articolo madeira.pdf


Key  words Azores – neotectonics – active faulting –
paleoseismology – seismic hazard

1.  Introduction

The studied region is located in a unique
tectonic setting (fig. 1). The central and eastern
groups of the Azores islands stand on a broad
sheared region that absorbs the deformation
induced by the eastward differential displace-
ment of the Eurasian and African plates, east of
the Azores triple junction. The volcanism that
built the islands and submarine volcanoes is
tectonically controlled and is a result of the

Active tectonics and first paleoseismological
results in Faial, Pico 

and S. Jorge islands (Azores, Portugal)

José Madeira and António Brum da Silveira
Departamento de Geologia and Laboratório de Tectonofísica e Tectónica Experimental,

Faculdade de Ciências da Universidade de Lisboa, Portugal

Abstract
The neotectonics of the islands of Faial, Pico and S. Jorge (Azores) is presented. Preliminary paleoseismology
data from trench exposures across three active fault zones (Lomba do Meio, Lagoa do Capitão and Pico do
Carvão faults) complement the information. Radiocarbon age constraints of paleoearthquakes suggest clustering
of surface rupturing events. Slip rates deduced from paleoseismology analysis range from 0.10 to 0.40 cm/year
and validate long-term slip rates obtained by neotectonic studies (using Pleistocene markers). The studied faults
allowed a preliminary seismic hazard assessment: magnitudes of the largest paleoearthquakes, determined from
slip per event range from Mw = 6.9 to 7.1, and maximum expected magnitudes, estimated from rupture length or
rupture area, vary from Mw = 6.4 to 6.8. The former Mw estimates are in closer agreement with the magnitude of
the major historic and instrumental seismic events in the archipelago, even though the used empirical relations
between magnitude and rupture parameters may not be the most adequate due to the unique tectonic setting of
Azores.

transtensile regime acting on that portion of
oceanic lithosphere. The deformation is repre-
sented by widespread active faulting of the
islands and the surrounding seafloor.

This work presents the description of the tec-
tonic structure of three islands from the Azores
central group: Faial, Pico and S. Jorge. The faults
were mapped through fieldwork and vertical air-
photo interpretation. Kinematics was deduced from
rare striated fault surfaces and displaced strati-
graphic and morphological markers. Deter-
mination of fault separations of K/Ar dated vol-
canostratigraphic units (at the scale of the island)
by cartographic methods allowed the estimation
of slip rates for a time scale of the order of tens
or hundreds of thousand years.

In order to verify the validity of the obtained
slip rate values, and to observe the faults at differ-
ent time and geometry scales, exploratory paleo-
seismology studies were performed across three
known active faults, one from each island. The

733

ANNALS  OF  GEOPHYSICS, VOL.  46, N.  5, October  2003

Mailing address: Dr. José Madeira, Departamento de
Geologia and Laboratório de Tectonofísica e Tectónica
Experimental, Faculdade de Ciências da Universidade de
Lisboa, Edifício C2, 5° piso, Campo Grande, 1749-016
Lisboa, Portugal; e-mail: jmadeira.@fc.ul.pt



paleoseismological analysis was to complement
the neotectonic study of the three islands and,
therefore, must be understood as a preliminary
and exploratory work. The choice of the trenched
faults and their location depends on geological
and morphological reasons, including: the size of
the fault scarps (many of the main faults present
scarps several tens to hundreds of metres high
with the base covered by thick talus deposits);
their topographic position (scarps located in de-
pressed areas are unfavourable as they are either
partially fossilized by recent deposits or amplified
by stream erosion); morphologically fresh aspect
of scarps suggesting recent surface rupture and/or
knowledge of historic surface rupturing events;
nature of the materials exposed in the scarps
(where possible, scarps cut in pyroclastic deposits
were preferred to those that expose the lava flow
basement).

Paleoseismology results allowed the deter-
mination of age of paleoearthquakes, estima-
tion of recurrence intervals, and comparison of
slip rates for different time scales.

2.  Geological setting

The Azores archipelago is located at the
North America, Eurasia and Africa triple junc-
tion (fig. 1). The Mid Atlantic Ridge separates
the American from the Eurasian and African
plates; east of the rift, the Azores-Gibraltar
Fault Zone is the boundary between Eurasia
and Africa. 

The islands of Flores and Corvo lie on the
American plate, while the central (Graciosa,
Terceira, S. Jorge, Faial and Pico) and eastern
(S. Miguel, Santa Maria and Formigas islets)
groups of islands are located along the western
segment of the Azores-Gibraltar Fault Zone
(Madeira, 1998; Lourenço et al., 1998), whose
morphologic expression is the Azores Plateau.
The region is under right lateral transtension
as a result of higher rates of spreading north of
the triple point and to the obliquity of the
Azorean segment of the Eurasian-African
plate boundary relatively to the spreading direc-
tion.

734

José Madeira and António Brum da Silveira

Fig.  1. Tectonic setting of the Azores archipelago (modified from Laughton and Whitmarsh, 1974; Lourenço et al.,
1998; Madeira, 1998). The Mid Atlantic Ridge (MAR) separates the North American plate (NA) from Eurasia (EU)
and Africa (AF). The Azores Oblique Spreading Centre (grey area) and Gloria Fault (GF) separate Eurasia from
Africa. The East Azores Fault Zone (EAFZ) is an abandoned segment of the Eurasia-Africa boundary. The archi-
pelago islands are Corvo (C), Flores (F), Graciosa (G), Terceira (T), S. Jorge (Sj), Faial (Fa), Pico (P), S. Miguel
(Sm) and Santa Maria (Sma). The Azores Plateau is enclosed by the 1600 m isobath (thin line). Inset shows location
of archipelago in the Atlantic and its relation with the mid-Atlantic ridge and the Azores-Gibraltar boundary.



735

Table  I.  Historic tectonic seismicity in Azores.

Date Location Intensity Estimated Effects of earthquake
(MCS-17; magnitude
MM-56)

Oct. 22, 1522 S. Miguel X (1) Voluminous landslides; 
> 5000 deaths estimated

June-July, 1571 D. João de VI/VII Seismic swarm
Castro Bank

May 24, 1614 Terceira X/XI; VIII (2) > 6.3 > 8 km of surface rupture 
on Lajes Fault; 93 deaths (3)

June 9, 1647 Terceira V/VI
Oct. 19, 1656 S. Miguel IV/V

March 29, 1690 Central Group V Alternative date is April 5, 1690
Nov. 15-25, 1698 Terceira IV Seismic swarm

Dec. 8, 1713 S. Miguel VI/VII
July 9, 1757 S. Jorge X/XI 7.1; 7.4 (4) Deaths: 1034 in S. Jorge; 

11 in Pico; small tsunami observed
Dec. 1759 to May 1760 Faial VI Seismic swarm

Aug. 1791 Terceira IV/V
Jan. 21, 1837 Graciosa VIII; IX (2) Probable rupture in Serra das 

Fontes Fault; 3 deaths
June 15, 1841 Terceira X/XI; IX (2) > 1 km of surface rupture in Cruz 

do Marco Fault; 5500 homeless
Oct. 30 to Nov. 8, 1848 S. Miguel VI/VII Seismic swarm

April 16, 1852 S. Miguel VII/VIII; VI (2) 9 deaths
Sept. 21 to Dec. 10, 1862 Faial V/VI Seismic swarm

March 16, 1920 Faial V
Feb. 9, 1924 Faial V/VI

Aug. 31, 1926 Faial VIII/IX; X (2) 8 deaths
(1) Machado (1966); (2) Nunes (1991); Nunes et al., (1992); (3) coeval texts refer three different numbers: 29, 93 or > 200
deaths; 93 is the most credible number; (4) Machado, (1949).

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)

As a result of its location on an active plate
boundary, the archipelago is subject to frequent
seismic activity. Although most are low to mod-
erate magnitude seismic isolated events or
swarms, the islands are occasionally struck by
high magnitude (M 7) earthquakes (table I;
fig. 2) exemplified by the October 22nd, 1522,
S. Miguel earthquake ( 5000 victims), the July
9th, 1757, S. Jorge event ( 1000 deaths) and
the January 1st, 1980, Terceira earthquake (64
casualties) (McKenzie, 1972; Udías et al., 1976,
1986; Hirn et al., 1980; Udías, 1980; Grimison
and Chen, 1986; Buforn et al., 1988; Moreira,
1991; Mezcua et al., 1991; Nunes et al., 1992;

Miranda et al., 1998). Published focal mecha-
nisms (table II; fig. 2) indicate dominant nor-
mal, dextral and sinistral strike-slip solutions
on WNW-ESE and NNW-SSE structures.

Volcanism has also been observed since the
settlement of the archipelago in mid 14th century.
At least 27 eruptions (fig. 3; table III) were report-
ed in the islands of S. Miguel, Pico, S. Jorge, Faial
and Terceira, and at sea between them, although
several eruptions may have been unnoticed
(Zbyszewski, 1963; Weston, 1963-1964; Forjaz,
1992; Queiroz et al., 1995; Madeira, 1998). The
nature and style of eruptions is variable and
include trachyte plinian or subplinian events,



basaltic Hawaiian/Strombolian, shallow surtseyan
or deeper submarine eruptions, and basic or acid
hydrovolcanic explosions.

3.  Neotectonics of Faial, Pico and S. Jorge

Two main fault systems were recognized in
the studied islands. The dominant structures,
striking WNW-ESE (N60-80W) and dipping
60° to 90° to NNE or to SSW, control the gen-
eral shape of the islands. The second fault sys-
tem, trending NNW-SSE (N10-30W) and dip-
ping 60° to 90° to WSW or to ENE, although
important, is less frequent (figs. 4, 11 and 14).

The size of the islands limits the observation of
the full length of the faults. Volcanism is con-
trolled by the tectonic structure: intersection 
of the two fault systems determines the location
of polygenetic volcanoes, while monogenetic
volcanoes lie mainly on WNW-ESE structures
(Madeira and Ribeiro, 1990; Madeira, 1998).

Splays, duplexes, en échelon structures, and
frequent changes in trend, portray the map ge-
ometry of the faults. In section, the fault planes
display variations in dip, sometimes alternating
almost vertical with less steep inclinations. At the
outcrop scale, the non-planar geometry of the
fault surfaces results in the formation of open
spaces along strike as well as along dip.

736

José Madeira and António Brum da Silveira

Fig.  2. Seismicity in the Azores: main historic tectonic earthquakes (triangles) and published focal mechanisms
of instrumental events (circles) (data from McKenzie, 1972; Udías et al., 1976, 1986; Hirn et al., 1980; Udias,
1980; Grimison and Chen, 1986; Moreira, 1991; Nunes, 1991; Miranda et al., 1998). Numbers relate to table II.



737

Table  II.  Seismic events with published focal mechanisms.

N. Date Magnitude Location Depth References

1 May 8, 1939 7.1 37.4N-23.9W 2, 4, 6, 7
2 Sept. 6, 1964 4.9 38.3N-26.6W 2, 4, 6, 7
3 Sept. 18, 1964 5.5 39.8N-29.7W 2, 4, 6
4 July 4, 1966 5.3-5.4 37.51N-24.75W 12 ± 5 km 1, 2, 4, 5, 6, 7
5 July 5, 1966 5.1-5.0 37.6N-24.7W 2, 4, 6, 7
6 April 20, 1968 4.8 38.3N-26.7W 7
7 April 20, 1968 5.0-5.1 38.30N-26.77W 15 ± 5 km 5, 6, 7
8 Sept. 1, 1968 4.8 39.16N-29.93W 6
9 Nov. 23, 1973 4.9 38.52N-28.37W 6
10 Dec. 11, 1973 5.0 38.7N-28.7W 6, 7
11 Jan. 1, 1980 7.2-6.4 38.82N-27.78W 10 km 3, 5, 6, 7
12 Feb. 12, 1981 5.3 38.5N-26.7W 7
13 Sept. 9, 1984 5.0 36.9N-24.6W 7
14 Oct. 16, 1988 5.1 37.70N-25.20W 8
15 Nov. 21, 1988 5.8 37.9N-26.2W 7
16 Jan. 21, 1989 5.4 38.04N-26.28W 8
17 June 26, 1989 5.7 39.23N-28.34W 8
18 July 22, 1992 3.2 38.15N-26.65W 9
19 July 22, 1992 3.4 38.15N-26.65W 9
20 July 9, 1998 5.8 (Md) - 6.2 (Mw) 38.63N-28.52W 10, 11

1 - McKenzie (1972); 2 - Udías et al. (1976); 3 - Hirn et al. (1980); 4 - Udias (1980); 5 - Grimison and Chen
(1986); 6 - Udías et al. (1986); 7 - Moreira (1991); 8 - Nunes (1991); 9 - Miranda et al. (1998); 10 - Vales et al.
(2000); 11 - Madeira et al. (1998a).

Fig.  3. Location of reported historic eruptions in the Azores (data from Zbyszewski, 1963; Weston, 1963/64;
Forjaz, 1992; Queiroz et al., 1995; Madeira, 1998). Submarine eruptions occurred at depths shallower than
– 400 m. Numbers relate to table III.

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)



The kinematics of the faults, deduced from
striated fault surfaces, as well as from the dis-
placement of morphologic (e.g., spatter cones,
streams and ridges) and stratigraphic markers,
indicates normal dextral slip on the WNW-ESE
fault system and normal sinistral displacement
in the NNW-SSE conjugate system. Small pull-
apart basins and push-ups are related to re-
leasing and restraining bends, respectively.
Morphologic features such as fault scarps, sag
ponds, alignments of volcanic cones and cra-
ters, displaced streams and craters, characterize
the fault traces.

Major faults usually have well-developed
scarps with metric to hectometric heights.

However, the fault scarps height may not corre-
spond directly to the accumulation of successive
surface rupture. Often, differential erosion of the
disrupted materials (lava flows versus pyroclasts)
or partial fossilization of the scarp by volcanism
may amplify or attenuate the tectonic slope. On
the up-thrown block, secondary fault scarps, show-
ing en échelon geometry, are frequent.

Observation of striated fault surfaces indi-
cates that, besides oblique slip, strain partition-
ing may occur at the fault zone scale: parallel
slip surfaces from a fault zone displaying either
dip slip or strike slip slickensides, show that
strike and normal components may be separat-
ed in time or space. The occurrence in the archi-

738

José Madeira and António Brum da Silveira

Table  III. Historic eruptions in the Azores.

N. Year Location Structure

1 1439? S. Miguel Pico da Ferraria - Sete Cidades
2 1439 or 43 S. Miguel Pico do Gaspar - Furnas
3 1562/64 Pico Pico do Cavaleiro (presently Cabeços do Fogo)
4 1563/64 S. Miguel Lagoa do Fogo, Pico do Sapateiro (Queimado),

Pico de Da Guiomar, Monte Escuro
5 1580 S. Jorge Riba do Almeida, Mistério da Queimada, Riba do Nabo
6 1630 S. Miguel Lagoa Seca - Furnas
7 1638 off shore Ponta da Candelária (S. Miguel) - 37°49 02 N-25°52 03 W
8 1652 S. Miguel Picos do Fogo I and II
9 1672/73 Faial Cabeço do Rilha Boi (presently Cabeço do Fogo) and Pincarito
10 1682 off shore Between S. Miguel and D. João de Castro Bank - 38°07 N-26°08 W
11 1713 S. Miguel Pico das Camarinhas
12 1718 Pico Lomba de Fogo, Cabeço de Cima and de Baixo, off shore S. João
13 1720 Pico Cabeço do Soldão (or Cabeço do Fogo)
14 1720 off shore Formed a temporary island on D. João de Castro Bank - 38°14 N-26°39 W
15 1761 Terceira Picos das Caldeirinhas, Mistério Negro
16 1800 off shore Ponta do Topo (S. Jorge) - 38°27 07 N-27°22 07 W
17 1808 S. Jorge Craters W of Pico do Pedro, Entre Ribeiras and Areias de Santo Amaro
18 1811 off shore Ponta da Ferraria (S. Miguel) - 37°51 04 N-25°51 08 W;

a temporary island (Sabrina) formed - 37°52 04 N-25°51 06 W
19 1867 off shore WNW of Ponta da Serreta (Terceira) - 38°47 04 N-27°27 00 W
20 1902 off shore W of Ponta do Topo (S. Jorge) - 38°31 02 N-27°26 08 W
21 1907 off shore Close to south coast of S. Miguel - 37°41 05 N-25°48 00 W
22 1911 off shore Mónaco Bank - 37°36 N-26°52 W
23 1957/58 off shore Capelinhos; phreatic explosion in Caldeira (Faial)
24 1963 off shore Probable eruption NW of Cachorro (Pico)
25 1964 off shore Probable eruption W of Velas (S. Jorge)
26 1981 off shore Probable eruption at Mar de Prata (SW of S. Miguel)
27 1998/00 off shore WNW of Ponta da Serreta (Terceira)

Modified from Madeira (1998), based on Zbyszewski (1963); Weston (1963/64); Forjaz (1992), Queiroz et al.
(1995) and coeval written accounts.



pelago of earthquakes with normal and strike
slip focal mechanisms in parallel faults, sepa-
rated by a few kilometers or tens of kilometers,
suggests that strain partitioning may also occur
at the regional scale (Madeira, 1998).

3.1. Faial

3.1.1.  Geological and structural setting

The island of Faial is 21 km long, has a
maximum width of 14 km, and reaches an alti-
tude of 1043 m at Cabeço Gordo (fig. 4).

Two central volcanoes and two fissural vol-
canic zones form the sub aerial part of the
island (Serralheiro et al., 1989; Madeira, 1998;
Pacheco, 2001). The ~.800-580 Ka old (Féraud
et al., 1980) Ribeirinha shield volcano con-
stitutes the eastern region of Faial. It is pre-
dominantly composed of sub aerial hawaiitic
lava flows mapped under the designation of
Ribeirinha Volcanic Complex (Rb in fig. 4).
The Caldeira stratovolcano was built on the
western flank of the Ribeirinha volcano and
constitutes the main relief of Faial. It is approx-
imately 15 km in diameter at sea level; the sum-
mit is truncated by a 2 km wide, 400 m deep,
caldera. The products of this volcano range
from basalts to trachytes and are divided into
two volcanostratigraphic units. The lower unit,
Cedros Volcanic Complex (Cd in fig. 4), is
mainly composed of sub aerial basalt to ben-
moreite lava flows. The available ages for this
unit range from .470 to 11 Ka (Féraud et al.,
1980; Baubron, 1981 in Chovelon, 1982). The
upper unit, Caldeira Formation (p and i in fig.
4), corresponds to a Holocene sequence of tra-
chytic products, emplaced by explosive erup-
tions. Radiocarbon ages from Caldeira Forma-
tion products range from .10 to 1 Ka (Madeira
et al., 1995).

A basaltic fissural unit, the Almoxarife
Formation (Al in fig. 4), overlies the southeast-
ern slope of Caldeira volcano and is covered by
Caldeira Formation pyroclasts. It comprises Ha-
waiian/Strombolian scoria cones and lava flows 
and one surtseyan cone. The only available age 
for this formation is a low quality K/Ar date of 
0.03 ± 0.02 Ma (Féraud et al., 1980).

The western region of Faial is formed by a
dextral en échelon alignment of basaltic Hawai-
ian/Strombolian and surtseyan cones and lava
flows, the Capelo Volcanic Complex (Cp in fig.
4), built on the west slope of Caldeira volcano.
It is younger than 10.000 years (as it overlies the
oldest pyroclasts of Caldeira Formation), and in-
cludes two historical eruptions (1672 and 1957
in fig. 4).

As already mentioned, the active faults con-
trol the general shape of the island (fig. 4). The
eastern part of Faial Island is characterized by 
a WNW-ESE trending graben structure (Pedro
Miguel Graben) composed of seven normal dex-
tral faults: Ribeirinha (R) (fig. 5), Chã da Cruz
(CC), Lomba Grande (LG), Ribeira do Rato
(RR), Rocha Vermelha (RV), Espalamaca (E)
and Flamengos (F) faults. The graben is partial-
ly fossilized by Holocene pyroclastic fall and
flow deposits from the Caldeira Formation in
the central area of the island. Other WNW-ESE
important faults are located south of the caldera
(Lomba do Meio - LM, and Lomba de Baixo -
LB, faults) and in the western part of the island
(Ribeira do Adão - RA; Ribeira das Cabras - RC;
Ribeira Funda - RF, and Capelo - C, faults).

The conjugate fault system, trending NNW-
SSE to NW-SE, composed of normal left later-
al faults, is secondary in importance: geomor-
phic expression is less developed and lengths
are smaller. Between the southern rim of the
caldera and the Lomba do Meio Fault these
structures are more abundant (inset in fig. 4)
displacing and controlling the smaller order
drainage. The longer faults are those of Água-
Cutelo (AC), Salão (S), and Cedros (CD).

3.1.2.  Historical seismicity - the 1958 
earthquake swarm

There are no records of earthquakes felt in
Faial until the 1614 event that struck Terceira
Island. However, significant local earthquakes
only occurred during the 20th century, almost
500 years after settlement. The 1924 earth-
quake, the 1926 seismic swarm, and the 1998
event caused important damage in Eastern
Faial. In 1958, a seismic swarm, contemporary
of the Capelinhos eruption, caused buildings

739

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)



740

José Madeira and António Brum da Silveira

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collapse and ground deformation along faults in
central and western areas of the island.

The 1958 seismic swarm started in May 12,
and continued until June. During the first three
days of most intense seismic activity, 450 earth-
quakes, some of which reaching intensities VIII
and IX (MCS-17 scale) in the epicentral region
(Western Faial), were felt. Seismicity caused
total collapse of 508 houses and heavy damage
in 1000. Housing was (and still is in many rural
areas) characterised by low quality, highly vul-
nerable, one or two storeys high, stone build-
ings (A and B vulnerability classes according 
to the 1998 European Macroseismic Scale;
Grünthal, 1998). The stronger earthquakes
caused surface deformation along several faults
(Capelo, Lomba do Meio, Lomba de Baixo,
Ribeira do Adão, Ribeira das Cabras, Lomba
Grande, and Espalamaca); mainly ground crack-
ing but, locally, 0.5 to 1 m vertical displace-
ments were reported. Photographs of ground
cracks also suggest right lateral slip (fig. 6a,b;
Zbyszewski and Ferreira, 1959). Widening or
narrowing of ground fissures during the first

two weeks of the seismic swarm is also referred
(Tazieff, 1959; Zbyszewski and Ferreira, 1959).
However, these effects were never studied in
detail or mapped because attention was focussed
on the ongoing eruption. At the epoch only 3
seismic stations existed in the archipelago
(installed in 1902 in S. Miguel and Faial, and in
1932 in Terceira; Silveira, 2002), but the equip-
ment in Faial was inoperative at the time. Pre-
sently a few tension cracks still persist along
fault scarps in the up-thrown block of Lomba
do Meio Fault.

3.1.3.  Geometry, kinematics and geomorphic 
expression of Lomba do Meio Fault

The southern slope of the Caldeira Volcano
is crossed by the north dipping Lomba do Meio
(inset in fig. 4; fig. 7) and Lomba de Baixo
faults. To the east, the Lomba do Meio Fault
links with the Espalamaca Fault through a
restraining bend that follows the west and north
slopes of the Cabeço Gordo height, which is

741

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)

Fig.  5. Fault scarp of Ribeirinha Fault, in NE Faial, viewed from the west. Ribeirinha village in the down threw
block gives the scale. The observed maximum height of scarp is 120 m in the centre of photograph.



interpreted as a push-up structure. To the west, it
links to Capelo Fault, a fracture system defined
by the alignment of cones and craters of Capelo
Volcanic Complex (< 10 ka), displaying right
lateral en échelon geometry, which extends to
Capelinhos volcano in the western tip of Faial.
In this particular area, Capelo Fault is expressed

by tens of sub-vertical fractures, concentrated in
a 250 m wide zone, cutting trough the pyro-
clastic sequence of a surtseyan cone exposed in
a paleo-sea cliff east of Capelinhos volcano.
These fractures display an accumulated NE
down throw of 50 cm. Thus, the Capelo, Lomba
do Meio and Espalamaca faults constitute three

742

Fig.  7. Fault scarps of Lomba do Meio Fault, in central Faial, viewed from the east. The main fault scarp is 
50-60 m high, but is amplified by fluvial incision. Notice dextral en échelon secondary scarps in up-thrown
block. Trench was open in front of the most distant electric pole (left side of photo).

José Madeira and António Brum da Silveira

Fig.  6a,b. Examples of surface deformation produced during the May 1958 seismic swarm in the island of
Faial: a) pull apart tension cracks (a) in dextrally sheared dirt road in Praia do Norte. NNW-SSE conjugate sys-
tem (b) is also present; b) surface rupture along fault scarp in Cabeço Gordo area. Note normal dextral dis-
placement of surface irregularities (a) and fractures with the orientation of conjugate system (b). Similar features
were observed in Faial after the July 9th, 1998, earthquake. Photographs reproduced from Zbyzewski and Veiga
Ferreira (1958) with kind permission of Instituto Geológico e Mineiro.

a b



sections of the same tectonic structure, charac-
terized by normal dextral slip.

The Lomba do Meio Fault geomorphic ex-
pression is a 50 m high, north facing, fault scarp
coupled with a set of right lateral en échelon
secondary fault scarps on the up-thrown block
(fig. 7). A trench was open across one of these
secondary en échelon scarps, where surface rup-
ture was reported in the 1958 seismic swarm.
Other reasons for this location were the size of
the main LM Fault Scarp, fresh aspect and py-
roclastic constitution of the secondary fault
scarps.

3.1.4.  Paleoseismic analysis of Lomba 
do Meio Fault

The trench exposed a sequence of pyro-
clastic deposits and colluvial wedges displaced
by a fault zone composed of three main fault
planes (A1, B and C) defining a graben and horst
structure (figs. 8 and 9). Fault plane B is re-
sponsible for the fault scarp, which is slightly
degraded. Stratigraphy is composed of trachyte
(1, 2, 3, 4, 5, 6, 7) pyroclastic fall and flow de-
posits, basaltic ash fall layers (9, 11), and collu-
vial wedges (8, 10, 12, 13); the sequence ends
with the topsoil.

Only one radiocarbon age was derived from
the trench; however, it was possible to correlate
some of the volcanic deposits exposed in the
trench with volcanic layers radiocarbon dated
outside the trench (Madeira et al., 1995; table
IV). On the basis of these stratigraphic corre-
lations, 2. intervals of dendrochronologically
calibrated radiocarbon ages of units 4, 5 and 7
are: unit 4-1878 to 1420 cal B.C.; unit 5-259 to
536 cal A.D.; unit 7-890-1040 cal A.D. For unit
6 a radiocarbon age of 1500 ± 50 BP was deter-
mined, but no calibrated dates are available.
Unit 12 was dated using a fragment of wood
preserved in the base of colluvial wedge that
yielded a 2. calibrated age interval of 1290-
1640 cal A.D.

The evolution of the fault zone was deduced
from geometric analysis, nature, and composi-
tion of the deposits exposed on the trench, and
indicates the following events (graphically rep-
resented in fig. 10a-o):

a) Deposition of pyroclastic sequence 1 to
5 (deposit 5 is 259 to 536 cal A.D.).

b) Surface rupture at fault planes A1, A2
and C (seismic event 1.-.SE1) after deposition of
pyroclast 5 and before the erosive episode that
created the unconformity on which rests pyro-
clasts 6 (1500 ± 50 BP). SE1 is marked by dif-
ferent thickness of layer 5 preserved below lay-
er 6: layer 5 was totally eroded from the higher
block (north of fault C) and partially removed
south of fault C, presenting different thickness
in the central (50 cm) and southern (at least 65
cm) tectonic blocks. This indicates that normal
separation on the faults was at least 50 cm in
fault C and 15 cm in fault A. The event horizon
(the top of 5) marking this rupture was not pre-
served due to erosion after SE1.

c) Erosion of fault scarps with levelling of
topography. Deposition of pyroclast 6. Formation
of a soil on 6. Deposition of layer 7 (between 890
and 1040 cal A.D.).

d) Surface rupture on fault plane A1 and A2
with normal separation of 80 + 15 cm (SE2).
The 80 cm displacement in fault A1 was deter-
mined from the separation in the base of layer
7, taking into account the thickness of layers 5
and 6, preserved between faults B and C, and
missing in the block between faults A1 and B;
the 15 cm separation were measured in lithic
rich layers in pumice 4 displaced by fault A2.

e) Erosion degrades fault scarp and trun -
cates layer 7.

f ) Surface rupture on fault plane B (SE3)(*);
normal separation must have exceeded 2 m in or-
der to expose pumice deposit 4 (which will con-
tribute to the formation of colluvial wedge 8) in
the fault scarp; this value was obtained from the
thickness of layers 5, 6, 7 added to the preserved
thickness of colluvial wedge 8.

743

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)

(*) There is no preserved event horizon for SE2 (the
top of layer 7), which we believe was eroded between SE2
and SE3. In fact, there is no direct evidence to separate the
two seismic events. If we consider surface rupture in both
faults (A1 and C), a narrow horst structure would be crea-
ted and a synthetic fault, generating a fault scarp further
south, would be needed to root fault A. There is no eviden-
ce of such a scarp, which suggests that SE2 is an earlier
event. Furthermore, horst structures are not observed in any
of the up-thrown faulted blocks in the archipelago.



. .

. .
. .

. .

Fig.  8. Simplified and reduced (originally at the 1/10 scale) map of the Lomba do Meio trench west wall
showing three main faults related to LM fault zone. Fault B is related to the present fault scarp, which is
slightly degraded. Stratigraphic sequence exposed in the trench is composed of: 1 - trachyte hydromag-
matic explosion breccia; 2 - trachyte explosion breccia (or colluvium?); 3 - trachyte weathered ash layer
(or colluvium?); 4 - trachyte pumice fall deposit, with a massive structure except for a few lithic rich lay-
ers; 5 - trachyte massive phreatomagmatic pyroclast composed of fine ash and lithics; 6 - trachyte weath-
ered pyroclast grading from lapilli to fine ash overlying an erosive surface cut on 5 and 4; 7 - trachyte
phreatomagmatic surge deposit with alternating fine ash and lapilli layers; the base is an erosive surface;
8 - wedge shaped colluvium made of pumice and lithics from level 4; the base is an erosive surface; 9 -
basaltic fine ash fall layer deposited on an erosive surface; the ashes fell into, and partially filled, open
cracks below; 10 - wedge shaped colluvium made of pumice and lithics from level 4 and basaltic ash from
level 9; the base is an erosive surface; 11 - discontinuous basaltic fine lapilli layer; it rests on 4, 7, 9 and
10 trough an erosive surface; 12 - wedge shaped colluvium containing pumice and lithics from level 4
and basaltic lapilli from level 11; 13 - wedge shaped colluvium containing pumice and lithics from level
4 and turfaceous material similar to that of the soil developed on 12; the sequence ends with the present
turfaceous soil which was displaced by fault plane B during the 1958 seismic swarm. Inset shows slope
profiles across the fault and location of trench: A - smaller scale profile across Lomba de Baixo (LB) and
Lomba do Meio (LM) faults (vertical and horizontal scales equal; vertical scale indicates altitude in
metres); B - profile of main Lomba do Meio Fault and associated secondary faults in up-thrown block
(dashed lines represent original topography before erosion). Radiocarbon calibrated dates of deposits 
(2 intervals) indicated: dates obtained outside the trench, attributed by correlation of deposits, in grey
rectangles.

José Madeira and António Brum da Silveira

744



745

g) Fault scarp retreat and formation of col-
luvial wedge 8, composed of pumice of layer 
4 and basaltic lithics from layers 5, 6 and 7.
Deposition of a basaltic ash layer (9) correlative
of a basaltic eruption. Erosion and partial remo-
val of basaltic ashes.

h) Surface rupture in fault planes B and C
(SE4); in fault B the value of normal sepa-
ration is unknown, but must have exposed
pumice of layer 4 in the fault scarp; in fault
plane C vertical separation was equal or small-
er than 9 cm.

i) Fault scarp retreat and formation of col-
luvial wedge 10, composed of ashes from layer
9, pumice from 4, and lithics from 5, 6 and 7.
Deposition of basaltic ashes (11) correlative of
a basaltic eruption. Partial erosion of basaltic
ashes that became discontinuous.

j) Surface rupture of fault plane B with
normal separation of unknown value (SE5).

k) Fault scarp retreat and formation of col-
luvial wedge 12, composed of ashes from 11,
pumice from 4, and basaltic lithics. A soil
developed on the colluvium. Calibrated radio-
carbon age of a wood fragment from the base of
the colluvium is 1290-1640 cal A.D.

l) Surface rupture in fault planes B (un-
known separation) and C (vertical separation 
of 11 cm) (SE6).

m) Fault scarp retreat and formation of col-
luvium 13, composed of pumice, basaltic ashes,
basaltic lithics and turfaceous soil fragments
from layer 12.

n) Erosion truncates colluvia 12 and 13;
colluvium 13 became discontinuous. Development
of present top soil (14).

Fig.  9. Oblique view Lomba do Meio trench west wall from outside the trench. A small graben, in the centre
of the trench, is bound by faults B and C. Darker deposit in centre of graben is basaltic ash 9. To the left (south)
of fault B is pumice 4. To the right of fault C deposits 6, 7 and basaltic ashes 9 and 11 are easily distinguishable.
A pen (enclosed by circle) gives scale.

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)



746

José Madeira and António Brum da Silveira

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o) Surface rupture on fault plane B (verti-
cal separation of 15 cm?). This event (SE7) is
assigned to the May 1958 seismic swarm.

Thus the Lomba do Meio trench revealed 7
surface rupturing seismic events in 1606 ± 138
years that can be summarized as follows:

1) The older event occurred between 259 to
536 cal A.D. and about 400 to 500 years before
deposition of layer 7 (890 to 1040 cal A.D.) in-
volving fault planes A1, A2, and C and an ac-
cumulated normal separation exceeding 65 cm.

2) The following four events occurred be-
tween 890 to 1040 cal A.D. and 1290 to 1640
cal A.D.; the second event reactivated fault
planes A1 and A2 and produced vertical separa-
tions of 80 and 15 cm respectively; the third
event produced rupture in fault plane B and a
separation exceeding 2 m in order to expose the
pumice deposit in the fault scarp; the fourth
event reactivated fault planes B and C with
unknown normal separation (probably > 70 cm,
deduced from the preserved thickness of collu-

vium 10) in fault B and 9 cm in fault plane C,
producing 60 cm of down-throw to the north;
the fifth event involved fault plane B producing
normal separation of unknown value (probably
> 60 cm) and may be related to deposition of
colluvial wedge 12 (between 1290 and 1640 cal
A.D.); this event preceded settlement.

3) The sixth event reactivated fault planes
B (unknown normal separation, possibly 50
cm) and C (vertical separation of 11 cm). There
is no historic written record of this event, which
probably occurred just before settlement (ar-
ound 1450 A.D.).

4) The last event involved fault plane B
during the May 1958 seismic swarm, producing a
vertical separation of 15 cm at the trench site.

Time distribution of the 7 events shows one
cluster of 5 events in a 510 ± 100 calendar years
period, separated by 500 years intervals be-
tween the first and the last events.

The average recurrence interval is 229 ± 20
years, but the recurrence interval during the

. . . .

. .
. .

Fig.  10a-o. Sequence of events (tectonic, depositional and erosional) leading to present day geometry exposed
in Lomba do Meio trench. Radiocarbon-dated deposits and surface rupturing seismic events (SE 1-7) indicated.
Full description in text.

a ecb d

f jhg i

k oml n

747

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)



cluster is 102 ± 20 years with clusters separat-
ed by approximately 500 years intervals.

The exposed fault planes are certainly
linked to the main Lomba do Meio Fault Zone
at depth, in which antithetic faults develop in
relation to synthetic splays of the main plane.
Fault plane C should branch into fault plane B,
and fault planes A1 and A2 may be linked to an
undetected synthetic fault further south.

Accumulated slip in the sampled 1600 years
period is > 1.10 m in fault planes A1.+.A2, in
fault plane B it was 4.20 m, and 0.70 m in fault
plane C. As planes A and C are antithetic to the
Lomba do Meio main fault, the trenched por-
tion of the fault zone produced a net down-
throw of 2.40 m to the north in 1600 years.
However, after 890 to 1040 cal A.D., fault plane
B accumulated 4.20 m, while in fault plane C
only 0.20 m of antithetic normal slip occurred,
thus yielding 4 m of down throw to the north in
a 1113 to 963 years period.

Slip rate deduced from Lomba do Meio
trench data is 3.6 to 4.2 mm/year. Considering
that the Lomba do Meio main fault produced
50-60 m down throw in pyroclasts from Cal-
deira Formation in the last 10-15 ka a longer-
term slip rate of 3.3 to 6.0 mm/year is obtained.
Both slip rate values are of the same order of
magnitude.

The detected displacements are just the
observable normal component of slip (no mark-
ers for strike slip component were found), in
just a few strands of the entire fault zone. Total
net slip is certainly larger.

3.2. Pico

The island of Pico is 46 km long, has a max-
imum width of 15.8 km and reaches an altitude
of 2351 m at Ponta do Pico (Pico volcano).

The sub aerial part of the island is com-
posed of two central volcanoes and one fissural
volcanic zone (Madeira, 1998; Nunes, 1999).
The older shield volcano (Topo volcano) is par-
tially dismantled by landslides, displaced by
faulting, and covered by younger volcanics. It is
composed of ankaramitic and basaltic lava
flows assembled under the designation of Lajes
Volcanic Complex (Lj in fig. 11); a single pub-

lished K/Ar date yielded an age of 250.±.40 Ka
(Baubron, 1981, in Chovelon, 1982). An inter-
mediate volcanostratigraphic unit, the Calheta
do Nesquim Volcanic Complex (Cn in fig. 11),
comprises fissural basaltic strombolian scoria
cone alignments and associated lava flows; this
unit outcrops in several areas on the eastern part
of Pico. Three K/Ar ages are available for the
Calheta do Nesquim Volcanic Complex ranging
from 270 ± 150 to < 25 Ka (Féraud et al., 1980;
Baubron, 1981 in Chovelon, 1982). The Mada-
lena Volcanic Complex is the younger unit in
Pico, which includes three historic eruptions in
1562, 1718 and 1720; very fresh morphology
suggests a Holocene age which is confirmed by
radiocarbon dates younger than 6000 years
(Madeira, 1998; Nunes, 1999). Structurally it can
be divided into two sub-units: the Pico Volcano
and the East Fissural Zone members (respec-
tively Mp and Mf in fig. 11). Pico is a strato-
volcano displaying a pit crater on its summit.
The east fissural zone is composed of several
alignments of Hawaiian/Strombolian scoria
cones and related lava flows; these flowed o-
ver cliffs cut in older units and originated lava
deltas.

Tectonic structure is characterized by two
fault systems (fig. 11). The main WNW-ESE
trending structures are the normal dextral
Lagoa do Capitão (LC) and Topo (T) fault
zones that progressively merge to the east; these
define a graben structure, narrower and shal-
lower than Pedro Miguel Graben (in Faial
Island). The western portion of the graben is
completely covered by the recent Pico strato-
volcano (< 10 Ka) and to the east it is partially
filled by lava flows and cones of the East
Fissural Zone member of Madalena Volcanic
Complex. Most structures on the eastern plateau
of Pico, whose morphology is marked by vol-
canic alignments and short fault scarps, belong
to this system.

The NNW-SSE trending conjugate faults
are less abundant and are marked, mainly, by
volcanic alignments. Although scarce, there is
evidence of normal left lateral, oblique slip. The
Lomba de Fogo-S. João (LF) fracture, along
which the 1718 volcanic eruptions occurred,
and the Santo Antonio (SA) volcanic alignment
are the most obvious structures. At the outcrop

748

José Madeira and António Brum da Silveira



749

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)

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scale, several faults from this system were ob-
served at Cabeço Vermelho (CV) quarry and in
Lagoa do Capitão trench.

Most scoria cones occur along WNW-ESE
structures, but the larger cones and Pico vol-
cano are located at the intersection of these with
the NNW-SSE conjugate faults.

At least two large gravitational (flank col-
lapse) structures were observed on the flanks
of the Pico stratovolcano and Topo shield vol-
cano: the landslide scars of S. Mateus and
Arrife.

3.2.1.  Geometry, kinematics and geomorphic 
expression of Lagoa do Capitão Fault

The Lagoa do Capitão Fault Zone runs
WNW-ESE for at least 30 km in the central and
eastern areas of the Island of Pico. It has com-
plex map geometry, with duplexes and splays,
and presents a set of south facing, 9 km-long,
fault scarps (inset in fig. 11) that reach a maxi-
mum height of 20 m. Towards the east, the
scarps disappear under recent scoria cones, one
of which formed during the 1562-1564 erup-
tion, but the fault trace is marked by alignments
of craters. Several sag ponds are associated with
this fault zone, the most important of which is

Lagoa do Capitão (Captain’s lake). To the west,
the Holocene volcanic pile of Pico stratovol-
cano buries the fault.

The Lagoa do Capitão Fault zone displaces
right laterally a few older scoria cones (for ex-
ample Cabeço do Caveiro; fig. 12a,b), indicat-
ing an oblique, dextral normal, slip.

3.2.2.  Paleoseismic analysis of Lagoa 
do Capitão Fault

An 8.5 m long trench was open across the
main strand of Lagoa do Capitão Fault, about
400 m east of the lake (fig. 13). The sequence
exposed is composed of alternating layers of
basaltic pyroclasts and colluvium, overlying a
basement of basaltic lava flows: 1 - pyroxene/
olivine rich basalt aa lava flow; 2 - pyroxene
rich basalt scoria and lapilli fall layer; 3 - collu-
vium deposit containing basalt clasts (from 1?)
and lapilli (from 2?) in clay matrix; a paleosol
developed on this deposit is preserved in places;
4 - discontinuous, strongly weathered, pyro-
xene rich, basalt lapilli fall layer; 5 - colluvium
deposit containing lapilli from 4 in clay matrix;
6 - basalt lapilli fall layer similar to 4; 7 - col-
luvium containing lapilli from 4 and 6; 8 - fine,
pyroxene rich, basalt lapilli layer, containing

750

Fig.  12a,b. Vertical aerial photograph of Cabeço do Caveiro region in the island of Pico showing an example
of strike-slip evidence: a) uninterpreted photo; b) interpreted photo showing base (dotted lines) and craters (arcs)
of scoria cones and fault traces. Cabeço do Caveiro cone is right laterally displaced.

José Madeira and António Brum da Silveira

a b



dispersed scoria fragments; the sequence ends
with the present soil. All contacts between lay-
ers are erosive.

The face of the scarp is cut in lava flows; the
same four layers of lapilli are found overlying
the lava flows in the up thrown block, but there
they are separated by paleosols instead of collu-
via (inset B, fig. 13). The topographic position of
the colluvial deposits (higher than the depressed
region located to the south) and its absence in the
up-thrown block confirms that they derive from
the fault scarp, although it is not possible to re-
late them to scarp forming events. The irregular
geometry of the colluvial deposits is a conse-

quence of erosive episodes that occurred during
intervals between deposition of successive lapil-
li layers and colluvia. Neither the original geom-
etry of colluvial deposits, nor that of pyroclastic
layers is preserved.

The trench revealed two main faults, one
directly related to the scarp (fault A), and anoth-
er (fault B), 4 m to the south, without any sig-
nificant geomorphic expression (fig. 13). Each
fault is composed of numerous slip surfaces,
predominantly vertical, sometimes with open
voids, presenting small vertical separations that
suggest dominant strike slip component associ-
ated to down throw to the south.

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)

Fig.  13. Simplified and reduced (originally at the 1/10 scale) map of the Lagoa do Capitão trench west wall
showing two faults (A and B) associated to LC Fault Zone. The fault scarp, slightly degraded, is related to the
northern fault. Stratigraphic sequence is composed of alternating layers of basaltic pyroclastic fall deposits 
(2, 4, 6, 8) and colluvial wedges (3, 5, 7; in grey), overlying a basement of basaltic lava flows (1); the sequence
ends with present topsoil. All contacts are erosional. Inset A: slope profile across the fault and location of trench.
Inset B: pyroclastic sequence (2, 4, 6, and 8), separated by dated paleosols and overlying lava flow 1, observed
in up-thrown block. Radiocarbon dated deposits indicated (in years BP).

751



Samples for radiocarbon analysis were col-
lected from the colluvial layers in the trench and
the paleosols separating the lapilli layers in the
up-thrown block (fig. 13; table IV). The results
revealed radiocarbon/relative age incompatibili-
ties, and no age correlation between colluvia and
paleosols separating equivalent lapilli layers;
nonetheless, all samples yielded Holocene ages
( 5300 -1000 years old; Madeira, 1998), includ-
ing material fallen into voids in fault A (1140 ±
± 90 BP), indicating recent surface faulting. This
agrees with the observation that the topsoil
seems displaced by fault A.

No paleoearthquakes were deduced from the
trench because of absence of reliable stratigraph-
ic markers and cumulative vertical separations
from the exposed sequence. The pyroclastic and
colluvial layers, where they are cut by the fault
planes, show variable separations and thickness-
es suggesting dominant strike slip component.
The vertical separation between correlative lapil-
li layers exposed in the trench and outcropping
on the up-thrown block, is apparent, as the pyro-
clasts were probably emplaced over a pre-exist-
ing scarp cut on lava flows.

3.3. S. Jorge

The island of S. Jorge is a 55 km long fis-
sural active volcano, with a maximum width of
6.7 km, and reaching an altitude of 1053 m at
Pico da Esperança.

The volcanic products in S. Jorge, all bas-
altic in nature, are divided into three stratigraphic
units (Forjaz and Fernandes, 1970, 1975; Forjaz
et al., 1970, 1990; Madeira, 1998). The older
Topo Volcanic Complex (Tp in fig. 14) consti-
tutes the eastern part of the island. It is a fissur-
al volcanic zone composed of scoria cones and
lava flows. Marine erosion already destroyed
the northern half of the lava pile and most of the
axial cones, creating steep cliffs 400 to 800 m
high. Cones are only preserved in the east tip of
S. Jorge. Four published K/Ar ages (Féraud et
al., 1980) range from 550 ± 60 ka in lavas from
the base of the pile, at sea level, to 110 ± 70 and
140 ± 50 ka in the higher lava flows. The Rosais
Volcanic Complex (Ro in fig. 14) constitutes
the basement of the western part of the island

and is similar to Topo Volcanic Complex. The
scoria cones in the Rosais axial zone are less
degraded and its products less weathered than
those of Topo suggesting that this unit is
younger. No ages are available for this unit and,
because younger lavas cover the contact
between Rosais and Topo complexes, it is not
possible to establish a field relation in order to
confirm the assumed stratigraphic relation. The
younger unit is Manadas Volcanic Complex
(Mn in fig. 14). It is also a fissural volcanic unit,
composed of two alignments of Hawaiian/
Strombolian and Surtseyan cones (one along the
axis of the island and another diverging from
the former towards the south coast) and the re-
lated lava flows. Three eruptions occurred in his-
toric times: two on land in 1580 and 1808 and a
probable submarine event in 1964 (fig. 14). The
Manadas lavas flowed over cliffs cut in Rosais
Volcanic Complex creating lava deltas (locally
called fajãs). Radiocarbon dates indicate 
a Holocene age for this unit; ages of 10 pre-
historic volcanic events range from 5310 ± 80
to 700 ± 70 years BP (Madeira et al., 1998b).

Two main normal dextral WNW-ESE fault
zones dominate the younger western half of the
island: Picos (P) and Pico do Carvão (PC) fault
zones (figs. 14 and 15). On the older eastern
half, a set of faults with the same direction
defines a graben structure; the most important
tectonic structure in that region is the Urze-S.
João (USJ) Fault which displays a 10 km long
continuous scarp. The two regions are separated
by the left lateral normal NNW-SSE Ribeira
Seca (RS) Fault represented by a west facing
very degraded scarp. The volcanic axis of the
island is left laterally offset by at least 3 km,
although the fault seems presently inactive.
Three other NNW-SSE structures are marked by
alignments of scoria cones west of Ribeira Seca
Fault.

3.3.1.  Historical seismicity

The Island of S. Jorge has been struck by
two high magnitude earthquakes since settle-
ment: the July 9th, 1757, with an estimated
magnitude M = 7.4 (Machado, 1949) and the
January 1st, 1980, M = 7.2 event (Hirn et al.,

752

José Madeira and António Brum da Silveira



753

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)

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1980). In both cases the rupture occurred on
offshore faults. The 1980 earthquake, with epi-
centre between S. Jorge, Terceira and Graciosa,
produced important destruction on the eastern
half of the island and some tens of deaths. The
1757 historic event was even more destructive:
all the eastern region of S. Jorge, from the 
village of Calheta to Topo, was completely
destroyed, killing 1000 people in a population
of 5000. This earthquake has been related to
fault rupture in S. Jorge Channel (between S.
Jorge and Pico islands) (Machado, 1949), sur-
face rupture in Pico do Carvão Fault (Ribeiro,
1982), or a fault rupture close to the north coast
of the island (Madeira, 1998). The last hypoth-
esis is favoured because a small tsunami, re-
ferred in contemporary texts, was observed in
Terceira and Graciosa islands, located north of
S. Jorge (fig. 2).

3.3.2.  Geometry, kinematics and geomorphic 
expression of Pico do Carvão Fault

The Pico do Carvão Fault Zone is composed
of three parallel strands, which cross the island
of S. Jorge in a N75W direction. It extends for
12 km, from Pico do Carvão cinder cone, where
it merges with Pico Fault Zone (figs. 15 and 16),
to Morro Grande (Velas) surtseyan cone; to the
west it probably extends to the site of the 1964
submarine eruption, adding, at least, 5 km more
to its length. En échelon secondary scarps and a
displaced crater indicate that the fault is an ob-
lique, normal dextral, structure.

Holocene volcanism from the Manadas Vol-
canic Complex (Madeira et al., (1998b) occur-
red along this structure and its products are local-
ly displaced by the fault. As a result, Pico do
Carvão Fault Zone exhibits a well developed and

754

José Madeira and António Brum da Silveira

Fig.  15. Oblique aerial photograph of central part of the island of S. Jorge, above the axial chain of cones, seen
from the west. Picos Fault Zone is marked by alignment of cones, craters and scarplets. Pico do Carvão Fault
Zone is represented by continuous scarp extending to Pico do Carvão cone where it merges with Picos Fault.

Fig.  16. Pico do Carvão fault scarp seen from the west, with Pico do Carvão scoria cone in background. Persons
(encircled) give scale and mark the location of trench.

15 16



continuous geomorphic expression, represented
by alignments of volcanic cones and craters and
a fault scarp at the eastern sector; the north fac-
ing scarp is 1750 m long and 2.5 to 10 m high
(inset in fig. 14; figs. 15 and 16).

3.3.3.  Paleoseismic analysis of Pico 
do Carvão Fault

An 11.5 m long trench was opened across
the Pico do Carvão fault scarp (fig. 17). It re-
vealed a faulted sequence of basalt lapilli fall
deposits (layers 1, 2, 3, 4 and 9) with paleosols
developed on top, colluvial deposits from the
erosion of the fault scarp (layers 4a, 5, 6, 7 and

8b) and carbonaceous clay sediments interpret-
ed as sag pond deposits (layer 8). The lapilli
layers display southward dips, parallel to the
slope. The sedimentary deposits related to the
fault scarp are gently dipping to the north, or
filling the tectonic depression.

Most of the deposits were radiocarbon dat-
ed (table IV; Madeira et al, 1998b): layer 2 -
younger than 2286-1975 cal B.C. (age of the pa-
leosol developed on 1); layer 3 - younger than
248-545 cal A.D. (age of the paleosol devel-
oped on 2); layer 4 - younger than 1221-1406
cal A.D. (age of the paleosol developed on 3);
layer 4a - older than 1221-1303 cal A.D. (soil
developed on 4a); layer 5 - 1290-1638 cal A.D.
(wood fragment in the base of 5); layer 8  -

Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)

. .

. .

. .

. .

. .

. .

. .

. .

Fig.  17. Simplified and reduced (originally at the 1/10 scale) map of Pico do Carvão trench east wall. The
exposed sequence is composed of: 1 - pyroxene rich, basalt lapilli fall layer; 2 - pyroxene rich, basalt scoria and
lapilli deposit, including a lower massive coarser zone (2a), a well stratified central deposit (2b), and a upper
massive zone, altered by pedogenesis (2c); 3 - sanidine and pyroxene rich basalt lapilli fall deposit; 4 - lithic rich
basalt lapilli fall layer; 4a - colluvial wedge formed by clay supported lapilli, pyroxene and sanidine crystals
from layers 3 and 4; 5 - colluvial deposit formed by clay supported lapilli and scoria; 6 - colluvial deposit sim-
ilar to layer 5; 7 - colluvial deposit, similar to 5, containing intercalated thin layers of fine basaltic ash; 8 - sag
pond clayey sediment containing wood fragments, discontinuous peat horizons, and a basaltic fine ash layer
(from 1580 eruption), passing laterally to colluvium closer to the fault scarp (8b); 9 - discontinuous basalt lapil-
li fall layer (probably from 1808 eruption). The sequence ends with a thin soil. Inset shows slope profile across
the fault and location of trench. Radiocarbon calibrated dates of deposits indicated (2 intervals).

755



1440-1641 cal A.D. (wood fragment from the
base of 8) to 1663-1955 cal A.D. (peat layer
some centimetres above an ash layer of the
1580 A.D. eruption); layer 9 - lapilli of the 1808
A.D. eruption.

The fault plane strikes N63-81W, dips 
75°-85° to the NNE, and presents an anasto-
mosed geometry (figs. 17 and 18). No striated
surfaces were observed. The fault produces 
3.5 m of vertical displacement of levels 2 to 4,
indicating surface rupture following deposition
of layer 4, about 750-700 years ago. Since then
the fault scarp receded about 1.8 m but main-
tains a steep inclination, supported by fast grow-
ing vegetation.

Millimetric displacements of thin ash layers
in colluvium 7 indicate upward propagation of
the fault plane during the 700 to 380 years BP
time interval.

There are two possible interpretations for
the recent tectonic activity on the trenched Pico
do Carvão Fault strand. One is that only one
major surface rupture occurred 750-700 years
ago, producing the 3.5 m of displacement ob-
served on stratigraphic references from layers
2, 3 and 4. Another interpretation is that the 
3.5 m separation is the sum of displacements
produced by more than one surface rupturing
events in the period between 700 ± 70 BP to
380 ± 40 BP. There is no way of verifying if
layers 5 and 6 accumulated different amounts
of normal separation because they are only pre-
served in the downthrown block. However, the
propagation of the fault plane to colluvium 7 is
indirect evidence that those colluvia may be
tectonically displaced (figs. 17 and 18).

Different estimates for the average recurrence
interval between seismic events producing sur-

756

José Madeira and António Brum da Silveira

Fig.  18. Photograph of central part of the east wall of Pico do Carvão trench. Fault plane is sharp vertical con-
tact below arrow. To the right (south) of fault plane is lapilli deposit 1 and to the left (north) are deposits 3, 4 and
colluvial wedge 4a. Above the fault trace is colluvium 7.



face displacement derive from the two hypothe-
ses. The first interpretation is that one major
earthquake occurred 782-597 years ago, after a
time interval of at least 3000 years without sur-
face rupturing events; this is deduced from the
fact that levels 2, 3 and 4 show the same amount
of normal separation. The second interpretation is
that, after 3000 years without surface rupture,
more than one event (possibly two, represented by
colluvial wedge 4a and colluvium 6?) occurred
within an interval of less than 420 years (from
1221-1406 A.D. to 1440-1641 A.D.), producing an
accumulated separation of 3.5 m. This may indi-
cate the occurrence of short periods of seismic clus-
tering, as observed in Lomba do Meio trench, sep-
arated by longer periods without surface rupture.
Recurrence interval between single events or clus-
ters of events is equal or larger than 3000 years.

The slip rate in the trenched strand of the
Pico do Carvão Fault, taking into account that
3.5 m of slip accumulated in an interval of 

3700 years, is of the order of 1 mm/year for
the normal component of the fault.

4.  Conclusions: neotectonics 
and paleoseismology

In this area of the Azores Plateau, fieldwork
observations identified a faulting pattern charac-
teristic of three-dimensional strain (Reches, 1983;
Reches and Dieterich, 1983), represented by two
main fault systems with oblique slip, each com-
posed of two sets dipping in opposite directions.

The fault geometry and kinematics indicate
a stress field with the minimum horizontal 
compressive stress axis ( .3) trending NE-SW.
However, permutations between maximum ( .1)
and intermediate ( .2) compressive stress axis
(NW-SE horizontal, and vertical, respectively),
may originate transtensile or tensile regimes
(Reches, 1983). This may explain a history of
alternating phases of tectonic activity and phas-
es of volcanism, observed in the archipelago
since settlement.

In the studied islands, all faults can be con-
sidered active (in the sense of Boschi et al.,
1996) as they displace volcanic sequences
younger than 100 ka (Féraud et al., 1980;
Chovelon, 1982).

Long-term slip rates range from tens of mil-
limetre to some centimetres per year (Madeira,
1998) and nearly 70% of the estimates are in
the order of 0.10 to 0.40 cm/year. Paleoseismic
slip rates are in the same order of magnitude
(table V).

Average recurrence intervals were estimated
in both Lomba do Meio and Pico do Carvão
trenches (table V). In Lomba do Meio, surface
rupturing events suggest clustering separated
by gaps of roughly 500 years. Recurrence inter-
val within cluster is 102 ± 20 years. In Pico do
Carvão, information is less reliable but also
suggests that clustering may occur; the time gap
before first paleoearthquake is 3000 years,
and two earthquakes may have occurred in less
than 420 years.

In Lagoa do Capitão the age of deposits fill-
ing voids in fault plane A, suggests that the
most recent surface rupturing event may have
occurred about 1000 years ago, providing a min-
imum value for the recurrence interval.

Slip per event values, determined in Lomba
do Meio trench, vary from 0.15 m to more than
2 m (SE1 - > 0.65 m; SE2 - 0.95 m; SE3 - > 2.0
m; SE4 - > 0.60 m; SE5 - > 0.60 m; SE6 - 
> 0.40 m; SE7 - 0.15 m). One, or two, surface
rupturing events accumulated 3.5 m of normal
slip in Pico do Carvão trench; in the second
hypothesis, considering that colluvial wedge 4a
had an original thickness of 1 m at the fault
scarp, the two events may have produced 2 m
and 1.5 m of slip, respectively.

According to the available parameters (slip
rate, recurrence interval and slip per event), the
degree of fault activity, in the studied islands, is
high to moderate (classes 2 to 4 according to
Slemmons, 1982).

5.  Discussion and conclusions:
seismic hazard assessment

Seismic hazard assessment in the Azores is
a complex task. One problem is the determina-
tion of strike slip component in oblique slip
faults; often, in the lack of markers for strike
slip, only the dip slip component is detecta-
ble, leading to underestimated net slip values.
Another complexity is that geologic record

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Active tectonics and first paleoseismological results in Faial, Pico and S. Jorge islands (Azores, Portugal)



does not allow the discrimination between 
coseismic, post-seismic and aseismic slip; 
this problem is being currently assessed by 
GPS monitoring of a network of 60 markers,
strategically implanted on the three islands
(DISPLAZOR, 2002). An additional difficulty
is that the interaction between volcanism and
faulting complicates the interpretation of paleo
surface ruptures; there is evidence that surface
deformation associated to eruptions may con-
centrate along pre-existing faults, leading to
surface displacement events that are difficult to
distinguish from those produced by coseismic
deformation. Furthermore, the available empir-
ical relations between seismic rupture parame-
ters and magnitude are not adequate for the par-

ticular tectonic environment in the Azores Pla-
teau (oceanic crust in a transtensile regime),
where lithospheric structure is not well under-
stood, and a thin oceanic crust interacts with
magmatism.

Testing the Wells and Coppersmith (1994)
equations with rupture parameters of two recent
earthquakes shows that the magnitudes obtained
do not differ significantly from those assigned
by seismology methods. The 1st January 1980,
6.9 to 7.2 magnitude, earthquake (Hirn et al.,
1980; Moreira, 1991) produced a 50-60 km long
surface rupture, based on the epicentral distribu-
tion of aftershocks (Hirn et al., 1980). Applying
the Surface Rupture Length (SRL) to the SRL/M
correlation [Mw = 5.08 + 1.16 log (SRL)] yields

758

José Madeira and António Brum da Silveira

Table  V. Estimated slip rates and recurrence intervals of faults from Faial, Pico and S. Jorge.

Fault / island
Separation (m) Age of Slip rates (cm/year)

Average

marker (Ky)
recurrence

interval Normal Strike Net Normal Strike Net
(years)

Ribeirinha 120 80 144 580 or 0.02 or 0.01 or 0.03 or
Faial 73-40 0.16-0.30 0.11-0.20 0.20-0.36
Lomba Grande 200 73-40 0.37-0.50
Faial
Rocha Vermelha 150 73-40 0.21-0.38
Faial 23 50-10 0.05-0.23
Espalamaca 145 73-40 0.20-0.36
Faial
Flamengos 115 73-40 0.16-0.29
Faial
Lomba do Meio 50-60 15-10 0.33-0.60 500
Faial 4 (*) 1.113-0.963 0.36-0.42
Lomba de Baixo 30-50 15-10 0.2-0.5 500
Faial
Capelo 0.49 1 0.05
Faial
Lagoa do Capitão 60 270-25 0.02-0.24 > 1000
Pico or 10 or 0.6
Topo-Pico 44 600 602 290-210 0.015-0.02 0.20-0.29 0.21-0.29
Picos-S. Jorge > 10 5.3-5.6 > 0.2
Pico do Carvão 3.5 (*) 3.7 0.1 3000
S. Jorge
Urze-S. João > 20 < 100 > 0.02
S. Jorge

Separations measured in main volcano-stratigraphic units by cartographic methods, from displaced morphologic
markers (Madeira, 1998), or in trenches (*).



magnitudes Mw = 7.05 to 7.14, inside the magni-
tude interval attributed by the cited authors.
Magnitude estimation from Rupture Area (RA)
[Mw = 4.07 + 0.98 log (RA)] has to deal with
unknown, and probably variable, schizosphere
thickness in the Azores. Hirn et al. (1980) indi-
cate a 14 km thickness based on the depth distri-
bution of the 1980 aftershocks, Grimison and
Chen (1986) consider 10 km, while Luís et al.
(1998), based on gravity data, suggest 7 km.
Magnitudes estimated from M/RA using the
thickness value indicated by Hirn et al. (1980)
are in better agreement with those assigned to
the 1980 event (Mw 6.9). The same verification
was made relatively to the 6.2 magnitude, July 9,
1998, event that produced a surface rupture esti-
mated as 8-10 km, based on the epicentral distri-
bution of aftershocks (Vales et al., 2000). Mag-
nitude estimates from SRL range from Mw = 6.13
to 6.24, while using RA (for a thickness of 14
km) Mw = 6.08 to 6.17 are obtained. Both SRL
and RA derived estimates are also significantly
close to the assigned magnitude.

Because of its submarine location, Maximum
Displacement (MD) is unknown in both earth-
quakes so MD/M correlation cannot be tested. In
the lack of a more appropriate equation, it is
assumed that estimation of magnitude from slip
per event, using equations such as the Wells and
Coppersmith’s, is the only available for seismic
hazard assessment.

The Mw values obtained, considering total
rupture of the known length of the Espalamaca/
Lomba do Meio/Capelo (19.5 km), Lagoa do
Capitão (30 km), and Pico do Carvão (17 km)
faults and a seismogenic thickness of 14 km
(Hirn et al., 1980), range from Mw = 6.5 to 6.8
and Mw = 6.4 to 6.7 using the M/SRL and
M/RA relations, respectively.

Higher, less credible, magnitudes are ob-
tained applying the Maximum Displacement
(MD) and Moment Magnitude (Mw) regression
equation [Mw = 6.69 + 0.74 log (MD)] (Wells
and Coppersmith, 1994). Considering the ob-
served displacements per event in the Lomba do
Meio trench (0.15 m - > 2.0 m), moment mag-
nitudes range from Mw = 6.1 to 6.9. Pico do
Carvão trench data suggest either a single,
Mw = 7.1, event (producing 3.5 m of normal
slip) or two, Mw = 6.9 and 6.8, events (generat-

ing 2 and 1.5 m of slip, respectively). Both the
MD and SRL values are underestimated, lead-
ing to under evaluation of maximum expected
magnitudes. MD values, determined in trench-
es, do not take the strike slip component in
account, and may not represent maximum dis-
placements, as they were obtained in a single
cross section of the fault. On the other hand, the
total length of faults is certainly larger because
they extend to offshore regions for which there
are no detailed bathymetry.

Furthermore, averaged recurrence intervals
do not express seismic behaviour of the faults
through time because of suggested clustering of
events; this makes it difficult to assess the prob-
ability of future earthquakes. However, the high
number of active faults in each island is clear
evidence for a high seismic potential in the area.

Acknowledgements

We thank late Prof. José Ávila Martins of
Azores University, Dr. Renato Leal, Mayor of
Horta, and Dr. Manuel Vargas, director of
Serviços de Desenvolvimento Agrário, in Faial,
Eng. José Ferreira, director of Secretaria Re-
gional da Habitação e Obras Públicas, and
Manuel Paulino Costa, Mayor of Lajes, in Pico,
and Eng. Alfredo Alvura and Miss Isabel Jorge,
directors of Secretaria Regional da Habitação e
Obras Públicas, and Frederico Maciel, Mayor
of Velas, in S. Jorge, for considerable logistical
support. Fieldwork was financed by SISPOR
(PEAM/C/RNT/35/91) and DISPLAZOR (PO-
CTI/32444/CTA/2000) research projects. Editor-
ial Committee of Instituto Geológico e Mineiro
kindly authorized the reproduction of photo-
graphs in fig. 7. We also acknowledge the con-
tribution of the reviewers and volume editor 
Daniela Pantosti to significant improvements 
in the manuscript. This is a contribution from
LATTEX- Laboratório de Tectonofísica e Tec-
tónica Experimental research team.

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