Cumaná-, flooding it completely.
This settlement suffered considerably. Most of the
dwellings, belonging to poor and labor people, were al-
most destroyed -FTBA-). The same newspaper on
March 03, several weeks after the earthquake and
tsunami, says: “El mar por un momento se retiró para luego
tornar formando una extensa marejada de gran elevación,
que inundó la población situada en el puerto…. El Río hinchó
violentamente sus ondas que se llevaron por delante cuanto a
su paso encontraron”. Translated into English: “The sea
for a short spell retreated to return later as a tsunami
wave of big height…… The river swelled violently de-

stroying everything at its passage”. The last first-hand
account we could find appeared on the nationwide
newspaper El Universal on March 22, 1929. It indicates
“…en el preciso momento de la catástrofe algunos pescadores
cuyas barcas estaban ancladas en Puerto Sucre vieron ame-
nazante hacia el Norte franco una negra y formidable nube
que se levanta sobre las aguas del mar, y que creyendo fuera
una borrasca o chubasco marino dieron la voz de alarma es
decir, de amarrar o de asegurar sus embarcaciones, de la cual
no tuvieron tiempo, pues al instante estalló el cataclismo y
una ola colosal los arrojo con sus barcos sobre la playa”
(…right at the moment of the catastrophe, some fish-
ermen, whose boats were anchored at Puerto Sucre
(Figures 4 through 6 and 8), saw an amazing and black
threatening cloud rising over the sea due North, and
believing it was a storm, gave the alarm of fastening
and securing the boats, but in such a short notice and
having not enough time, a colossal wave rafted the
boats ashore).

These several accounts provide very useful infor-
mation for the understanding of what precisely hap-
pened during the January 17th, 1929 earthquake and
tsunami that struck Cumaná, and particularly its west-
ern coast, extending between the Manzanares River
mouth to the North and the city port named Puerto
Sucre to the South, and affecting the fishermen village
of the El Salado sitting on that coast stretch. It is worth
noting that this western coast stretch of Cumaná, al-
though in a partly-protected large embayment opened
to sea towards the West, is more exposed to open sea;
reason why the seaport sits there. Being this city well

Figure 6. Aerial photograph of the seaport of Cumaná, known as
Puerto Sucre, after the 1929 earthquake, during the phase of recon-
struction and upgrading in the 1930. In this view, the narrow light-
colored coastal sand barrier is easily recognizable along seashore. In
the same way, the salt flats, of lower elevation than the barrier, are
identifiable because of being flooded, particularly in the upper left
corner of the picture. From the size, the boats appear to be “pi-
raguas”, except for the large sloop tied to the pier. Instead, some
“peñeros” (small wooden rowing fisherman boats) lie on the beach.

Figure 7. NW-looking bird-eye view of the Manzanares River
mouth, in 1957, embanked on both sides. River width close to the
mouth is in the order of some 50 m. On the right (northern bank)
used to sit the Francis Rodel fish cannery, in the El Dique neigh-
borhood. On the southern bank has developed the El Salado
neighborhood; largely affected by most tsunamis that has struck
Cumaná through the years. The steel bridge, which used to exist
during the first author’s youth, was named Aristides Rojas. Co-
conut tree plantations are visible along the river margins. Photo-
graph by Gerardo González.



known to the first author, this allows describing the pre-
event scenario rather profusely. The city of Cumaná has
grown on a salt-flat (Figure 9) that had to be progres-
sively artificially filled to be constructed and urbanized
through the years. Cumaná suffered from inundation
after every single large rain or pour (Figure 10). This sit-
uation was later overcome with the construction of the
city drainage system in the 70’s, accompanied by the de-
sign and construction of a spillway for the Manzanares
River. The salt-flat originally formed behind a coastal
sand barrier that hardly reaches 1.7-2.0 m amsl in eleva-
tion, and the salt flat floor used to be close to a 1 m
below msl (Figures 9 and 10a). Salt exploitation by locals
was still a common practice in 1960’s. It also implies that
tsunami wave height and inundation height (flow depth)
or run-up height at Cumaná is about the same. It is of
major importance to indicate that tidal range along the
Venezuelan coast is less than 35 cm. Therefore, time of
tsunami with respect to tide height plays almost no role
on the inundation height. In terms of typical navigation
vessels, it is relevant to mention that fishermen in north-
eastern Venezuela in the first half of the 20th century
most frequently used “Piragua” boats that are 6 to 10 m

long and have a draught between 1 and 2 m depending
on the load aboard, which are still in use by present-day
fishermen (Figures 5 and 8).

From all these accounts, the tsunami wave height
retained by most scientists is the one from Centeno Graü
[1940] of 6 m. It is the most straightforward and no in-
terpretation is needed. But we have to bear in mind that
Centeno Graü’s work is a catalog in itself; in other words,
the result of a compilation and not a first-hand account.
However, this value can be in some way tested, and even
contested. As a matter of fact, another account indicates
only 9 feet high waves (some 3 m; El Nuevo Diario of
January 22nd, 1929). Another estimate of the wave height
can be derived from the following facts: A) The anchored
boats at Puerto Sucre (probably of the Piragua type; Fig-
ures 5, 6 and 8) were rafted ashore by the waves; being
these boats no more than 3 m deep and exhibiting
draughts between 1 and 2 m, and taking into account
that the coastal sand barrier is about 1.5 m high, to
abandon the boats at the shore, as mentioned in the
account, the tsunami waves were hardly over 3 m in
height. If run-up height had been larger, the boats
would have been abandoned much farther inland. B)

AUDEMARD AND LEAL GUZMÁN

6

Figure 8. Modern equivalents to the boats that could have been tied to the Puerto Sucre pier in 1929: “Piragua” in the far background
and “Peñero” in the foreground.



7

The fact that the “Commewynne” steam-boat at Puerto
Sucre could sail out to sea repeatedly, it implies that
the captain had time to respond to arriving tsunami
waves, which were not large and powerful enough to
drift the ship ashore. C) Several boats tied to the pier
drowned. If these boats also are of the Piragua type

(Figures 5, 6 and 8), a 2-3 m high wave would be largely
enough to sink boat that could not freely float. And D)
The sea along the west coast of Cumaná, whose sea-
bottom is very flat, retreated some 200 m before re-
turning and overflowing the sandy beach. If this is
compared to the first author’s observations collected
during the 1997 event [González et al. 2004], a sea re-
treat along the same stretch of beach of a 100 m, al-
lowed estimating a wave height in the order of a 1 m.
By analogy, at constant beach slope gradient, the re-
treat of some 200 m during the 1929 tsunami would
be equivalent to a wave of a couple of meters at most.

From these observations several other conclusions
can be drawn: 1) several waves seem to have happened.
2) Most eyewitnesses at Cumaná first report a sea re-
treat, like for the 1997 earthquake. 3) The tsunami
wave are reported on the west coast of Cumaná, on
the open seaside, completely opposed to the earth-
quake epicenter proposed by Mocquet et al. [1996] and
Audemard [1999, 2007],(Figures 2 and 3), which lies in-
side the Cariaco Gulf. Therefore, it should be consid-
ered that this tsunami is necessarily related to a
submarine slump or slide occurring in the Cariaco
Trough, and probably inside the submarine Man-

RELIABILITY OF TESTIMONIES ON VENEZUELAN HISTORICAL TSUNAMIS

Figure 9. Bird-eye view to the west of Cumaná in 1950, showing
T intersection between Los Mangles (future Perimetral) and Fer-
nández de Zerpa avenues. In the foreground, notice salt deposi-
tion. Puerto Sucre seaport is visible above the trees. In the far
background, the shape outline of the relief of the Eastern Inte-
rior Range stands out.

Figure 10. Cumaná, a city prone to past flooding. a) View to south of the future Perimetral Avenue, at El Dique in 1960, with Aristides
Rojas bridge over the Manzanares River in background. Small ponds attest to recent rains. Note typical vegetation: coconut trees on the
riversides and mangrove trees in the foreground (Picture by Gerardo González). b) Cancamure Avenue flooded after heavy rain. c) All
flooded around the El Indio roundabout in the 1960’s (Picture by Vitorio De Benedetto). d) Las Palomas sector, upstream of the Aristides
Rojas bridge, inundated by Manzanares River overflow in 1960’s (Picture by Vitorio De Benedetto). These flooding problems were min-
imized with the construction of a diversion channel, pouring to the east into the Cariaco Gulf in the 1970’s.

a) c)

b) d)



zanares Canyon, in a similar way to the tsunami wave
reported during the 1997 earthquake, which shows ev-
idence of subaerial sliding at the Manzanares river
mouth [González et al. 2004], whose turbidite currents
into the Cariaco Trough were reported by Thunell et
al. [1999] and Lorenzoni et al. [2012]. And 4) Two first-
hand accounts (El Nuevo Diario on 1929/I/22 and
1929/III/03) report the rise of the Manzanares River
waters along its final stretch, overbanking and flood-
ing along the river course. This seems to point out to
generation of a riverbore at the river mouth.

Applying the ITIS-2012 tsunami intensity scale
proposed by Lekkas et al. [2013], the western coast of
Cumaná, stretching from Puerto Sucre to the Man-
zanares River mouth, can be classified as intensity VII
(damaging) to VIII (heavily damaging), based on boats
drifted ashore and damage grade 4 to dwellings of high
vulnerability (classes A and B), respectively. Using the
same level of damage, according to Imamura-Iida
magnitude scale [Iida, 1963], this tsunami should be
graded 1, to which would correspond a wave height
range of 2 to 5 m, which appears to be consistent to
one of the eye-witness accounts, as well as to our eval-
uation. ITIS-2012 also indicates that tsunami wave for
intensity VIII is expected to be higher than 2 m, but
smaller than 5 m (corresponding to intensity IX).

4.2 The October 29th, 1900 tsunami 
For the October 29th, 1900 earthquake-tsunami,

the first-hand accounts tell us a similar story. The news-
paper la Linterna Mágica, on November the 2nd, pub-
lishes: “En el Puerto Tuy el mar se separó como ocho
cuadras, y luego se vino encima de la playa una gran mole de
agua como de diez metros de altura que anegó los almacenes.”
(At Puerto Tuy (Figure 11), sea retreated like 8
“cuadras” -about 1 km; a “block” ranges between 100 a
150 m in length-, and then returned onto the beach as
a huge wall of water of about 10 m high, which flooded
the warehouses -FTBA-). Another account in the same
newspaper indicates that: “Una parte del pueblo de Paparo
se hundió en el agua, quedando las casas sólo con la mitad
afuera.” (A portion of the village of Paparo (located
next to seashore; Figure 11) was drowned, being only
the upper half of the houses sticking out -FTBA-). On
La Religión of November 6th, the following note was
found: “En San José, población situada a menos de dos
millas de Río Chico, se desbordó el río que atraviesa el pueblo
en ambas márgenes, bañando las calles y luego se volvió a su
cauce natural, siendo más grave este fenómeno cuanto que
una de las márgenes del río San José tiene cuatro metros de al-
tura. El mismo fenómeno se verificó en todo el curso del río,
brotando a tierra un sinnúmero de peces que sirvieron de ali-
mento a la población en aquellos instantes de pavor; y de di-

AUDEMARD AND LEAL GUZMÁN

8

Figure 11. Google Earth map of the Barlovento coast between the Tuy and Guapo river mouths. All accounts from this region as to the
1900 tsunami come from this stretch of low-lying flat coastal plain.



9

vertimento durante todo el día a los chiquillos (...) Media
hora después del cataclismo crecieron las aguas de los ríos sin
que antes ni después de aquel aciago momento hubiese llovido
en sus lechos.” (In San José, village located less than 2
miles from Río Chico (Figure 11), the river that crosses
town flooded over on both sides, watering the streets
before returning to its natural riverbed. This is even
worse if considering that one of the river bank is 4 m
higher than the river course. This was seen all along the
river course, throwing on land countless fish that fed
the population during those dreadful days; and were
used as toys by kids the day long ….. Half an hour after
the cataclysm, the river waters were raised without any
rain before or after that terrible moment -FTBA-). 

To understand the relevance of these accounts, the
coastal area of Barlovento, along the Barcelona Em-
bayment shore, needs to be described (Figures 3 and
11). The Barlovento Depression exhibits a flat-lying to-
pography, bounded by a sandy beach that is usually less
than 1.7 m high. This alluvial plain extends far inland
with almost no relief for tens of kilometers, being the
villages of Paparo (ca. 0.7 km inland), San José (ca. 7.5
km inland) and Río Chico (ca. 5 km inland) not far from
the coastline, while Puerto Tuy sits right on the beach,
at the mouth of the Guapo River (Figure 11). The Oc-
tober 29th, 1900 earthquake strikes this region before
sunrise, still at full darkness (4:40-4:45 am local time)
and the tsunami, as mentioned by one of the accounts,
strikes the region around half an hour later, still at dark.
We still actually wonder how an eyewitness could reli-
ably see anything at nighttime, and furthermore, how
he could survive a 10 m high wave in an area with nei-
ther any natural elevation nor vertical escape except for
tall trees. If the other accounts are analyzed in detail, it
would be more appropriate to believe that riverbore ac-
tually took place, in which case, the water elevation
could reach up to 3-4 m, eventually to 5 m above
riverbeds at most at up to 7 km inland from coastline,
considering that houses were half drowned and they
were on river banks (inundation height of 1.5 m above
alluvial plain at most; equivalent to mid-height of ba-
hareque houses), which are 3 to 4 m above the riverbed
in normal conditions.

At Los Roques Archipelago (Figure 3 inset), Es-
píndola [1900] writes a note, entitled El terremoto en Los
Roques, in the newspaper La Religión, which appears
published a week after the event (on November 06th,
1900). A pertinent extract goes: “Una fuerte conmoción
seísmica se ha sentido en esta isla y los islotes circunvecinos
a las 4 y 40 minutos de la madrugada de hoy (...) Se oyeron
estampidos sordos, como de poderosa artillería, la atmósfera
se oscureció por largo tiempo y el mar se retiró mugiendo a

muchos metros de la playa. Los tripulantes de las embarca-
ciones que han llegado a este puerto en lo que va ocurrido del
día, y que navegaban en los canales de estas islas, me dicen
haber oído las mismas detonaciones, al tiempo que sintieron
sacudidas violentas y una agitación extraña en las aguas”.
Our free translation (FTBA) goes: A strong shaking was
felt on this island [Gran Roque] and other smaller keys
at 4:40 am today (...) Booms were heard, as those of
powerful artillery, sky got dark for quite a while and sea
retreated mooing at many meters from the beach. Ship
crews who have disembarked during the day, and were
sailing between the archipelago islands, tell me they
have heard the same booms, at the same time that they
felt strong shaking and a strange motion of sea waters.

Combining, the descriptions of towns sitting on
Barlovento seashore and Los Roques Archipelago, we
could say that the 1900 earthquake epicenter would ap-
parently seem closer to Los Roques than Paparo and
San José, based only on earthquake noise hearing. Since
there is no noise reporting at the southern site, we do
not know if it corresponds to an actual lack of noise or
a lack of description by locals. On the other hand, this
tsunami waves exhibit a striking feature. Both at Los
Roques Archipelago and Barcelona Embayment at
Barlovento, significant initial sea retreat has been re-
ported, about 1 km in Barlovento and “many meters” at
Gran Roque. Considering the tsunami could be even-
tually triggered by tectonic slip along the SSF, each of
the 2 abovementioned sites sits on opposite sides or
blocks across the fault, where initial water oscillations
would be expected to behave in opposed manner.
Would this imply a submarine slide origin, or even any
other source, for this earthquake-related tsunami, as
proposed by other previous authors??

From the damage to buildings at Barlovento,
where dwelling and warehouse drowning seems a com-
mon feature nearshore (Puerto Tuy) and several kilo-
meters inland (Río Chico and San José de Río Chico),
inundation appears not to be catastrophic but rather
slow instead, more like a rising flood, suggesting that
riverbore took place at the lowermost stretch of several
rivers. Then, assigning an ITIS-2012 intensity level is not
straightforward. Inundation during this tsunami is re-
ported up to 7.5 km inland but only close to river. Lit-
tle flow damage seems to have been recorded by
dwellings. From damage descriptions, it appears to
range between IV (largely observed) and V (strong).
However, damage might have been minimized by the
height of terrace risers (about 4 m above riverbed), on
which houses were built, and inundation progression
substantially slowed down by dense tall tropical vege-
tation few kilometers inland. If tsunami height (or

RELIABILITY OF TESTIMONIES ON VENEZUELAN HISTORICAL TSUNAMIS



tsunami flow depth enhanced by riverbore effect of 4.5-
5.0 m) is taken into consideration, the intensity of this
tsunami may reach as high as IX (destructive). Mean-
while, at Los Roques Archipelago, intensity V (strong)
may be assigned on the basis of most boats, while sail-
ing between islands of the archipelago, felt strong
water shaking. 

Centeno Graü [1900], a young civil engineer who
would compile the first seismic catalog of Venezuela
many years later [Centeno Graü, 1940], writes a note
in the newspaper La Linterna Mágica, on November
15th, 1900, entitled Interesantísimo estudio. The follow-
ing extract refers to the tsunami effects around
Barcelona: “En el mismo puerto "El Rincón" que he men-
cionado anteriormente, uno de los caños del río Neverí se an-
gostó como más de 2 metros, los árboles de sus riberas están
arrasados como por un temporal. Este caño está en terreno
de aluvión muy reciente. El nivel de las aguas del Neverí se
levantó a juzgar por uno de los caños: el de Puente Colorado.
Este caño no corría desde hacía tiempo porque su embo-
cadura, con los detritus y sustancias vegetales, quedó más
alta que las aguas del Neverí. Al día siguiente del movimiento
seísmico y en mis exploraciones noté que dicho caño estaba
corriendo en abundancia. A los pocos días volví, y ya no
corría. Fui a su embocadura, y me cercioré que esta es más
alta, con un metro, que el Neverí”. FTBA is as follows: In
the same El Rincón seaport that I mentioned before, a
channel of the Neverí River (Figure 3) got narrower in
more than 2m, and the trees on its riverbanks are torn
down like by a strong wind. This channel incises very
recent alluvial sediments. Water level of the Neverí
River seems to have been raised, based on one of its
channel, the one under the Colorado Bridge. This chan-
nel had been dry for a long time because sediments and
dead trees at its mouth raised its river bed above the
Neverí waters. The day after the earthquake, during my
field explorations, I observed running water in that
channel. Few days later, it went dry again. I went to its
mouth, and confirmed it was a meter higher than the
Neverí River level.

The detailed descriptions by Centeno Graü [1900]
clearly attest to his observational skills, not only as an
engineer but also as a naturalist. By the way, the best
descriptions of damage by this earthquake were un-
doubtedly his. He even estimated the possible epicen-
tral area of this earthquake [see Colón et al. 2015 for
more details). Based on his observations on water lev-
els and relative river bed heights narrated above, we
have estimated that water level has been raised at El
Rincón seaport by about 2 m, eventually 3 m, since
water was running on the higher and commonly aban-
doned channel of the Neverí River. In addition, river-

bore seems to have happened here as well, enhancing
the coastal flooding at the Neverí River delta. In addi-
tion, the fact that trees (of unknown species and ro-
bustness) are torn or broken down along the river
channel, it allows estimating the run-up height at least
at 3 m. This effect (generation of garbage) in the envi-
ronment allows to classify it as intensity VII [damag-
ing; Lekkas et al. 2013] at least. The herein estimated
tsunami wave height may upgrade it up to intensity
VIII (heavily damaging). Collected damage descriptors
are useless to assign an Imamura-Iida magnitude (Iida,
1963], but can be classified as grade 1 from estimated
tsunami wave height.

Summing up: 1) the tsunami associated to the 1900
earthquake was recorded at three sites (Figures 3 and
11): A) Gran Roque and others keys of Los Roques
Archipelago, B) Barlovento coast (between Paparo and
Puerto Tuy) and as inland as Río Chico (5 km from
seashore) and San José de Río Chico (7.5 km from coast-
line), both on margins of the Río Chico River, and C)
Neverí River mouth, at El Rincón seaport (Barcelona).
2) Riverbore is common to most localities on the
Barlovento coast (Figure 11): Paparo next to Tuy River
mouth, Puerto Tuy at El Guapo River mouth, and Río
Chico and San José de Rio Chico along the Río Chico
River. Same situation happens at El Rincón seaport,
near El Dorado Bridge. 3) Sea retreat was noticed at
Gran Roque and at Barlovento; up to 1 km at the latter
one. No observation has been found for Barcelona yet.
4) Maximum run-up height is: A) 5 m above river level
(1.5 m above alluvial plain) along the Río Chico River,
B) at least 3 m above the water level of the Neverí River
at El Rincón seaport (Barcelona); and C) less than
coastal sand barrier height at Gran Roque leeward side
(less than 1.5 m). From the number of tsunami reports
and their spatial distribution (size of their felt area), this
is the largest tsunami of all tsunamis produced by a
local earthquake in eastern Venezuela. In fact, based on
the extent of the area with tsunami reports, which is in
the order of 250-300 km long (distance between Los
Roques Archipelago and Barcelona; Figure 3), the mag-
nitude of this tsunami would be less than 3, and most
likely magnitude 2, by applying the Imamura-Iida
tsunami magnitude scale [Iida, 1963].

4.3 The July 15th, 1853 tsunami
Five different eyewitness accounts tell us about this

earthquake and its associated tsunami. All accounts re-
port on Cumaná, but two of them refer to a strong af-
tershock that took place on August 3rd, almost 3 weeks
later. These two accounts also provide information
about two other localities: Barcelona, which is located

AUDEMARD AND LEAL GUZMÁN

10



11

some 30-40 km WSW of Cumaná and farther into the
Barcelona Embayment, and the Coche Island (Figure 3). 

The first account that we could find, says: “El mar se
retiró algunas varas al principio del terremoto, y como si hu-
biese recogido sus fuerzas, volvió después con un ímpetu ex-
traordinario penetrando más de cien varas en todo el rededor
de la población. Algunos chorros de aguas termales brotaron de
repente y las aguas del Manzanares, que divide la población,
se elevaron algunos pies en ese instante” (Anonymous eye wit-
ness, 1853; La catástrofe de Cumaná. Folletos, Academia Na-
cional de la Historia, Caracas).FTBA goes more or less like
this: “Sea got away some rods [vara = 0.835 m or about
33 inches] at the beginning of the earthquake, and as if
it had put together all its strength, came back with an ex-
traordinary rush, invading over a hundred rods [>85 m]
all around town. Some hot water springs suddenly ap-
peared and the waters of the Manzanares River, which
run across town, were then raised few feet”.

“Como ahora siglos, el mar inundó una gran parte del
Salado. Se desbordó el rio Manzanares que atraviesa la ciu-
dad” (Diario de Avisos y Semanario de las Provincias, Cara-
cas: 27 de julio de 1853). This second account can be
translated as follows: “Today as few centuries ago [prob-
ably referring to the predecessor 1530 tsunami], sea in-
undated a large portion of El Salado [coastal
neighborhood of Cumaná]. The Manzanares River that
crosses the city, flooded over its banks” (FTBA).

The two following accounts refer to the large af-
tershock felt in Cumaná, in August 3rd, 1853. “Se nos in-
forma al poner en prensa este número que el 3 del corriente ha
sufrido Cumaná otra fuerte conmoción de tierra que ha
derribado muchas de las casas que quedaban en pie después
del terremoto del 15. El Neverí se ha desbordado, inundando
gran parte de la ciudad de Barcelona” (Diario de Avisos y
semanario de las provincias, Caracas: 10 de agosto de 1853).
Translation (FTBA) goes: “We have been informed
when printing this issue (of Diario de Avisos y semanario
de las provincias in Caracas on August 10th, 1853) that
Cumaná on August 3rd has suffered another strong
ground commotion (shaking), which has pulled down
many of the still standing houses spared by the earth-
quake on the 15th. The Neverí [River] has flooded over,
inundating most of the city of Barcelona”. From this
account, it is still unclear to the authors when the
Neverí flooding occurred: on July 15th during the main
shock or on August 3rd with the large aftershock?
Grases et al. [1999] relate the account on the Neverí
flooding to the aftershock.

“El último temblor de esta ciudad [Cumaná] tuvo lugar
en la noche del 3 de Agosto. Asegúrase que surgieron manan-
tiales de agua subterráneos, y que el mar volvió a invadir parte
de la costa por el lado del Dique, dejando una profundidad de

14 brazas” (Diario de Avisos y semanario de las provincias,
Caracas: 13 de agosto de 1853). The translation (FTBA)
goes: the last earthquake in Cumaná happened on the
night of August 3rd. People are persuaded that under-
ground waters were spouted, and sea invaded again the
coast by El Dique [neighborhood of Cumaná located
on the northern bank of the Manzanares River near its
mouth; Figures 7. 9 and 10a]-, leaving a depth of 14
fathoms [≅ 25 m; a fathom is equivalent to 6 feet or 1.8
m approximately]”.

The fifth account seems to confirm most of what
the eyewitness of the first account reported: “El mar,
salvando sus límites conocidos inundo en una extensión de
200 varas, las sabanas del Salado y Caigüire, sumergiendo
un alijo cargado de maíz, que acababa de llegar a la playa.
Una embarcación sintió intensamente el sacudimiento en
frente de la isla de Coche” [Beauperthuy 1853]; Otra relación
del terremoto de Cumaná En: Diario de Avisos y semanario
de las provincias, Caracas: 10 de septiembre de 1853). This
report goes: “Sea, leaving its known limits, inundated
an extension of 200 rods [about 170 m; vara ≅ 33
inches or 85 cm] in El Salado and Caigüire flatlands,
drowning a corn supply or stockpile, which had just
arrived to the beach. A boat felt strong shaking off
Coche Island (Figure 3).

From these five accounts, several facts can be de-
duced: 1) A large aftershock on August 3rd accompa-
nied the July 15th main shock, and both were felt in
Cumaná. 2) The 1853 tsunami is not the first one suf-
fered by Cumaná. When describing the 1853 event, the
writer mentions it is not the first time that El Salado is
drowned by tsunami waves. 3) The sea retreated at
Cumaná before inundating the city on July 15th, 1853.
4) Inundation was in the order of a hundred to two
hundred “rods” (varas) on flat-lying areas such as
Caigüire or El Salado (in fact, salt-flats; Figure 12); in
other words, actual inundation was between 85 to 170
m inland. 5) Inundation takes place preferentially along
rivers, both the Manzanares in Cumaná and Neverí in
Barcelona. 6) Caigüire is also inundated; not only El
Salado. Caigüire lies at the former east end of Cumaná
(in 1960’s), on the southern coast of the Cariaco Gulf
entrance (Figure 12), and not on open sea, such as El
Salado or El Dique. 7) It is still unclear to us whether
the Neverí inundation happened during the main
shock on July 15th or a large aftershock on August 3rd,
because of the way the news is reported. We however
suspect it is associated to the main event. 8) The sea
surface shaking is spotted off the coast of Coche Is-
land, to the north (Figure 3). 9) Maximum run-up
height is not easily discernable. For instance, the first
account expressly says: “Manzanares River waters were

RELIABILITY OF TESTIMONIES ON VENEZUELAN HISTORICAL TSUNAMIS



raised few feet”, near the river mouth (El Salado),
while the second one indicates that went over its
banks. Nowadays, the Manzanares River near its
mouth hardly incises down by a meter or so (Figure
13). This would imply that tsunami height, better to
say riverbore height, would have needed to be over a
meter (or two?). But the fifth account brings additional

information about this inundation in low lying flat-
lands or saltflats. Beauperthuy [1853] says that a corn
stockpile on the beach was drowned. In doing so,
tsunami waves would have required to be at least 2 to
3 meter high to go over both the coastal sand barrier
and the corn supply sitting on it, since the current
sandy beach around El Salado and Caigüire is already
about 1.5 m high. This maximum run-up height of
about 3 m seems to be in good agreement with some
200 m of tsunami inundation. Hafeez [2008] measured,
after the December 2004 Indian Ocean tsunami, inun-
dation distances and run-up heights at different Indian
localities, obtaining a rather linear relationship be-
tween both parameters (his figure 3). Particular inter-
est for us shows two of his localities with similar
topographic conditions and relative locations to our
current study case. The Rajakkamangalam and Man-
avalakurichi lie at the mouth of the Panniyar and Val-
liyar river mouths, respectively [Hafeez, 2008]. This
author expressly indicates “these rivers also con-
tributed to such a huge amount of inundation”. River-
bore appears to have taken place in such cases. The
Inundation distance and run-up height at Rajakka-
mangalam were 350 m and 3-4 m, respectively; and
they were at Manavalakurichi 250 m and 3-4 m,

AUDEMARD AND LEAL GUZMÁN

12

Figure 13. View of the Manzanares River near its mouth. The
Simón Berrizbeitia’s Monalisa yatch stands for scale. Riverbanks
are less than 1 m high above river level. Higher grounds corre-
spond to river protection embankments, which are also visible in
Figure 7, coconut trees in both figures are comparable.

Figure 12. Bird-eye to the NW of the Caigüire sector, taken in 1925. Note the mangrove trees by the seashore in the far background. Today,
the Perimetral Avenue runs there. Also notice the low-lying flat topography of the salt-flat, on which are built the wooden huts of locals.
That is the view of a typical fisherman village of the time.



13

respectively [Hafeez, 2008]. In other words, a rough re-
lation of 1 to 70-100 can be established between run-up
height and inundation, for localities sitting on low-
lying coastlands near rivers. Consequently, a 200 m in-
undation distance appears to go well with a 3 m run-up
height for the 1853 tsunami in Cumaná. Finally, the
meaning of “leaving a depth of 14 fathoms”, equiva-
lent to some 25 m, remains unclear to the authors.

By applying ITIS 2012 scale (Lekkas et al. 2013],
the tsunami at Coche island can be categorized as in-
tensity IV (largely observed) at least, since it was felt
onboard small vessels or boats. Meanwhile, the facts
that the Manzanares river rose few feet and inundated
close to 200 m inland along Cumaná western shore,
with no other damage descriptors, allow to establish-
ing a minimum intensity of VII [damaging; Lekkas et
al. 2013]. Its magnitude by applying Imamura-Iida
scale, is at least 0 at Cumaná.

4.4 The September 1st, 1530 tsunami
Three different testimonies describing the 1530

tsunami are here evaluated. The first account of the
three is from Fernández de Oviedo y Valdéz. It says:
“El año de mill é quinientos é treynta, en el mes de septiem-
bre, en un día sereno é tranquilo, en un instante, á las diez
horas del día, en la provincia de Cumaná se levantó el mar en
altura de quatro estados é juntamente dio la tierra un horrible
bramido, é inundóse la tierra, sobrepujando la mar sobre
ella…” (Fernández de Oviedo y Valdés, Gonzalo [(1535)-
1851] Historia General y Natural de las Indias. Islas y Tierra
Firme del Mar Océano. Primera Parte. Imprenta de la Real
Academia de la Historia: Madrid). The story goes: “In
1530, in September, in a quiet and peaceful day, at 10 in
the morning, in the Province of Cumaná, the sea raised
in 4 “estados” [over 13 m; 1 “estado o estadal” = 4 “varas”
or stick = 4 x 0.835 m ≅ 3.34 m] and the earth bellowed
horribly at the same time, and land was drowned, run-
ning waters over it…”.

The second account on the 1530 earthquake and
tsunami comes from a letter of Deputy Mayor Andrés
Villacorta to the Canonry of Nueva Cádiz that says in
Spanish: “Oy jueves, primero de setiembre de mill e quinien-
tos e treynta años, a ora de las nueve se levantó el mar de tal
manera ques cosa milagrosa a los que la vieron y entró den-
tro de esta tierra donde estava sytuada esta fortaleza, e con
ello dio un bramido la mar e tenbló la tierra tres vezes en
media ora, e abrióse por muchos lugares, e con el tenblor cayó
esta fortaleza hasta los cimientos” [Carta de Andrés Villa-
corta, Teniente de Alcaide, al Cabildo de Nueva Cádiz, a
razón del terremoto de 1530, Citado en Otte, 1977:
243]. The FTBA goes as follows: “Today, Thursday
September 1st 1530, at around 9 in the morning, the

sea raised in such a way that was a miracle who could
tell about it, and went inland where the fortress is situ-
ated, and the sea bellowed once, and land shook three
times in half an hour, and cracked wide open in many
places, and the fortress fell down to its foundations”.

The third testimony is much more elaborated and
abundant in details in many different relevant aspects:
“...y al otro día siguiente vino la nueva de cómo la fortaleza de
Cumaná era cayda del gran temblor e terremoto y se abrió la
tierra en muchas partes y salió la mar de sus términos (...) y el
mismo dia viniernon ciertos yndios... los quales dixeron que se
avia anegado un pueblo questava a dos leguas de alli e que ellos
avian salido a nado donde murieron quatro yndios e muchos
muchachos e perdieron toda su ropa (...) Temblo la tierra veynte
y tres veces a cada vez que temblaba la Tierra bramaba debajo
della de una manera espantosa e vido viniendo por el dicho
golfo... quel agua de la mar salio de sus limites y los dichos in-
dios decian que bramó la mar como leon (...) e vido los arboles
arrancados y encima de otros arboles a donde salio la mar de
sus términos e vido algunos peces colgados netre las ramas [pro-
ducto] del gran terremoto e vido otros arboles de mangle que
son muy rezios e muy gordos quebrados del dicho terremoto e
otros arrancados de rayz e otras cosas de mucha admiración”
[Información hecha en la Isla de Cubagua, 1530].

The free translation by authors (FTBA) goes: “...
and the day after, the news arrived that the fortress of
Cumaná was pulled down by the great tremor and
earthquake, and land opened in many places and sea
left its boundaries (...) the same day some Indians
came... who said that a village at 2 leagues away (about
11 km away; league = 6666.7 “varas” or sticks = 5572.7
m) was drowned and they were able to escape swim-
ming while 4 Indians drowned and many young people
had lost all their clothing (...) Land shook 23 times; each
time Earth trembled, it bellowed underneath in a hor-
rible way, seen as coming by the gulf [Cariaco Gulf lo-
cated due east of Cumaná]... that seawater went out of
its limits and those Indians mentioned that sea roared
like a lion (...) trees were seen unrooted and piled on
top of others where sea inundated, and some fish were
seen hanging in tree branches because of earthquake,
and mangrove trees, which are very strong and robust,
were broken by the earthquake and others fully un-
rooted, and others things of much admiration”. For
Grases et al. [1999], the latter part of the account by the
Indians takes place into the Cariaco Gulf, located due
east of Cumaná (Figure 3).

As expected, the information about this 1530
earthquake and associated tsunami is more complex to
unravel, but many details, however, are provided. 

As to the earthquake, we can express the follow-
ing: 1) Day and time of occurrence is very well estab-

RELIABILITY OF TESTIMONIES ON VENEZUELAN HISTORICAL TSUNAMIS



lished: in midmorning (9-10 am) of Thursday Septem-
ber 1st, 1530. 2) Both earthquake and tsunami takes
place. Time lag between earthquake and tsunami
seems short. 3) Earthquake epicenter is close to
Cumaná. Many accounts refer to loud noises, like roar-
ing, booming or bellowing, accompanying shaking. 4)
Many earthquakes (aftershocks) were felt at Cumaná
after the main shock, up to 23; most of them also ac-
companied by loud noise from the ground. 5) Roaring
in some cases would seem to come from the Cariaco
Gulf, due east of Cumaná, which would be in contra-
diction with a focus on the Cariaco Trough, located
west of Cumaná, as proposed by Audemard [2007]; un-
less some echo effect or reverberation is called upon. 6)
The fort built by Jácome Castejón was torn down to its
foundation by the earthquake and not by the tsunami. 

As to the tsunami, we can list the following facts:
A) Inundation is reported both at Cumaná and at a vil-
lage 11 km (2 leagues) away (Figure 3). Being this vil-
lage around the Cariaco Gulf, the locality, which should
suit favorable conditions for Indian settling and land
cultivating at the time of the earthquake and tsunami,
as well as exhibiting a topographic situation prone to
drowning during high waves inundation, is the delta
plain of either Guaracayal or Marigüitar, that lie 18 to
23 km due east from Cumaná (Caigüire), respectively
B) Wave height of tsunami waves seems to be signifi-
cantly high since someone reports “lucky ones those
who could tell about the sea rise”. At the nearby vil-
lage, Indians had to swim to survive and four of them
drowned. This also implies that run-up has to be few
meters high. This seems to confirm the description pro-
vided by Centeno Graü [1969], which indicates that sea
got some meters above its normal level, leaving the
beach dry and when returning, it inundated most of
the city existing at that time. C) However, waves as high
as 13 m (4 estados) seem an exaggeration to us, al-
though some reports indicate that waves went over
treetops at Manzanares river mouth [see Audemard
2007, for more details]. D) Using plants as a height
reference, we must indicate that two main plant species
are common to this seashores and river banks at
Cumaná: coconut and mangrove trees (Figures 7, 10a,
12, 13 and 14), particularly Rhizophora sp. In the referred
case, waves as high as 5 to 7 m, as interpreted by Au-
demard [2007], would be large enough to go over man-
grove trees and leave fish hanging from its branches, as
reported in the third account. E) A better bracketing of
wave height can be provided from the fact that robust
mangroves (probably Rhizophora trees) were torn
down and even some specimens have their roots pulled
out completely, as mentioned in the third account.

Based on recent studies of damage to mangrove popu-
lations, in Banda Aceh, Indonesia, and Pakarang Cape,
Thailand, as a result of the devastating Indian Ocean
2004 tsunami, Yanagisawa et al. [2010] found that more
than 50% of mangrove trees with 20-25 cm [very ro-
bust] stem diameter at breast height (DBH) could sur-
vive a tsunami of less than 6-7 m, although mangrove
trees were destroyed completely under 7-9 m or higher
tsunami waves. We feel that coastal morphology, plant
populations, shelf configuration and profile, between
these two Indian Ocean study sites and the Cumaná re-
gion are pretty much similar. Therefore, their conclu-
sions can be extrapolated to our case. In a previous
study, Yanagisawa et al. [2009] categorize damage to
mangrove trees into five patterns: (1) broken at stem or
prop roots, (2) uprooted and inclined, (3) uprooted and
fallen down, (4) uprooted and swept up by tsunami
flow, and (5) lost bearing capacity because of ground
erosion. However, the same authors indicate that Rhi-
zophora trees were destroyed only slightly in the pat-
terns resembling patterns (2)-(4) because the prop roots
of Rhizophora trees are sufficiently thick to resist the
tsunami flow. They add that when pattern (5) does not
show, pattern (1) is mostly applicable as the predomi-
nant damage pattern of Rhizophora trees. Then, from
the description of damage to mangrove populations
during the 1530 tsunami waves given in the third ac-
count, it would seem that pattern (1) and (3) were the
two most common, implying that low-lying coastal
plain erosion did not take place then. Although we do
not know the actual stem diameter of the mangrove
trees affected during the 1530 event in Venezuela, it
would appear that no total destruction of tree popula-
tion occurred. It would seem to point to flow depths
during the Cumaná event below 7 m. F) Audemard
[2007] indicated that tsunami waves at the Manzanares
River mouth (north part of the old city) flooded inland
as far as the ranges (Caigüire Hills?). As applied for the
1853 tsunami herein, the inundation distance may give as
clues as to the run-up heights. In old maps of the city of
Cumaná, the river mouth was some 500 m away from
the Caigüire hills foothills, although they are just over 2
km away nowadays. From a map by Beltrán and Ro-
dríguez [1995], a coastal advance, likely strongly influ-
enced by anthropogenic processes since the early 50’s,
of some 130 m has happened in less than 50 years, be-
tween 1937 and 1981. So, despite the low precision of
old maps, before the instrumental -theodolite- era, the
delta plain of the Manzanares River since the foundation
of the city of Cumaná in 1515 AD, has surely substan-
tially changed, particularly advanced through the years.
In any case, an inundation distance of at least 500 m

AUDEMARD AND LEAL GUZMÁN

14



15

would allow estimating a lower bound for the run-up
height in the order of 5 m. Consequently, the run-up
height in Cumaná, characterized by a flat morphology
typical of a young prograding delta, would be ranging
between 5 (from inundation distance) and 7 m (damage
to Rhizophora trees). This value range is consistent with
an earlier estimate proposed by Audemard [2007].

The occurrence of Indians drowning (at village in
the Cariaco Gulf) and mangrove trees tearing and up-
rooting (at Caigüire, Cumaná) during this tsunami both
allows to estimating a minimum ITIS-2012 intensity of
VIII (heavily damaging; Lekkas et al. 2013]. This also
determines the tsunami magnitude to be grade 2 in the
Imamura-Iida tsunami magnitude scale [Iida 1963]. If
the tsunami wave height happens to be between 5 and
7 m, as proposed after this research, the assigned ITIS
2012 intensity can be as large as X (very destructive). 

5. Concluding remarks
The first striking commonality from the historical

evaluation of eyewitness accounts is that inundation for
all these earthquakes are reported at river mouths or
settlements on their mouths (Figures 3 and 11): Tuy,
Río Chico, Guapo, Neverí, Manzanares. From
comparison with modern analogs, such as the Valdivia
1960, Camaná 2001, Sumatra 2004, and Tohoku-Ochi
2011 tsunamis, this is not surprising because inunda-
tion and wave invasion happens sooner, faster and more
efficiently along rivers, through the river mouth and
along the incised river channel. As a matter of fact, sea-
water invasion during tsunami wave progression shows
a prominent acute salient at river mouths. The expla-
nation is obvious: there is no natural barrier blocking
the landward wave progression. In addition, the water
invasion is eased by the lower level of the coastland area
resulting from river incision. This also drives that max-
imum inundation tends to happen and occur along

rivers. However, a major difference between the
Venezuelan historical tsunami events and those above-
mentioned needs to be underlined. It refers to the size
of river discharge in Venezuela. As a country lying in
the Tropics, river flow is hardly negligible and appears
to be significantly higher than for the other cases. For
instance, the Manzanares River, which is a small river
for our standings, has an average annual discharge of
560-770 x 106 m3, which is equivalent to some 15 x 106

m3/month, or 5,63 m3s-1 (ranging between 3.5 and 7.0
m3s-1) at river mouth [Medina et al. 2013]. This then
surely leads to the formation of riverbore when both
waters (tsunami wave and river flow) encounter at river
mouths, rising river level and significantly flooding over
banks. Then, this may have fundamental implications
on the dynamics of the inundation process, as well as
on characteristics of the tsunami waves, particularly as
to wave height. In other words, flooding heights along
rivers when riverbore occurs, are not necessarily the
same as maximum run-up heights, but should tend to
provide a rather precise lower bound.

The other common fact is that the city of Cumaná
has been affected by tsunami waves associated to all 4
events occurring on the EPF but not by the 1900 AD
event, the largest of all 5 events assigned to SSF, whose
epicenter lies close to the far west end of the Barcelona
Embayment (Figure 3). Nevertheless, it is a fact that
there are more frequent and more widespread eyewit-
ness accounts on the tsunami waves during the 1900
AD event (Figure 3). A larger area of affectation by
tsunami waves definitely support its larger earthquake
magnitude: Gran Roque Island of the Los Roques
Archipelago and river mouths of Tuy, Río Chico,
Guapo and Neverí. All these rivers drain into the
Barcelona Embayment; Neverí on the SE while all
others on the SW (Figure 3). 

Another outcoming commonality is that the value
of the run-up height (in all our cases equivalent to the
water depth of the inundation, because all affected lo-
calities sit on low-lying coastlands) from such eye-wit-
ness or first-hand testimonies not necessarily are rid of
subjectivity. However, combining a good knowledge of
coastal physiography, shelf morphology, natural envi-
ronments and cultural aspects (construction types,
housing, customs, life style, vessels, among many oth-
ers) of affected populations at the time of occurrence
of tsunamis with a thorough and careful reading of the
testimonies, may lead to find ways of bracketing both
inundation distances and run-up heights for any given
historical tsunami. For instance, an eye-witness during
the 1900 earthquake reports tsunami waves of 10 m; or
13 m during the 1530 tsunamigenic earthquake. Simi-

RELIABILITY OF TESTIMONIES ON VENEZUELAN HISTORICAL TSUNAMIS

Figure 14. Beach at Caigüire in 1960’s, where mangrove trees
grow almost on the sand barrier, which is visible between trees.
Also notice the height of sand barrier above sea level.



larly, 6 m high tsunami waves are reported in associa-
tion with the 1929 earthquake. It is very likely that the
actual height of tsunami waves in all 3 cases may be
half of the reported height at most, based on sound ar-
gumentation constructed from the descriptions pro-
vided by the eyewitnesses themselves (Table 1). As well,
tsunami waves during the 1530 are reported to go over

treetops. This may be very misleading if interpreted as
it sounds. Actually, maximum run-up heights for the 5
tsunamis herein evaluated are: 5-7 m at Cumaná for the
1530 event, 5 m at Barlovento and 3 m at the Neverí
mouth for the 1900 tsunami, 3 m at western Cumaná
for the 1853 and 1929 events and about 1 m for the 1997
earthquake (Table 1). A difficult aspect to manage,

AUDEMARD AND LEAL GUZMÁN

16

PARAMETERS EARTHQUAKE/TSUNAMI

01-IX-1530 15-VII-1853 29-X-1900 17-I-1929 09-VII-1997

Epicenter
Coordinates

10.261°N, 
64.313°W
(estimate;

Rodríguez et al., 
2006)

10.265°N, 
64.359°W
(estimate;

Rodríguez et al., 
2006)

10.660°N, 
66.080°W
(estimate;

Rodríguez et al., 
2006)

10.394°N, 
64.000°W
(estimate;

Rodríguez et al., 
2006)

10.545°N, 
63.515°W
(estimate;

Rodríguez et al., 
2006)

MM I
O

(with most damage 
settlement)

X (Cumaná) IX (Cumaná)
IX (Guarenas-

Guatire & Macuto)

VIII-IX (Caigüire, 
east Cumaná;

Audemard, 2007)

VIII (Cariaco-
Casanay)

Magnitude
(Ms)

7.1-7.3 (estimate)
(Audemard, 2007)

7.1-7.3 (estimate)
(Audemard, 2007)

7.6
(Pacheco and Sykes, 

1992)

6.3
(Audemard, 2007)

≤ 6.6
(Mocquet et al., 

1996)

6.8
(Baumbach et al., 

2004)

Causative fault

El Pilar -EPF-
(segment A)

(Audemard, 1999, 
2007)

El Pilar–EPF-
(segment A)

(Audemard, 1999, 
2007)

San Sebastián 
-SSF- 

(east segment)
(Audemard, 2002)

El Pilar -EPF-
(segment B-1)

(Audemard et al., 
2007)

El Pilar -EPF-
(segment B-2)

(Audemard et al., 
2007)

Tsunami height 
from eyewitness
accounts

Cumaná: ≅ 13 m
(4 estados; Fer-

nández de Oviedo y 
Valdés, 1851)

Manzanares River 
rose few feet

(La Catástrofe de 
Cumaná, 1853)

Puerto Tuy
(Barlovento):

 ≈ 10 m (Linterna 
Mágica, 02-XI-1900)

6 m 
(Centeno Graü, 

1940)
West Cumaná: 9 

feet (3 m)
(El Nuevo Diario, 

22-I-1929)

Cumaná & Cariaco: 
≤ 1m

(González et al., 
2004)

Recalculated
tsunami height 
(THIS RESEARCH)

Cumaná: 5-7 m
(This ratifi es 

Audemard, 2007’s 
estimate)

Cumaná (Caigüire): 
3 m

Barlovento: 5 m
Los Roques: 

< 1.5 m
El Rincón: ≥ 3 m

West Cumaná: 3 m

≤ 1m (unchanged)
(González et al., 

2004)

ITIS-2012
tsunami max. 
intensity

Cumaná & Cariaco 
Gulf: ≥ VIII

(up to X on tsunami 
height) 

Coche Island: ≥ IV
West Cumaná: 

≥ VII

Barlovento: IV-V 
(up to IX on tsuna-

mi fl ow depth)
Los Roques: V

El Rincón: VII (VIII 
on tsunami height)

West Cumaná:
VII-VIII

Cumaná & 
Cariaco Gulf: 

IV

Imamura-Iida
tsunami magnitude

2 (Cumaná & Caria-
co Gulf )

0
(west Cumaná)

1 (Barlovento)
0 (Los Roques)

? (El Rincón; 1 from 
tsunami height)
 2 (from tsunami 

extent)

1 
(west Cumaná)

-1
(Cumaná & Cariaco 

Gulf )

Table1. Summary of major parameters of the five tsunamigenic local earthquakes assessed during this investigation. It compares how
tsunami heights from eyewitness accounts have been substantially reduced for some earthquakes, when the event is contextualized in time
and space. The ITIS-2012 tsunami intensity scale and Imamura-Iida tsunami magnitude scale have been applied to the data provided by
eyewitness accounts as well. The earthquake epicenters are shown on Figure 2 or 3.



17

though, is the eventual enhancement of the tsunami
wave height by contributing underwater sliding, also
triggered by the local earthquakes on steep submarine
(even subaerial) walls, such as inside the Cariaco Trough,
on the continental slope or along steep rocky coasts.

In all the tsunamis analyzed in this paper, eyewit-
nesses report sea retreat first. That is the case for the
1530, 1853, 1929 and even 1997 tsunamis in western
Cumaná (El Salado, El Dique or Puerto Sucre seaport).
Testimonies for the latter event were collected by the
first author in the first few days following the July 9th,
1997 earthquake. Reports of sea oscillations inside the
Cariaco Gulf during the 1997 event were also collected.
This seems sound in case of the Cariaco 1997 earth-
quake because the earthquake epicenter was located
farther east; more precisely, on the land bridge between
the Cariaco and Paria gulfs [Baumbach et al. 2004], the
latter gulf lying even farther to the east (Figure 2). The
sea surface oscillations detected on western Cumaná
during this 1997 earthquake, on the contrary, are at-
tributed to subaerial and submarine slides taking place
at the river mouth banks and along the submarine Man-
zanares Canyon, respectively [Audemard and Leal
2014,2015], as attested by deep turbidite currents in the
Cariaco Trough detected by Thunell et al. [1999] and
Lorenzoni et al. [2012]. This same argumentation is to
be applied to the 1929 earthquake, whose epicenter also
lies east of Cumaná, into the Cariaco Gulf, but the
tsunami waves occurred on the opposite side of
Cumaná, at the Manzanares River mouth (El Salado)
predominantly. Instead, a more complex scenario is to
be conceived if the 1530 and 1853 earthquakes do ac-
tually take place in the deep Cariaco Trough, as pro-
posed by Audemard [1999, 2007], unless the simpler
submarine slide hypothesis is accepted for all these
tsunamis affecting Cumaná. Aguilar et al. [2016], in
order to explain an increase of more open seawater cir-
culation into the Cariaco Gulf, proposes a major
change in the Salazar Sill depth (lying just North of
northern Cumaná, in the Cariaco Gulf entrance) at
around 1853 AD, in association to a submarine slide.
This could explain the occurrence of inundation of the
Caigüire saltflats during this earthquake, which seems
not to be reported during other earthquakes and asso-
ciated tsunamis. But the 1530 tsunami affectation is
even more difficult to explain with an earthquake locus
in the Cariaco Trough lying due west of Cumaná, tak-
ing into account that an Indian village at 2 leagues into
the Cariaco Gulf was clearly inundated, with 4 casual-
ties by drowning. Now that run-up height for this 1530
tsunami is better bracketed, numerical modeling of dif-
ferent tsunami scenarios -combining earthquake epi-

center west or east of Cumaná, tsunami waves gener-
ated by (fully strike-slip or normal oblique) tectonic slip
or submarine slide or combination of both-, should
provide answers or constraints to this uncertainties. A
few first attempts [Audemard et al. 2014], using the pis-
ton modeling developed by the Norwegian Geotechni-
cal Institute -NGI- , have been performed, trying to
reproduce a 3 m high inundation at the western coasts
of Cumaná. Actually, the Barcelona Embayment shelf
configuration with a pure strike-slip motion on EPF, at-
tempting to recreate the 1853 tsunami, induces tsunami
waves of only 30 cm in height [Audemard et al. 2014],
which appears insufficient to inundate western
Cumaná with 3 m high waves, unless other local con-
siderations are incorporated (funneling effect of the
Manzanares Canyon, riverbore formation, actual
oblique -normal-dextral- slip in a pull-apart setting,
among others). Very much remains to be done and
tested in this field yet.

Speculating about the 1853 slide scenario proposed
by Aguilar et al. [2016], which surely inundates Caigüire
from the testimonies collected herein, one of their own
figures (Figure 15) is much worth discussing. The mor-
phology of the coast and shelf bathymetry at the Cari-
aco Gulf entrance and just North of Cumaná, and
particularly North of Caigüire, points out to a potential
large slide that indented the coast at Caigüire and asso-
ciated shelf; and slid down to deeper waters, as sug-
gested by the belly shape the isobaths exhibit.

In terms of intensity, the ITIS 2012 scale [Lekkas et
al. 2013] has been applied to all 5 tsunamis (Table 1).
Even for the recent 1997 event, the quantity and qual-
ity of the six types of descriptors integrated in the ITIS
scale (Quantities, impact on humans, impact on mobile
objects, infrastructure, environment and structures) are
definitely insufficient for a good well constrained as-
sessment in all cases. However, in some cases, some di-
agnostic descriptors (e.g., damage to trees, drowned
individuals, among others) help to establish the mini-
mum tsunami intensity. In this research, the assessment
of the tsunami wave height (or flow depth) by contex-
tualizing the eyewitness account(s) as a whole, has led
to more reliable values. In addition, the tsunami de-
scriptions have been also converted into tsunami in-
tensity values by applying ITIS 2012 scale [Lekkas et al.
2013], as well as tsunami magnitude grades by apply-
ing Imamura-Iida [Iida 1963] scale. This has actually led
to more robust and better bracketed tsunami wave
heights. However, we need to highlight that although
descriptors in the six types of elements assessed in the
ITIS 2012 scale appear to have a good level of detail for
modern tsunamis, its application to historical tsunamis

RELIABILITY OF TESTIMONIES ON VENEZUELAN HISTORICAL TSUNAMIS



in the modern world characterized by a rather short
written history, seems more difficult to implement.

Last but not least, these new estimates on tsunami
run-up or wave heights for earthquakes produced by
local active tectonics have major implications on search
for geologic past tsunami records along the Venezuelan
coasts. For the particular case of the Eastern Venezue-
lan coasts, the search for tsunamites by trenching and
coring should be essentially restricted to the first 500-m-
wide strip from the coastline in low-lying flatlands, if nat-
ural (e.g., vegetation, coastal sand barrier height) and
anthropogenic (e.g., building and housing, coastal em-
bankments) obstructions to inundation are not signifi-
cant, due to the modest size of tsunami waves produced
by local earthquakes of magnitude up to Mw 7.6, mostly
on offshore strike-slip (or normal oblique) faults. 

Acknowledgements. This is a contribution to the TERPRO
Commission of INQUA, led by Dr. Alessandro Maria Michetti from the
University of Insubria (Como, Italy). Funds to the research are provided
by FONACIT through grants to Project FONACIT 2013000361 and past
projects FONACIT-ECOS Nord PI-2003000090 and PI-2009000818. We
wish to thank the funding support the first author received from Istituto
Nazionale di Geofisica e Vulcanologia -INGV- and Istituto Superiore
per la Protezione e la Ricerca Ambientale -ISPRA- to partly present these
results at the VI INQUA International Workshop on Paleoseismology, Ac-
tive Tectonics and Archaeoseismology (VI PATA) held in Pescina (AQ) be-
tween 19 and 24 April 2015, as well as the invitation from the VI PATA
Organizing Committee. Really, many thanks for sponsoring me!! It was
a very enlightening and an unforgettable meeting in many ways:
friendly talks, lively discussions, nice sightseeing, excellent Mediter-
ranean food, eye-filling window geology, lovely re-acquaintances with
friends and colleagues, varied wine tasting, teaching fieldtrips (visit to
the Fucino 1915 and L’Aquila 2009 surface ruptures and damage to the
urban area of l’Aquila itself; and some paleoseismic trenches too!), illu-
minating Rome archaeoseismic visit, among many others….. It is also
a contribution to Working Group 2 of IOCARIBE, the regional sub-
sidiary body of the UNESCO Intergovernmental Oceanographic Com-
mission, which at present is focused on designing, building and

implementing the Tsunamis and Other Coastal Hazards Warning System for
the Caribbean Sea and Adjacent Regions(CARIBE-EWS). We thank Raquel
Vásquez for helping us with some macroseismic data. Last but not
least, we are thankful to two anonymous reviewers and the Sector
Editor Dr. Francesca Bianco, for providing pertinent comments.

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*Corresponding author: Franck A. Audemard M,
Earth Sciences Dpt., Venezuelan Foundation for Seismological
Research -FUNVISIS-, Caracas, Venezuela; email:
audemard@funvisis.gob.ve.

© 2017 by the Istituto Nazionale di Geofisica e Vulcanologia. All
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