articolo galadini2.pdf


Key  words  paleoseismology  –  active fault  –   Holo-
cene –  Central Italy

1.  Introduction

Recent works summarising data on the
geometry and the kinematics of the active faults
show that the Central Apennines are affected by
two parallel active fault sets characterised by
predominantly normal movements (Barchi et al.,

2000; Galadini and Galli, 2000). The identifica-
tion of the active faults mainly followed geomor-
phologic criteria and paleoseismological data are
available for few faults only (i.e. the Campo
Imperatore Fault, Giraudi and Frezzotti, 1995;
the Aremogna-Cinquemiglia Fault, D’Addezio
et al., 2001; the Ovindoli-Pezza Fault, Pantosti
et al., 1996; the Fucino Fault, Galadini and
Galli, 1999).

A comparison between the active faulting
framework and the distribution of the seismicity,
as derived from the available historical seismic
catalogues (e.g., Working Group CPTI, 1999;
reporting earthquakes since 217 B.C.), indicates
that earthquakes with M 6.5 can be related to the
westernmost fault set. Paleoseismological data on
the Ovindoli-Pezza Fault (which is part of this

815

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

Mailing address: Dr. Fabrizio Galadini, Istituto di
Geologia Ambientale e Geoingegneria, Area della Ricerca
di Roma  «Tor Vergata», Via del Fosso del Cavaliere 100,
00133 Roma, Italy; e-mail: f.galadini@igag.cnr.it

Paleoseismology of silent faults 
in the Central Apennines (Italy): 

the Mt. Vettore and Laga Mts. faults

Fabrizio Galadini (1) and Paolo Galli (2)
(1) Istituto di Geologia Ambientale e Geoingegneria, CNR, Roma, Italy

(2) Servizio Sismico Nazionale, DPC, Roma, Italy

Abstract
Paleoseismological analyses have been performed in the Central Apennines along faults showing geomorpholo-
gical evidence of Late Quaternary activity and characterised by the absence of historical seismicity. Three 
trenches were made along the Mt. Vettore Fault, across a scarp on a Late Pleistocene-Holocene alluvial fan. The
youngest displacement event (E1) occurred after 4155-3965 years BP and before the 6th-7th century A.D., a pre-
vious event (E2) occurred between 5940-5890/5795-5780 years BP and 4155-3965 years BP, while the oldest
event (E3) occurred between 18.000-12.000 years BP and 5940-5890/5795-5780 years BP. One trench was exca-
vated across the Laga Mts. Fault which gave evidence for two displacement events after 8320-8150 years BP.
The minimum vertical slip rate estimated through the paleoseismological analysis of the Mt. Vettore Fault is
0.11-0.36 mm/yr, while the minimum slip rate along the Laga Mts. Fault is 0.12 mm/yr. The paleoseismologi-
cally inferred recurrence interval is not longer than 4690 years for the Mt. Vettore Fault and not longer than 7570
years for the Laga Mts. Fault, while the minimum elapsed times since the last activation are 1300 and 800 years
for the two faults, respectively. The evaluation of the former elapsed time was based on paleoseismological data,
while the estimation of the latter was based on the absence of historical earthquakes which may have been cau-
sed by the Laga Mts. Fault and on the completeness of the historical catalogues for the large magnitude events
in the last eight centuries. Based on the length of the fault at the surface, earthquakes with M 6.5 and 6.6 may
be expected from the activation of the Mt. Vettore and Laga Mts. faults, respectively.



fault set) suggest that also this fault activated dur-
ing the historical period (the youngest event has
been radiocarbon dated at the Middle Ages;
Pantosti et al., 1996). On the other hand, the active
faults of the eastern set show geomorphic evidence
of past activation related to strong earthquakes, but
no significant historical earthquakes may be relat-
ed to them (Galadini and Galli, 2000). For this rea-
son we usually define these faults as «silent».

The silent state of the eastern faults suggest-
ed to adopt a paleoseismological approach to
investigate two faults of this set which display
clear evidence of recent movements, i.e. the Mt.
Vettore and the Laga Mts. faults. Investigations
through the excavation of trenches were made
during 1998 and 1999. 

The following sections will be dedicated to
the recognition of the paleoseismologically in-
ferred displacement events. Tectonic data are
supported by the stratigraphic analysis related
to the sedimentary units detected in the trench-
es. Further sections will be dedicated to the def-
inition of the parameters describing the fault be-
haviour (slip rate, recurrence interval, elapsed
time since the last activation, maximum expect-
ed magnitude).

2.  Seismotectonic framework

The Apennine Chain is affected by active
normal faulting (Galadini et al., 2001 and refer-
ences therein). Moderate-to-large-magnitude
earthquakes reported in the available catalogues
(e.g., Working Group CPTI, 1999) define a seis-
mically active belt in the inner portion of the
Apennine Chain, following the Apennine axis.

Active faulting has been documented for the
Abruzzi sector of the Central Apennines (e.g.,
Barchi et al., 2000; Galadini and Galli, 2000;
Valensise and Pantosti, 2001; Roberts et al.,
2002). Some works define two main parallel sets
of prevalently normal-to-oblique faults (Barchi 
et al., 2000; Galadini and Galli, 2000; D’Addezio
et al., 2001; Valensise and Pantosti, 2001). In con-
trast, the works by Ghisetti and Vezzani (2000)
and Roberts et al. (2002), mainly dedicated to
structural aspects, define a larger number of active
normal faults. Other works at a regional scale
report active fault sets made of master faults

showing strike-slip movements and shorter faults
characterised by normal movements with a style
typical of the strike-slip tectonics (Cello et al.,
1997). All the available literature indicates, how-
ever, that the main active faults of the Central
Apennines are located along the borders of inter-
montane extensional basins, they are several tens
of kilometers long and have been responsible for
some of the strongest earthquakes which occurred
in peninsular Italy in the last few centuries (e.g.,
Barchi et al., 2000; Galadini and Galli, 2000;
Valensise and Pantosti, 2001). Taking into ac-
count that: 1) the evidence of recent tectonic
activity along some of the faults described by
Ghisetti and Vezzani (2000) and Roberts et al.
(2002) appears debatable (e.g., compare the
Avezzano-Bussi Fault in the former work and the
Salto Valley Fault in the latter with the data
reported in Galadini and Messina, 2001), and 2)
the role of strike-slip movements in the Central
Apennines seems definitely secondary (as indi-
cated by the great number of works available on
the recent faulting of the Apennines: see the liter-
ature mentioned in Galadini et al., 2001 and
Valensise and Pantosti 2001) we decided to adopt
the more widely accepted structural scheme (fig.
1) for the active tectonic regime (Barchi et al.,
2000; Galadini and Galli, 2000).

The Apennine sector reported in fig. 1 has been
affected by several earthquakes with M > 6.5.
In particular, the catalogue by Working Group
CPTI (1999, from which all the magnitude values
and the epicentral locations have been taken)
reports the 1349, 1456, 1703 (January 14), 1703
(February 2), 1706, 1915 events as the strongest
earthquakes in the investigated region. 

Galadini and Galli (2000) gathered all the
available information on active faulting and
paleoseismology of the region. Data show that
the recurrence interval for surface faulting
events in the Central Apennines is always longer
than 1000 years and usually plurimillennial. Slip
rates are lower than 1 mm/yr and the length of
the active faults ranges between 16 and more
than 30 km.

Galadini and Galli (2000) compared the data
on the active faults with the long-term seismic-
ity; this procedure gave rise to the hypothesis
that almost the entire westernmost set of normal
faults experienced activation after 1000 A.D.

816

Fabrizio Galadini and Paolo Galli



(only the Sangro Valley Fault seems to be silent)
while, in contrast, the available seismic cata-
logues do not indicate the occurrence of large
earthquakes which may be consistent with the
activation of faults of the easternmost set. The
Mt. Vettore and Laga Mts. faults are part of this
set of silent faults.

3.  Paleoseismological analysis

The main purpose of our work was the def-
inition of the chronology of the fault activity
and the characteristics of the displacements
(amount of offset, type of movement, ...). The
chronological aim conditioned the choice of the

817

Paleoseismology of silent faults in the Central Apennines (Italy): the Mt. Vettore and Laga Mts. faults

Fig.  1. Seismotectonic framework of the investigated area. The investigated faults are reported in red. Earthquake
epicenters and the highest intensity datapoints distribution (HIDD; size proportional to intensity, I > 8 MCS) were
taken from Magri and Molin (1984) for the 1456 earthquake, Boschi et al. (1995) for the 1349 and 1706 earthquakes,
Monachesi and Stucchi (1998) for the 1703 earthquake, Molin et al. (1999) for the 1915 earthquake; all the epicen-
ter locations were derived from Working Group CPTI (1999). MVEF - Mt. Vettore Fault; NFS - Norcia Fault System;
LMF - Laga Mts. Fault; UAFS - Upper Aterno Valley Fault System; AF - Assergi Fault; CIF - Campo Imperatore
Fault; CVF - Mt. Cappucciata-Mt. San Vito Fault; CFCF - Campo Felice-Colle Cerasitto Fault; MAVF - Middle
Aterno Valley Fault; OPF - Ovindoli-Pezza Fault; MMF - Mt. Morrone Fault; FF - Fucino Fault; MRPF - Mt. Rotella-
Mt. Pizzalto Fault; ACF - Aremogna-Cinquemiglia Fault; USFS - Upper Sangro Valley Fault System.



trench sites. Four trenches were excavated
across those splays affecting the younger de-
posits and landforms and samples collected for
radiocarbon dating (table I) or mineralogical
analysis. Radiocarbon dating was generally done
on bulk sediments. Dated units are related to 
colluvial (CAST-6, -9, -10, CAMP-21) or allu-
vial (CAST-5, CAMP-1, -7) deposition. Dating of
colluvial deposits generally gives, however, only
the lower chronological limit for the deposition.
Paleosols were dated in the trench excavated
across the Laga Mts. Fault (CAMP-15, -17). In
this case, sampling was done on the A horizons
of the soils. One wood fragment (CAMP-11)
was also collected from displaced deposits along
the Laga Mts. Fault.

Samples for radiocarbon dating were analy-
sed by Beta Analytic Inc. (Miami, U.S.A.). 
Two samples (CAMP-4, -11) gave evidence of

an age older than the limit of the method. Ra-
diometric counting was generally employed. 
In three cases (CAMP-1, -7, -11), due to the
lower sample size, AMS counting was used.

The conventional radiocarbon ages obtain-
ed (all standard analyses; table I) were calibrat-
ed by Beta Analytic (if conventional ages
were younger than 19.000 years BP) using the
INTCAL98 database reported in Stuiver et al.
(1998). Ages reported in the text represent the 1 
calibrated results (68% of probability). Table I,
however, also reports the 2 values, thus per-
mitting the reader to define the chronological
constraints of the displacement events based on
the 2 chronology.

Further chronological constraints were
derived from the Late Pleistocene-Holocene
stratigraphic setting of the investigated region
which is particularly well known, for the moun-

818

Fabrizio Galadini and Paolo Galli

Table  I. Radiocarbon dates of samples collected in the investigated areas and in the trenches excavated across
the Mt. Vettore and Laga Mts. faults. R - radiometric technique; BLC - bulk/low carbon material procedure;
AMS - accelerator mass spectrometry technique.

Sample Lab. code Analysis C13/C12 Measured Conventional Calibrated age Calibrated age Sample
Beta ratio age.BP age.BP 1 BP 1 BP description

CAST5 125045 R, BLC – 25.5 ‰ 5150 ± 60 5150 ± 60 5940-5890/5795-5780 6005-5745 Alluvial deposit 
(silt)

CAST6 125046 R, BLC – 25.6 ‰ 3740 ± 70 3730 ± 70 4155-3965 4275-3870 Colluvium 
(silt)

CAST9 125048 R, BLC – 25.6 ‰ 1850 ± 60 1840 ± 60 1840-1705 1885-1600 Colluvium 
(silt)

CAST10 125049 R, BLC – 25.7 ‰ 1670 ± 60 1660 ± 60 1600-1510 1705-1400 Colluvium 
(silt)

CAMP1 106260 AMS – 28.1 ‰ 10.020 ± 70 9970 ± 70 11.637-11.608/11.596- 9824-9045 Charcoal 
11.592/11.580 fragments

-11.329/11.323- within 
11.297/11.272-11.261 alluvial 

deposits
CAMP4 118167 R, BLC – 26.2 ‰ > 39.640 > 39.630 / / Colluvium 

(clayey silt)
CAMP7 106261 AMS – 27.1 ‰ 7490 ± 50 7460 ± 50 8320-8150 8345-8125 Charcoal 

fragments
within

alluvial deposits
CAMP12 128977 R, BLC – 28.7 ‰ 33.180 ± 470 33.120 ± 470 / / Lacustrine 

organic silt
CAMP15 142196 R, BLC – 24.4 ‰ 1230 ± 40 1240 ± 40 1245-1135/1110-1095 1270-1065 Buried soil 

(silty sand)
CAMP17 163998 R – 25.0 ‰ 2430 ± 120 2430 ± 120 2730-2340 2770-2290/2270-2160 Buried soil 

(silty sand)
CAMP20 120600 AMS – 25.1 ‰ 7650 ± 60 7650 ± 60 8425-8365 8500-8330 Organic silt 

(colluviated
paleosol?)

CAMP21 142197 R, BLC – 24.2 ‰ 9200 ± 230 9220 ± 230 10.685-10.190 11.150-9730 Colluvium 
(silt)



tainous area, through investigations made
with a paleoclimatological perspective since
the end of the 80 s (e.g., Frezzotti and Giraudi,
1989, 1990a,b; Frezzotti and Narcisi, 1989,
1996; Giraudi, 1994, 1995, 1998a,b, 2000;
Giraudi and Frezzotti, 1997). In these works,
the authors define the stratigraphy of continen-
tal Late Pleistocene-Holocene deposits of vari-
ous facies (glacial, fluvioglacial, alluvial,
aeolic, etc.) also reporting fundamental infor-
mation about the paleosols which have formed
for about 30.000 years BP. Detailed chronolog-
ical constraints are also given.

4.  Mt. Vettore - Castelluccio Plain

4.1. Geomorphic analysis

The Mt. Vettore normal fault is NNW-SSE to
NW-SE trending and is about 18 km long (figs.
1, 2a,b and 3a,b). It is located in a high moun-
tainous environment, since Mt. Vettore reaches
2476 m a.s.l. Only one major intermontane basin
formed along the fault, i.e. the Castelluccio Plain
(fig. 3a,b). According to Coltorti and Farabollini
(1995), deposition in the piedmont area is relat-
ed to the abundant clastic material produced by

819

Paleoseismology of silent faults in the Central Apennines (Italy): the Mt. Vettore and Laga Mts. faults

Fig.  2a,b. Panoramic views of the two areas paleoseismologically investigated. a) View of the Western Mt. Vet-
tore slope, characterised by two bedrock fault scarps (marked by the arrows); the trench sites (not visible in the
photograph) are located in the flat area at the foot of the slope (see next figures for further details). b) View of
the SW slope of the Laga Mts.; the arrows mark the scarps presumably related to the Holocene activity of the
fault (the trench site is located to the right of the photograph, see next figures for further details).

a

b



820

Fabrizio Galadini and Paolo Galli

Fig.  3a,b. a) Map of the Mt. Vettore fault area; the trenches were excavated across the minor segment located
in the Prate Pala area. b) Geomorphological map of the Castelluccio Plain: the Prate Pala scarp affects the large
Late Pleistocene-Holocene alluvial fan fed from the Valle delle Fonti area.

b

a



821

Paleoseismology of silent faults in the Central Apennines (Italy): the Mt. Vettore and Laga Mts. faults

the Mt. Vettore SW slope (fig. 3b). These authors
mapped slope deposits and landslide accumula-
tions in the most elevated areas, while they
reported alluvial deposits and landforms in the
piedmont area. We analysed a large alluvial fan
(fig. 3b) fed by the Valle delle Fonti creek
(Castelluccio fan), through the use of aerial pho-
tographs, and recognised five different deposi-
tional phases (fig. 4a). These phases are known
throughout the Central Apennines (e.g., the
Majelama alluvial fan, Frezzotti and Giraudi,
1992; the Campo Imperatore alluvial fans, Gi-
raudi, 1994). Available works related the 1st de-
positional phase to the Last Glacial Maximum
(LGM, about 22.600 years BP in the Central
Apennines, i.e. the Campo Imperatore Stade in
Giraudi and Frezzotti, 1997), while the 4th and
the 5th phases are related to the boundary Late
Pleistocene-Holocene and to about 3800-3200
years BP, respectively. No chronological con-
straints are available for the 2nd and 3rd alluvial
phases. The Castelluccio Plain is, therefore, part-
ly filled by an alluvial fan which probably for-
med between about 23.000 and 3200 years BP.

Two fault splays are easily detectable along
the Mt. Vettore western slope, since they formed
impressive limestone scarps. In particular, the
easternmost scarp is several metres high and
shows a fault plane displacing only the carbon-
ate bedrock. The westernmost fault, in contrast,
places the bedrock in contact with Late Plei-
stocene slope deposits. Based on this geomor-
phic evidence, the fault was considered ac-
tive by Calamita and Pizzi (1992) and Cello 
et al. (1997). More recently, Galadini and Galli
(2000) confirmed the recent fault activity by
reporting the evidence of displacements affect-
ing recent deposits in the piedmont area. In par-
ticular, during 1997-1998, the authors made
analyses on the Mt. Vettore Fault and investigat-
ed a scarp (Prate Pala scarp; fig. 4b,c) in the
Castelluccio alluvial fan, not reported in the pre-
vious works. The Prate Pala scarp formed into
the gravel of the alluvial fan and, in particular, it
affects the top surfaces related to the 4th and 5th
alluvial phases. We interpreted it as the result of
recent fault activity, since it is completely diver-
gent from the drainage which recently devel-
oped on the alluvial fan and small creeks appear
to be displaced across the scarp (fig. 4a).

Two topographic profiles were made to esti-
mate the height of the Prate Pala scarp (fig. 4b,c).
This height is about 3.3 m in the area of the 4th
alluvial fan, while it is about 2 m in the area of the
5th alluvial fan. The trenches made across the
scarp in the area of the 4th alluvial fan (see below)
showed that these values result from correlation of
different surfaces on both sides of the scarp. The
topographic surface of the footwall area has an ero-
sional origin and is carved into the gravels, while
the surface in the hangingwall is a top depositional
surface of colluvial units (see sections dedicated to
the trench analysis). If we consider that about 1 m
of colluvial units deposited in the hangingwall (as
derived from paleoseismological data), the vertical
offset affecting the 4th alluvial fan is 4.3 m. Since
the 4th alluvial fan can be related to the boundary
Late Pleistocene-Holocene (about 12.000 years BP),
the vertical slip rate is 0.36 mm/yr.

The 5th alluvial fan can be related to about
3800-3200 years BP. In this case, considering the
vertical offset of 2 m, the slip rate is 0.52-0.62
mm/yr.

Since the Mt. Vettore Fault Zone is made of at
least three parallel splays, the reported values de-
fine minimum slip rates for the entire structure. In
short, the minimum slip rate for the Mt. Vettore
Fault ranges between 0.36 and 0.62 mm/yr.

Three trenches were dug across the Prate Pala
scarp and due to logistic problems (the Castel-
luccio Plain is intensely cultivated) we had the
opportunity to make the excavations only in the
area of the 4th alluvial fan. The depth of the
trenches was always conditioned by the presence
of the gravels, generally showing a massive tex-
ture, which are not useful for the definition of the
faulting history, due to their homogeneity across
the fault. Moreover, the trenches showed the same
stratigraphic succession and structural setting. 
For this reason, we report a detailed description 
of trench 1 and the few differences observed in
trenches 2 and 3.

4.2. Paleoseismology

4.2.1.  Trench 1

The Castelluccio alluvial fan is entirely
made of gravels and for this reason we decided



to focus our attention on the most superficial
units. The origin of most of these units (2, 3, 4
in fig. 5a,b) is colluvial and therefore the radio-
carbon ages (1600-1510 years BP, 1840-1705
years BP, 4155-3965 years BP, 1 cal ages for
units 2, 3, 4, respectively) define lower chrono-
logical limits for the deposition. However, the
colluvial events to which units 2 and 4 are relat-
ed have not only a local importance, since these
units were found in all the trenches investigated.
They were also found in a small excavation we
made 300 m north of the trench area for strati-
graphic purposes. It is therefore probable that
these colluvial phases affected a large part of the
Castelluccio alluvial fan and that the re-deposi-
tion of former sediments/soils occurred during
periods of climatic instability. Some constraints
about the deposition of unit 2 may derive from
the climatic history of the investigated region. A
colluvium such as that of unit 2 is generally
related to the mobilization of surficial soils
which are no more in equilibrium with the envi-
ronment of formation. This lack of equilibrium

is due to the modification of the climatic condi-
tions which permitted the pedogenesis. The cli-
matic change chronologically close (and subse-
quent) to the reported radiocarbon date was
identified in the Central Apennines as having
occurred during the 6th-7th century A.D. In par-
ticular, since in this period a glacial advance-
ment occurred in the Gran Sasso Chain area (see
fig. 1 for location), defined as Calderone 3a
stade (Giraudi, in press). This glacial advance-
ment is consistent with the increase in the lacus-
trine level in the Fucino Lake (see fig. 1 for lo-
cation) during the 7th century A.D. (Giraudi,
1998a) and probably represented the effect of a
widespread climatic change towards cooler and
drier conditions, as suggested by similar chrono-
logical constraints for the advancement of
Alpine glaciers (Orombelli and Porter, 1982;
Strumia, 1997). Unit 2 may have been deposit-
ed, therefore, during the 6th-7th century A.D.

Unit 3 is lithologically similar to unit 2, as
for the fine fraction. The carbonate pebbles are,
however, finer and sparser than in the unit pre-

822

Fabrizio Galadini and Paolo Galli

Fig.  4a-c. a) Geomorphological map of the Castelluccio alluvial fan: the fan resulted from the deposition dur-
ing five different alluvial phases. b) Panoramic view of the scarp on the alluvial fan (note the slope of the road
when it crosses the scarp). c) 3D view of the scarp (vertically exaggerated), location of the trenches and scarp
height as derived from the profiles A-A and B-B reported in fig. 4a.

c

a

b



viously described. The maximum thickness is
about 50 cm. An origin similar to that of unit 2
can be defined for unit 3. The sandy fraction
gave a date of 1840-1705 years BP (1 cal age).
Due to the colluvial origin of unit 3, the same
problems defined for unit 2 about the implications
of the obtained date may be outlined for unit 3.

As for unit 4, the high content of organic mat-
ter and the monogenic origin of the deposit
(containing very few pebbles) suggest that the
colluvium originated from re-deposition of an
exposed A-horizon of a soil. For this reason the
obtained radiocarbon date cannot be far from
the age of colluviation.

Paleoseismology of silent faults in the Central Apennines (Italy): the Mt. Vettore and Laga Mts. faults

Fig.  5a,b. a) Log of the N wall of trench 1 excavated across the Prate Pala fault scarp (Mt. Vettore Fault); the
analysis of the wall defined the occurrence of three displacement events. b) Panoramic view of trench 1 (N wall).

823

a

b



Finally, the sedimentological characteristics
(faintly stratified silty sands) of unit 5 (radio-
carbon dated at 5940-5890/5795-5780 years BP,
1 cal age) define an alluvial origin.

Major (F1) and minor (F2 to F6) faults place
the carbonate gravel (unit 6) in contact with the
colluvial and alluvial units 4 and 5 (fig. 5a,b).
Considering the whole geometry, F3 is probably
the antithetic fault of F1. Among these two faults,
a minor shear plane (F2) displaces units 4 and 5.

Due to the reduced height of the trench, the
fault planes are exposed for a few tens of cen-
timetres, but show a high-angle dip (70°-80°).
The main component of the movement is verti-
cal, as indicated by the sinking of the gravels
(unit 6) in the central part of the trench, the
preservation of unit 5 and the thickness increase
of unit 4 in the same area. Moreover, the dip
towards west of the unit 6 layers (fig. 5a,b)
(while the alluvial fan deposition occurs towards
south), together with the pebble imbrication
related to similarly directed paleocurrents, prob-
ably results from gravel deposition controlled by
the N-S tectonically-induced depression.

The youngest displacement event (E1)
occurred after the deposition of unit 4 which 
is the uppermost unit displaced by the faults 
F1 and F2. This event occurred, therefore, af-
ter 4155-3965 years BP (1 cal age, which is
close to the deposition age of unit 4) and before
the deposition of unit 2 which seals the fault
planes, that is before the 6th-7th century A.D.
The preservation of unit 4 only in small sectors
of the footwall suggests areal erosion event
after the displacement event. This erosional
event erased the scarp-derived colluvium which
possibly formed after the displacement.

The vertical displacement of the base of unit
4 across fault F1 can be roughly estimated in
0.45 m, if an average line representing the base
of this unit in the hangingwall is projected on
the fault plane and the vertical separation with
the same line at the footwall is calculated. This
value is a minimum estimate, since the progres-
sively higher elevation of the unit 4 base
towards NE in the footwall is probably due to
the fault-related displacement.

A previous event (E2) affected units 5 and 6
before the deposition of unit 4. This is suggest-
ed by the lack of unit 5 in the footwall, between

units 6 and 4. This means that unit 5 was dis-
placed and eroded before the deposition of unit
4. Further evidence for the occurrence of event
E2 is represented by the minor fault planes F4,
F5 and F6, which affect units 5 and 6, being
sealed by unit 4. The event E2 occurred after
5940-5890/5795-5780 years BP (1 cal age,
unit 5) and before 4155-3965 years BP which,
based on the considerations about the origin of
unit 4 (see section dedicated to the stratigraphy)
may represent an age close to the deposition of
this unit. Due to the irregular depositional sur-
face and the limited exposure of unit 5, the ver-
tical offset related to E2 cannot be defined.

A previous event or phase of events (E3)
may be indicated by the faint layering of unit 6,
dipping westwards and an imbrication of the
pebbles indicating similarly directed paleocur-
rents. The deposition and therefore the attitude
of unit 6 have been conditioned by the presence
of a lowered area west of the fault F1. This low-
ered area suggests the occurrence of displace-
ment events along the fault F1 before the depo-
sition of unit 5. Therefore the fault activity
occurred before 5940-5890/5795-5780 years BP
and after the deposition of unit 6 which, based on
the geomorphological setting and the correlation
with the succession of other Central Apennine
alluvial fan (see previous section), may have
occurred about 18.000-12.000 years BP.

4.2.2.  Trench 2

The trench was excavated 40 m north of
trench 1. Unit 7 is made of gravels in abundant
sandy matrix. The texture is matrix-supported,
the pebbles are angular or sub-angular, with
long axes highly-dipping towards W. The de-
scribed attitude suggests a deposition over a
west-dipping scarp. Since these deposits can
only be detected in the fault zone and show typ-
ical colluvial characteristics, we interpret unit 7
as a colluvial wedge resulted from the retreat of
a scarp carved into the gravels of unit 6.

Numerous shear planes affect the investi-
gated section (N trench wall) and have been
responsible for the displacement of units 4, 5,
6 and 7 (fig. 6a,b). Some shear planes (F7,
F10) are sealed by unit 4, other (F6 and F11)

824

Fabrizio Galadini and Paolo Galli



are sealed by unit 2, while the shear planes F1
to F5 are sealed by unit 1.

The youngest displacement event (E1)
occurred after the deposition of unit 4 and was
detected along the fault planes F2 to F6 and the
fault plane F11. The available date for unit 4
(derived from trench 1, 4155-3965 years BP)
represents the lower chronological limit. The
upper chronological limit, similarly to trench 1,
may be defined by the 6th-7th century A.D.
(see previous section). The presence of unit 4
between fault planes F3 and F4 at depth (fig.
6a) suggests that faulting of unit 4 was also
responsible for the formation of an open fissure
between the mentioned fault planes (subse-
quently filled by the same faulted material of
unit 4). Since the bottom of unit 4 is very irreg-
ular and this unit is not present in the footwall,
the vertical offset cannot be estimated.

The interpretation of unit 7 as a colluvial
wedge due to the retreat of a former scarp de-
fines an older event (E2), as this unit was fault-

ed during E1. Since unit 4 deposited over this
colluvial wedge (see the sector between the fault
planes F1 and F2), the scarp which fed the col-
luvium formed – and the related event occurred
– before 4155-3965 years BP (approximate dep-
osition age of unit 4). This event may be the
same as that responsible for the displacement of
unit 5 in the western portion of the trench. In
this case, the occurrence of an event before the
deposition of unit 4 is suggested by the fact that
this unit seals the fault planes F7 and F10. The
lower chronological limit for E2 along F6 to F10
is defined by the age of unit 5 (5940-5890/5795-
5780 years BP). Due to the lack of correlative
deposits in the eastern and western parts of the
trench, the vertical offset cannot be defined.

Also in trench 2, a previous event (E3) may
be defined by the gentle dip of unit 6 towards
west, i.e. towards the area lowered by the fault
activity. The dip of the gravel is probably due 
to the presence of a tectonically subsiding area 
also before the deposition of the younger units

825

Paleoseismology of silent faults in the Central Apennines (Italy): the Mt. Vettore and Laga Mts. faults

Fig.  6a,b. a) Log of the N wall of trench 2 excavated across the Prate Pala fault scarp (Mt. Vettore Fault); units
are the same of fig. 5a,b; the paleoseismological analysis defined the occurrence of three displacement events.
b) Panoramic view of trench 2 (N wall).

a

b



(5 to 1). This event or phase of events has, there-
fore, the same chronological constraints defined
for trench 1, i.e. E3 occurred between 18.000-
12.000 years BP (probable age of unit 6) and 5940-
5890/5795-5780 years BP (age of unit 5).

4.2.3. Trench 3

Trench 3 was excavated between the previ-
ously described trenches. Also in this case we
investigated the N trench wall (fig. 7a,b).

The stratigraphic succession (units 4, 5 and 6)
is affected by 8 shear planes defining fault activi-
ty before the deposition of unit 2, sealing the de-
tected faults. A pervasively sheared area was
detected between fault planes F1 and F4; shear
planes were responsible for the warping of units 4
and 5 and the re-orientation of the pebbles of unit
6. We only reported the major shear planes (F1 to
F3) affecting this highly deformed area (fig. 7a).

The most recent event (E1) is indicated by
the displacement of unit 4 along fault planes F1,
F4 and F7 and by the continuous deformation
between fault planes F1 and F4, responsible for

the gentle dip towards W of the limits between
units 4, 7 and 6. The displacement occurred after
the deposition of unit 4, i.e. after 4155-3965
years BP. Also in this case, on the basis of the
discussion of trench 1 (see previous sections),
the upper chronological limit of this event is rep-
resented by the colluvial deposition (unit 2) pro-
bably related to the 6th-7th century A.D. Since
unit 4 is almost absent in the footwall, it is not
possible to precisely define the vertical offset.
An estimate of the minimum vertical offset may
be obtained by computing the vertical separation
(1.2 m) between the base of unit 4 in the hang-
ingwall and the limit unit 6/unit 2 (indicating the
occurrence of erosional activity responsible for
the erasure of unit 4) in the footwall (fig. 7a,b).
The assumption of a subhorizontal attitude of the
unit 4 depositional surface is necessary to con-
sider this estimate as a reliable minimum vertical
offset. We believe, however, that a local topogra-
phy gently dipping westwards characterised the
investigated area also before the deposition of
unit 4 (as suggested by the fact that such kind of
topography characterised the area during the
deposition of unit 6, gently dipping towards W,

Fabrizio Galadini and Paolo Galli

Fig.  7a,b. a) Log of the N wall of trench 3 excavated across the Prate Pala fault scarp (Mt. Vettore Fault); units
are the same of fig. 5a,b; the paleoseismological analysis defined the occurrence of three displacement events.
b) Panoramic view of trench 3 (N wall).

a

b

826



and by the present topography). The estimate of
the minimum vertical offset has to be taken,
therefore, with caution.

As already observed for the other trenches, a
previous event (E2) affected units 5 and 6 before
the deposition of unit 4, as suggested by the pre-
sence of fault planes (F5 and F6) sealed by the
latter unit and by the lack of unit 5 in the foot-
wall (east of F1), between units 4 and 6 (indicat-
ing erosion of unit 5 after its displacement and
before the deposition of unit 4). The displace-
ment occurred, therefore, after 5940-5890/5795-
5780 years BP (age of unit 5) and before 4155-
3965 years BP (approximate depositional age of
unit 4). Since unit 5 is scarcely exposed in the
hangingwall and is absent in the footwall, it is
not possible to give an estimation of the vertical
offset of this unit. The presence of unit 5
between the fault planes F4 and F5 suggests that
during E2 a fissure opened and was filled by the
sediments of unit 5.

As in the case of the previously described
trenches, older displacement events (E3) are sug-
gested by the gentle western dip of unit 6, indi-
cating a deposition conditioned by the tectoni-
cally subsiding area bounded by the faults F1 to
F6. The chronological constraints are the same as
those defined for the previously described trench-
es, i.e. the lower chronological limit is 18.000-
12.000 years BP, while the upper limit is 5940-
5890/5795-5780 years BP.

4.3. Summary of the displacement events

The three trenches excavated across the fault
scarp in the Castelluccio alluvial fan showed the
same displacement succession, with at least two
events occurred during the Holocene.

The youngest event (E1) was chronologi-
cally constrained between 4155-3965 years BP
and the 6th-7th century A.D.

An older event (E2) occurred between 5940-
5890/5795-5780 years BP and 4155-3965 years BP.

While E1 and E2, easily detectable in all the
investigated trenches, were interpreted as related to
individual displacement events, E3 is probably
related to a number of events which occurred be-
tween 18.000-12.000 years BP and 5940-5890/
5795-5780 years BP.

5.  Laga Mts. - Campotosto Basin

5.1. Geomorphic analysis

The NW-SE-trending Laga Mts. normal
fault is 30 km long and bounds two intermon-
tane basins: the Amatrice and Campotosto
basins, located along the northern and south-
ern portions of the fault, respectively (fig. 8).
This fault was already considered active by

Paleoseismology of silent faults in the Central Apennines (Italy): the Mt. Vettore and Laga Mts. faults

Fig. 8. Map of the Laga Mts. Fault. Clear evidence of
Late Pleistocene-Holocene activity can be detect-
ed along most of the fault, apart from the north-
ern portion (dashed) which was considered not
active by Galadini and Messina (2001).

827



828

Fabrizio Galadini and Paolo Galli

Fig.  9a-e. a) Geomorphological map of the Campotosto area; the trench was excavated at site 3; b,c,d) topo-
graphic profiles across the Laga Mts. Fault made at sites 1, 2 and 3, respectively; e) panoramic view of the trench
site.

c

d

e

a

b



829

Paleoseismology of silent faults in the Central Apennines (Italy): the Mt. Vettore and Laga Mts. faults

Calamita and Pizzi (1994), Cello et al. (1997),
Galadini and Galli (2000). More recent studies
showed that Late Pleistocene-Holocene ac-
tivity can only be related to the southern por-
tion of the fault (Galadini and Messina 2001).
These authors reported evidence of recent activ-
ity along a segment about 20 km long.

Lacustrine and alluvial deposits not older
than the Late Pleistocene were found in the
Campotosto Basin (fig. 9a-e), directly overlying
the Miocene flysch. Deposits of an alluvial ter-
race (charcoal fragments within sand levels, sam-
pled at two different sites, fig. 9a-e) gave radio-
carbon ages of 11.637 - 11.608/11.596 - 11.592/
11.580 - 11.329/11.323 - 11.297/11.272 - 11.261
years BP (1 ) and 8320-8150 years BP (1 ).

In the area of the Campotosto Basin, the
fault is made of three parallel splays affecting
the Laga Mts. SW slope at different height (see
fig. 9a for the central part of the fault). The
western splay is the most interesting for the
analysis of the recent faulting, since evidence
of displacements of Late Pleistocene-Holocene
deposits and landforms was found (Galadini
and Galli, 2000). Evidence of recent activity is
represented by fault scarps on the arenaceous
bedrock and deposits related to terraces which
formed along the incisions perpendicular to the
slope (fig. 9a). Erosional flat landsurfaces in
the piedmont area were also displaced by the
westernmost splays of the fault zone (fig. 9a).
Some scarps can be detected on Holocene ter-
races.

Complete information on the vertical offset
was derived from the displacement of a terrace
formed in a valley perpendicular to the Laga Mts.
slope (site 1 of fig. 9a). This terrace is affected by
all the main splays which form the fault zone.
The topographic profile made along this terrace
(fig. 9b) shows a total vertical offset of 21 m
(Galadini and Galli, 2000). The displaced terrace
is younger than a large erosional terrace carved
into a lacustrine succession radiocarbon dated at
33.120 ± 470 years BP (sampling site indicated in
fig. 9a) and older than alluvial deposits radiocar-
bon dated at 11.637 - 11.608/11.596 - 11.592/-
11.580 - 11.329/11 323-11.297/11.272 - 11.261
years BP (1 ). Based on the regional data about
the chronology of the deposition in the piedmont
areas of the Central Apennines (e.g., Dramis,

1983; Blumetti et al., 1993; Giraudi, 1996), a
probable age of 20 000-30 000 years BP can be
hypothesised for the displaced terrace. This led
Galadini and Galli (2000) to estimate a vertical
slip rate of 0.7-0.9 mm/yr. 

A terrace formed over alluvial sandy de-
posits radiocarbon dated at 8320-8150 years
BP (1 .; Galadini and Galli, 2000) is affected
by a fault scarp at site 2 (fig. 9a). An aban-
doned creek carved into this terrace (and the-
refore more recent than the reported date) was
also displaced, as suggested by the presence
of a fault scarp. The topographic profile made
across the scarp (fig. 9c) defined a vertical
offset of about 3 m (Galadini and Galli;
2000). Another topographic profile (fig. 9d)
was made on the top of the displaced terrace,
in the area chosen for trenching (site 3 in fig.
9a). This topographic profile defined a verti-
cal displacement of 3 m occurred after 8320-
8150 years BP (1 .). This represents, howev-
er, a minimum offset since the trench (see
below) uncovered about 1 m of colluvial de-
posits in the hangingwall. This means that the
vertical separation between the two correla-
tive surfaces (top of the debris flow unit 11 in
the paleoseismological section of fig. 10a,b,
see next section) across the fault zone may be
of about 4 m. Considering that the footwall
area experienced continuous erosion, this rep-
resents a minimum value for the vertical off-
set which defines a minimum vertical slip rate
of 0.48-0.49 mm/yr. This slip rate is slightly
higher than that (0.3-0.36 mm/yr) defined by
Galadini and Galli (2000) who did not consid-
er the data subsequently derived from the
trench.

The mentioned displaced terrace (site 3 of
fig. 9a) was incised by the presently active 
torrent fed by the Laga Mts. after 8320-8150
years BP (age of the terrace alluvial sands). The
trench site was located on the terrace remnant
of the left valley flank (fig. 9e).

5.2. Paleoseismology

The trench was 32 m long and not deeper
than 2.5 m (maximum depth reached in the fault
zone; fig. 10a,b). The presence of deposits main-



830

Fabrizio Galadini and Paolo Galli

Fig.  10a,b. a) Log of the NW wall of the trench excavated across the Laga Mts. Fault at site 3 in fig. 9d; the 
paleoseismological analysis defined the occurrence of two displacement events after 8425-8365 years BP. 
b) Panoramic view of the investigated trench wall.

a

b



ly made of sandstone boulders in sandy matrix
(lowest stratigraphic levels) limited the depth of
excavation. Fault planes within this kind of
deposits are not easily recognisable and there-
fore we limited the excavation in the central por-
tion of the trench at the top of the blocky unit.

Since the two trench walls showed the same
stratigraphic features and defined the same his-
tory of displacement, only the NW trench wall
will be described (fig. 10a,b).

Sandy units and deposits made of boulders,
cobbles and pebbles in sandy matrix were ex-
posed in the NW trench wall. Stratigraphy is
definitely more variable than in the case of the
Mt. Vettore Fault trenches. Figure 10a,b shows
alternating coarse debris flow episodes (units 6,
11 in fig. 10a), fine-sediment colluvial (2, 4, 5,
10 in fig. 10a) and alluvial (7, 9 in fig. 10a)
deposits. The origin of the colluvial units 2 and
10, i.e. the colluviums which deposited close to
the fault zone (fig. 10a,b), is not clear. Indeed
we have no data to understand if colluvial dep-
osition is related to a process of scarp retreat or
re-deposition in the piedmont area during phas-
es of climatic instability.

Two different pedogenetic levels were identi-
fied (units 3 and 8). Chronological constraints are
available for unit 3 (1245-1135/1110-1095 years
BP, 1 cal age), unit 8 (2730-2340 years BP, 1 
cal age) and unit 10 (10.685-10.190 years BP and
8425-8365 years BP, 1 cal age). Since the lat-
ter two dates are related to a sediment of colluvial
origin, they define only a lower chronological
limit for the deposition of unit 10.

Part of the stratigraphic succession exposed
in the NW trench wall (units 10, 11a and 11b) is
affected by five fault planes (F1 to F5 in fig.
10a). Faults F1 and F5 bound a small depression
filled with the colluvial unit 10. This structure
shows a mainly normal component in the fault
movement and extension roughly parallel to the
trench direction. Fault F1 places the debris flow
deposit (unit 11b) in contact with the colluvial
unit 10. F2 only affects unit 10, while the other
fault planes place unit 11a in contact with unit
10. F5 does not seem to displace unit 10.

Two displacement events were recognized
through the analysis of this trench.

The youngest event (E1) is indicated by the
faults (F2, F3 and F4) affecting unit 10. Since unit

10 has a colluvial origin, its deposition occurred
after the youngest radiocarbon date obtained for
this unit (8425-8365 years BP, 1 .). E1 occurred,
therefore, after this date. The upper chronological
limit cannot be reliably defined, since F2, F3 and
F4 are only sealed by the present soil. The lack of
correlative deposits across the fault zone does not
permit to define the vertical offset.

A previous event (E2) was responsible for the
displacement of units 11a and 11b. In particular,
it formed the depression between F1 and F5 filled
by the colluvial unit 10. The formation of this
depression is, therefore, preceding the deposition
of unit 10. The chronology of E2 cannot be, how-
ever, precisely defined, since the deposition age
of unit 10 is poorly constrained (generically after
8425-8365 years BP, 1 .). Therefore, if unit 10 is
the product of colluvial deposition from the scarp
formed during E2, this event may have occurred
at about 8425-8365 years BP (youngest age of
the presumed colluvial wedge). If unit 10 result-
ed from deposition during a period of climatic
instability, i.e. the deposition was not conditioned
by E2, the age of this displacement event cannot
be defined.

In the previous section, however, we dis-
cussed a vertical offset of about 4 m of the ter-
race dated at 8320-8150 years BP (1 .). Since it
is improbable that such a large offset is due to
one displacement only (see sections dedicated
to the fault behaviour), it may indicate that both
E1 and E2 occurred after 8320-8150 years BP.

The analysis of the trench wall reported in
fig. 10a defined a minimum value for the cumu-
lated vertical offset from the stratigraphic data.
If the base of unit 10 (exposed in the hanging-
wall, fig. 10a) had an almost regular attitude,
the vertical separation between the top of unit
11b in the footwall (where unit 10 was probably
present before an erosional episode erased it)
and the projection of the unit 10 base from the
area SW of fault F5 on fault F1 gives a mini-
mum vertical offset of 1 m.

6.  Fault behaviour

Paleoseismological data corroborate the
previous hypothesis of repeated Holocene acti-
vation of the Mt. Vettore and Laga Mts. faults

831

Paleoseismology of silent faults in the Central Apennines (Italy): the Mt. Vettore and Laga Mts. faults



(Galadini and Galli, 2000 and references there-
in) mainly based on geomorphologic investiga-
tions.

The implications of the available data, in
terms of slip rates, elapsed time since the last
event, recurrence intervals and expected magni-
tude, will be discussed in the following sec-
tions.

6.1. Slip rates

The paleoseismological trenches were exca-
vated across single splays of complex fault
zones. For this reason, the data obtained on the
vertical offsets from the trench analysis could
only provide information on the minimum dis-
placements which may be related to the entire
structures. As for the Mt. Vettore Fault, we con-
sider the Prate Pala scarp (across which the
investigated trenches have been made) as the
surficial expression of the westernmost splay
within the fault zone. Therefore, we estimated a
minimum slip rate. The topography of the Prate
Pala scarp gave evidence for a minimum verti-
cal slip rate ranging between 0.36 and 0.62
mm/yr (see section dedicated to the geomorphic
analysis). A slip rate can also be obtained from
the displacement estimated through the trench
analysis. A minimum vertical offset of 0.45 m
affects the base of unit 4 of trench 1 (fig. 5a,b).
Based on the age of the displacement (younger
than 4155-3965 years BP and older than the
6th-7th century A.D.), a minimum vertical slip
rate of 0.11-0.36 mm/yr can be defined.

The trench made across the westernmost
segment of the Laga Mts. Fault showed a mini-
mum vertical offset of 1 m in the past 8425
years. This offset gives a minimum vertical slip
rate of 0.12 mm/yr. In this case, however, more
reliable information can be derived from the
topographic profiles described in the section
dedicated to the geomorphic analysis of the
Laga Mts. Fault (Fig. 9a-e). By considering
these topographic data, Galadini and Galli
(2000) obtained a vertical slip rate of 0.7-0.9
mm/yr. Since this rate was obtained through the
evaluation of the surface displacement across
the entire fault zone, it can be considered a
more realistic estimate of the fault behaviour.

6.2. Elapsed time since the last activation

The paleoseismological analysis did not
define precise upper chronological limits for
the displacements observed across the Laga
Mts. Fault. Faulting can be observed through-
out the entire stratigraphic succession below the
present soil. The latter is, however, a very thin
layer of humic material developed over a collu-
vial deposit. Radiocarbon dating of this layer is
meaningless, since the obtained date would
derive from the mixture of organic matter orig-
inated from the colluviated parent material and
from the present humic matter. It is clear, there-
fore, that only the historical seismological
information can cast light on the most recent
activation of the Laga Mts. faults. Available-
seismic catalogues (Boschi et al., 1995, 1997,
2000; Camassi and Stucchi, 1997; Working
Group CPTI, 1999) give reliable information
on the occurrence of large magnitude earth-
quakes since the first centuries of the 2nd mil-
lennium A.D. Historical data suggest that no
earthquakes of M > 6 affected the Central
Apennines which may be related to the activa-
tion of the Laga Mts. Fault (Castelli et al.,
2002). For this reason, we define in this paper
a sort of «conventional» minimum elapsed
time (eight centuries) derived from: 1) the
lack of earthquakes in the seismic catalogues
which may be related to the mentioned faults,
and 2) the hypotheses about the completeness
of the historical information for the largest
magnitude events reported in Stucchi and
Albini (2000), indicating a low probability of
lost historical information for destructive
earthquakes in the period 1200 A.D.-present.

The investigated splay of the Mt. Vettore
Fault is sealed by a colluvial unit (2 in fig.
5a,b). The age of 1600-1510 years BP gives
little information on the deposition age of this
unit which, due to the colluvial origin, may
have occurred many centuries after the report-
ed date. As mentioned in the section dedicat-
ed to the stratigraphy of trench 1, the presence
of this colluvial unit over a wide area of the
alluvial fan suggests that colluviation was not
a depositional phase of a mere local impor-
tance. Significant colluviation following the
reported date can probably be related to the

832

Fabrizio Galadini and Paolo Galli



climatic change which occurred during the
6th-7th century A.D. This means that a paleo-
seismologically inferred minimum elapsed
time of 1300-1500 years can be defined.

6.3. Recurrence intervals

Radiocarbon dates permit hypotheses
about the time span between the defined dis-
placement events. However, available chrono-
logical constraints do not define very narrow
time intervals of event occurrence.

First of all, in the case of the Mt. Vettore
Fault the event E3 probably represents more
than one episode of surface faulting. As for E2
and E1, we have no data to hypothesise that
the two events are consecutive. Moreover, the
upper chronological limit of E2 coincides with
the lower chronological limit of E1 (4155-
3965 years BP); therefore, the minimum time
span between these two events would be zero.
The maximum time span can be evaluated by
first defining the uppermost chronological
limit of E1. Based on the discussion in the
previous section, this limit may be the 6th-7th
century A.D. This chronology should be com-
pared with the lower chronological limit of E2
(5940 years BP). Therefore, the maximum
time span between E2 and E1 is 4690-4490
years, representing the maximum recurrence
interval for surface faulting events along the
Mt. Vettore Fault.

The recurrence interval of the Laga Mts.
Fault is even less defined than that of the Mt.
Vettore Fault, since we only have evidence 
for two events, both after 8320-8150 years BP 
(1 .). These events are probably consecutive
(i.e. no events are lacking in the investigated
trench between E2 and E1) since unit 10 is a
colluvium deposited in a wide open fissure
formed during E2, while E1 was responsible
for the displacement of the same colluvial
unit.

As reported in the previous section, the
upper chronological limit for E1 is 1200 A.D.
The possibility that E1 occurred on 1200 A.D.
and E2 occurred at 8320-8150 years BP gives
a maximum time span between the two events
of 7570 years.

In short, assuming that the investigated
fault segments are representative of the entire
fault zone, paleoseismological data may de-
fine time intervals not longer than 4690 years
and not longer than 7570 years for the Mt.
Vettore and Laga Mts. faults, respectively. 

6.4. Expected magnitude

Hypotheses on the magnitude of the earth-
quakes which may originate along the investi-
gated faults can be derived from the surficial
fault length, by using the equation linking the
Surface Rupture Length (SRL) with the mo-
ment magnitude (Wells and Coppersmith,
1994). We consider, indeed, that the length of
the fault surficial expression (along which geo-
morphic evidence of recent activity can be
detected) is comparable to the SRL, as the men-
tioned surficial expression results from the rep-
etition of earthquakes which caused surface
faulting.

Starting from this assumption we mapped
the studied faults through the observation of
aerial photographs and subsequent investiga-
tions in the field. Therefore, we were able to
precisely estimate the fault surficial expres-
sion which resulted from cumulated episodes
of surface faulting. The estimated length of the
fault surficial expressions for the Mt. Vettore
and Laga Mts. is 18 and 20 km, respectively.
Based on the equations linking the rupture
length with the magnitude (Wells and Cop-
persmith, 1994), the expected magnitude for the
mentioned faults is 6.5 and 6.6, respectively.

7.  Conclusions

Previous works on the Central Apennine
active tectonics showed that two parallel sets 
of NW-SE trending active normal faults affect
this portion of peninsular Italy. A comparison
between the active faulting framework and the
spatial distribution of the strong historical earth-
quakes (as derived from the available Italian cat-
alogues) plus paleoseismological data indicated
that the faults of the westernmost set activated
during historical times. In contrast, no strong

833

Paleoseismology of silent faults in the Central Apennines (Italy): the Mt. Vettore and Laga Mts. faults



earthquakes (M 6.5) occurred in the areas
where the faults of the easternmost set are locat-
ed. The lack of historical earthquakes which may
be related to this set defines a silent state for the
eastern faults which, based on considerations
about the completeness of the catalogue for the
largest magnitude events, lasted for at least eight
centuries.

Considering the historically silent behaviour,
paleoseismological analyses were performed
along two adjacent faults (Mt. Vettore and Laga
Mts. faults) of the eastern set, in order: 1) to cor-
roborate the hypotheses of recent activity previ-
ously derived from geomorphological investiga-
tions, and 2) to define quantitative parameters
describing the fault behaviour.

As for point (1), the trenches made across the
three mentioned faults showed the occurrence of
repeated Holocene displacement events, thus con-
firming previous geomorphologically inferred
hypotheses.

As for point (2), results of the paleoseismo-
logical analyses can be summarised as follows:

1)  Number of events: three events were iden-
tified along the Mt. Vettore Fault, occurring be-
tween 4155-3965 years BP and the 6th-7th cen-
tury A.D. (E1), between 5940-5890/5795-5780
years BP and 4155-3965 years BP (E2), and
between 18.000-12.000 years BP and 5940-
5890/5795-5780 years BP (E3) respectively;
two events have been identified along the Laga
Mts. Fault, both occurred after 8320-8150 years
BP.

2)  Slip rate: the minimum vertical slip rates
available for the Mt. Vettore Fault are 0.11-0.36
mm/yr (paleoseismologically inferred) and 0.36-
0.62 mm/yr (geomorphologically inferred), while
for the Laga Mts. Fault the minimum rate is
0.12 mm/yr (paleoseismologically inferred) and
the geomorphologically inferred vertical slip
rate (based on the displacement of Late Pleisto-
cene landforms) is 0.7-0.9 mm/yr.

3)  Recurrence interval: the time interval be-
tween subsequent events is not longer than
4690 and 7570 years for the Mt. Vettore and the
Laga Mts. fault, respectively.

4)  Minimum elapsed time: paleoseismologi-
cal data defined an elapsed time of 1300-1500
years since the last Mt. Vettore Fault activation;
for the Laga Mts. Fault paleoseismological data

on the elapsed time are sparser, due to the lack
of reliably datable units sealing the investigated
faults; for this reason the elapsed time was fixed
in eight centuries, on the basis of the available
historical data showing no evidence of earth-
quakes which may be related to the investigated
faults and on considerations about the complete-
ness of the seismic catalogues for the largest
magnitude earthquakes.

5)  Maximum expected magnitude: based on
the length of the fault surficial expressions, and
by means of the equations linking the surficial
rupture length with the moment magnitude, the
investigated faults may cause earthquakes with
M 6.5 (Mt. Vettore) and 6.6 (Laga Mts.).

Considering the silent behaviour of the faults
during at least the past eight centuries and the
related high level of seismic hazard which may
be associated to them, we believe that future re-
search should focus on the production of damage
scenarios related to the activation of the investi-
gated faults. Although the faults affect high
mountainous regions, villages with 5000-10.000
inhabitants are located in the hangingwall areas
and at distance not larger than 15 km from the
surficial expressions of the investigated struc-
tures.

Acknowledgements

P. Messina (CNR, Istituto di Ricerca sulla
Tettonica Recente, Roma) and R. Basili (Istituto
Nazionale di Geofisica e Vulcanologia, Roma)
participated in the analysis of the trench excavat-
ed across the Laga Mts. Fault. We are grateful to
C. Giraudi for the discussions on the chrono-
logical framework of the Late Pleistocene-Ho-
locene continental stratigraphy of the Central
Apennines. One of the two anonymous referees
suggested modifications which improved the
paper.

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