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Geophysical data along the northern Italian sector of the European Geotraverse
Tectonophysics,
167
176 (1990) 167-182
Elsevier Science Publishers
B.V., Amsterdam
- Printed
in The Netherlands
european
Geophysical data along the northern Italian sector of the European Geotraverse E. CASSANO,
L. ANELLI
and R. FICHERA
AGIP, P. 0. Box 12069, 20120 Milan (Iialy) (Received
March 251988;
revised version accepted
April 24,1989)
Abstract Cassano,
E., Anelli,
Geotraverse.
L. and Fichera,
In: R. Freeman
R., 1990. Geophysical
and St. Mueller
data
(Editors),
along
the northern
The European
Italian
Geotraverse,
sector
of the European
Part 6. Tectonophysics,
176:
167-182. Magnetic, northwards
gravimetric
and
from the Ligurian
geometry,
depth,
and nature
we attempt
a structural
anomalies,
the gravimetric
structures ophiolites,
volcanites
evolution Tertiary
reveal
Alpine
data provide
of the area. The study
by Permian
extensional
tary faults during characterized
structures, tectonics
the Mesozoic.
by large-scale
side, the panorama
bodies
Apenmne having
structural
evidence
area consists
basement
natures
slabs beneath
of the sedimentary
we depicted the central
coupled
with volcanism,
Beginning
in the Tertiary
uplifted
of localized
46”OO’ (Fig. 1). Our study consists of a series of maps and three geophysical-geological sections which all together furnish a tectonic-structural outline of the southern Alps-P0 Plain-northern Apennine system. Qualitative analysis of the data was performed with filtered maps, while the quantitative interpretation was obtained using 0 1990 Elsevier Science Publishers
sequence.
B.V.
From
By filtering and
a band
the presence
These
the southern
and
provide
crust).
system. High”
data indicate
and origins.
bodies
By integrating
geometries
involving
the Bouguer of translated to
Apetines.
seismic interpreta-
as well as the chronological zones, having
zone was affected
and dislocated
to gradual
the pre-Mesozoic
thick ophiolitic
on
these factors
of a substratum
and two erogenic
in the Triassic-Lias,
Pontremoli evidence
can be ascribed
Alps and northern
as a foreland
the area was subjected
Bouguer anomalies and the residual magnetic field were obtained for the PO Plain area. Part of these data were used for a synthesis of the area enclosed between longitudes 8”37’ and 10°07’E of Greenwich, and the N latitudes 44O 20’ and
Genoa
zone to the north and south. The central
overthrusting
by the presence
Apennine
the structural
of a rigid zone acting
which overthrust
between
(superficial
to the “Milan
runs. Magnetic
various
basement
data,
in the area
sector. Data and interpretation
relative
Introduction
0040-1951/90/$03.50
obtained
Basin-northern
anomalies
disrupted
Paleogene-Neogene
is complicated
Alps-P0
residual
geological
were
South-Alpine
down to the magnetic
and northern
and magnetic
and surface
compressive
data
of the southern
data
and tectonically
Seismic reflection tions with borehole
reflection
of the subsurface
outline
on the southern
with high susceptibility
seismic
coast to the Lombardy
by synsedimen-
sinking.
The fault zones are
basement.
On the Apennine
bodies.
graph systems checked by 2-D and 3-D computerized models (Talwani and Ewing, 1960; Talwani and Heirtzler, 1962; Talwani et al., 1964; Talwani, 1965). Borehole data and the PO Plain regional seismic sections (Pieri and Groppi, 1981) were integrated with the magnetic and gravimetric data by interactive modelling to obtain the geophysical-geological
sections.
Gravimetry The gravimetric survey, which was carried out by AGIP or by a subcontractor during hydrocarbon research operations, includes approxi-
E CASSANO
ET AL.
phase to help the qualitative analysis. The filtering operation can be done directly in the space domain by means
of a 2-D convolution
with the filter
operator,
main by means
of the product
trum (signal Fourier operator
spectrum
of the signal
or in the frequency
of the signal spec-
Transformation) (operator
do-
and the filter
Fourier
Transforma-
tion). Since the object the structures immediately
of this work is to investigate
of the sedimentary underlying
made using a Gaussian-type, a 52 km cutoff wavelength The amplitude-averaged
cover
basement,
and
a map
the was
high pass filter with (Fig. 3). radial
spectrum
of the
Bouguer anomalies and the dimensions of the studied area were taken into account when this cutoff wavelength was chosen. Therefore, the filtered map (Fig. 3) essentially represents the NNINES
components of the Bouguer anomalies with short and medium wavelengths. The Bouguer anomaly map (Fig. 2) shows a regional drop of 165 mGa1 between the Ligurian Sea (+ 15 mGa1) and the Apermine-Po Plain margin (-150 mGal), with a rise towards the pre-Alpine area where a maximum value of - 30 mGa1 is reached north of Bergamo. Certain sectors were differentiated by analyzing the anoma-
Fig. 1. Index map of the southern Alps-PO Plain-northern Apennine System area.
lies having Apennine
mately 20,000 stations equipped with highly sensitive gravimeters (0.01 mGa1) of the Western 4A, Worden 654, W. Wilde and Lacoste-Romberg type. Station densities vary from l/km* in the PO Plain to 0.5/km2 in the Apennines and O.l/km* in the Alps. The Bouguer anomaly map (fig. 2) was obtained using a density value of 2400 kg/m3 in the topngraphic and Bouguer reduction calculations. This map and a few elaborations were used to make a qualitative analysis and quantitative interpretation. The anomaly wavelength depends on the depth of the source; under certain conditions the filtered maps can be used, in a qualitative way, to identify and separate these sources from the regional context. Seismic, borehole data, and the quantitative interpretation itself are commonly used in this
shorter
wavelengths.
sector
This sector is characterized by almost-parallel isoanomalies having an average NW-SE trend (Fig. 2). The weak density contrasts between the geological formations do not cause isolated anomalies. The isoanomalies suddenly become denser at the longitude of Genoa and their trend rotates from NW-SE to E-W. This indicates that there might be an element with a NNE-SSW trend separating the two zones of the Apennine sector which appears homologous to the SestriVoltaggio Line. The anomalies with the shorter wavelengths (Fig. 3) have dispersed trends and are associated with frequent stratigraphic and tectonic contacts. PO Plain Sector This sector is characterized by a zone of minimum values (-150 mGa1) at the boundary with
GEOPHYSICAL
DATA
OF NORTHERN
8’37 1’
ITALIAN
SECTOR
OF EGT
169
’
10-07
BEG,G(O
1 ’
f
\
\+\
(
\
iL’bilO1~
-
\\L-GALSOMAGGI~RE
44’20’ -
CONTOUR
INTERVAL
50 mGal Y
CONTOUR
’
INTERVAL
5 mGsl
Fig. 2. Bouguer anomaly map of the study area.
\
1 11
170
E. CASSANO
44”20’ -
CONTOUR
INTERVAL
10 mGal \
CONTOUR
INTERVAL
2 mGal
Fig. 3. Bouguer anomaly map made using a highpass filter
ET AL.
GEOPHYSICAL
DATA
OF NORTHERN
ITALIAN
-
SECTOR
OF EG’I
CONTOUR
INTERVAL
50 nT \
CONTOUR
INTERVAL
5 nl DATUM
PLANE
= 4000
mt
a.s.1.
Fig. 4. Map of the residual magnetic field.
172
the outcropping Apenmne folds (Fig. 2). A series of short wavelength anomalies with amplitudes up to 10 mGal (Fig. 3) form an arc which goes from Cremona wards
to Casteggio
and
northwest.
These
the
gravimetric
expression
rato folds already The
area
acterized
structural “Milan
and Monfer-
(Cassano
A pseudocircular length
of about
nT, extends is connected ceptibility
which
Pavia has
a medium
of about
is attributed
is char30 mGa1
to a known called the
et al., 1986a). This high,
also depicted on the map of magnetic interpretation (Fig. 7), is confirmed by the reduced section encountered in the Battuda 1 well (Figs. 7 and 9).
Magnetometry
anomaly
which
having
and
high sus-
(Figs. 4 and 5).
SSW trend
in the Genoa
area with a NNE-
and an amplitude
of 900 nT (Figs. 4
and 5) is due both to a deep substratum susceptibility
and to the outcropping
the Voltri Group.
Anomalies
lengths are present (Fig. 6).
throughout
with high ophiolites
having
shorter
the studied
In the Milano-Voipedo-Mortara anomalies have N-S and WNW-ESE plitudes Tertiary
of 100
to Volpedo-Mortara,
with a substratum
as
has a wave-
60 km and an amplitude
from Milan
The anomaly and
high in the PO Plain basement High”
the
1981). Milan
and an amplitude
2). This anomaly
1 toare
from seismic interpreta-
by an anomaly
wavelength (Fig.
between
Volpedo
anomalies
of the Emilia
known
tion (Pieri and Groppi,
from
a 52 km cutoff wavelength which was chosen the most representative for the study area.
of
wavearea
area, these trends, am-
of about 15 nT, and are associated volcanic bodies.
with
The anomalies in the Rapallo zone, with a NW-SE trend and an amplitude of 130 nT, indicate the presence
of thick ophiolitic
bodies.
The study area was surveyed by AGIP when the Magnetic Map of Italy was being prepared. A total of 15,000 km of survey lines were used for this study, flown at altitudes of 4800 ft, 5000 ft,
In the Pontremoli, Salsomaggiore and Bergamo zones, low-amplitude anomalies (lo-30 nT) indicate low-susceptibility sources related to cristalline basement wedges (Cassano et al., 1986b). The
8500 ft, and 13300 ft with various grids measuring 2 x 7.5 km, 5 x 5 km and 1.5 X 3 km. CFS and Varian magnetometers, with 0.01 and 0.02 nT
trends of the anomalies at Pontremoli and Salsomaggiore are “Apenninic” (i.e. NW-SE) and those at Bergamo are “South-Alpine” (E-W). The negative anomaly zones (Figs. 4, 5 and 6)
sensitivities were used to make the measurements. After making the appropriate corrections and sub-
are indicative of depressed basement largest of these zones has a NE-SW extends from Genoa to Lake Iseo.
areas. trend
The and
stracting the Geomagnetic Reference Field (IGRF 1978), the recorded values were used for plotting the residual magnetic field (RMF) anomaly map. These anomalies are either caused by susceptibility contrasts within the basement or by the presence of rocks with high susceptibility in the sedimentary cover. Although various values were recorded at different flight altitudes, an “upward continuation” operation was used to calculate the
We carried out a magnetic interpretation to (a) define the depth and structural setting of the magnetic basement and (b) identify the magnetic markers located inside the sedimentary cover. The
values for the same altitude, thus obtaining an homogeneous map (Fig. 4). Since the magnetic anomalies in the studied area were quite complex, the RMF map was treated with a “reduction to the pole” operator (Fig. 5). Therefore this map can be examined in a manner which is analogous to that of the gravimetric map. AC with the gravimetry, a filtered map was also made for the magnetometry using a highpass Gaussian-type filter with
term “magnetic basement” refers to the deepest marker revealed by the interpretation. The magnetic basement is generally characterized by relatively low susceptibility contrasts (125-377 X 10e5 S.I. units), with the Milan-Pavia high (“Milan High”) showing a local susceptibility increase to 2ooO X lop5 (S.I. units). The isobaths (Fig. 7) show a culmination in the Pavia zone (5000 m below sea level), which is
Structural map of the magnetic basement
GEOPHYSICAL
DATA
OF NORTHERN
ITALIAN
-
SECTOR
OF EGT
CONTOUR
173
INTERVAL
50 n-r -
CONTOUR
INTERVAL
5nT DATUM
PLANE
= 4000 mt a.s.I.
O’Pkm
Fig. 5. Map of the residual magnetic field reduced to the pole.
174
E. CASSANO
44”20’ -
CONTOUR
INTERVAL
20 I-IT -
CONTOUR
INTERVAL
2 nT DATUM
PLANE=
4000mt
S.S.I.
Fig. 6. Highpass filter map of the residual magnetic field reduced to the pole.
ET Al.
GEOPHYSICAL
DATA
OF NORTHERN
ITALIAN
SECTOR
175
OF EGT
S. CQLOMSANO
n
4
,
,
44’20’ +
+
+
STRUCTURAL
HIGH
AXIS
-
-
-
STRUCTURAL
LOW
AXIS
-r -
MAGNETIC -
BASEMENT DEPTH CONTOUR IN km BELOW THE SEA LEVEL TUSCAN
DISCONTINUITV
FAULT OVERTHRUST
.3-
.q?y
LIGURIAN
D.
Fig. 7. Map of the magnetic basement structure.
BASEMENT UNITS
E. CASSANO
176
46”OC
MORTARA
1
44”20’ ‘4s. 3/ .d**..
DEPTH CONTOUR IN km BELOW THE SEA LEVEL ~Di~ERENliAlE~ MAGNETIC LAYERS
/...
\
\
I
,,“Ey 0 .“2p.
Fig. 8. Map of the intrasedimentary
* MAGNETIC
CLASTIC
PERMIAN
VOLCANITE
TERTIARY
,uv++-ww OPHlOLlTE
... ..
&w #x*-*x.
3 WELL 30km
magnetic
markers.
VOLCANITE
BODY
ET AL
I
0 A
SOUTH
Miocene.
Surface idealized
the south,
where strong
structural
model indicated
data show that the Apennines
towards
and subsurface
that thin basement
tilting
The Garlasco-Sartirana in the thrust detachment.
Apemtines. volcanites
opposite
(dacites)
with
polarity.
The
date from the
to the Tertiary
A basement
NORTH
is thin compared faults having
section
Alps to the northern The Mesozoic
the PO Plain area with low-angle
are present.
are present.
from the southern
sheets are involved
Alps overthrust
and regional and the southern
subsidence
volcanites
cross section magmatic-stage
PO Plain geological
sector where Permian
western
LEGEND
no. 4 (see Fig. 1 for location):
is seen in the Sartirana-Lachiarella
section
20 km
of the latter increases
susceptibility
the thickness
Early-Middle
section;
high magnetic
Fig. 9. Geophysical-geological
a
3 loo-
178
E. CASSANO
dislocated by faults and magnetic discontinuities having a NNW-SSE trend. There is a very deep depression on the eastern side of this high zone, which extends from Genoa to Lake Iseo where the basement reaches its maximum depth (over 15,000 ml. The Milan High is bordered on the north and on the south by a few magnetic horizons, which have been associated with the South-Alpine and Apennine basements respectively. Those horizons bordering the high on the north develop with an E-W trend in the Bergamo area at a depth that varies between 0 and 8OfKl m. Their structural geometry is compatible with the tectonics of the sedimentary cover. Those horizons bordering the high on the south develop with an average NW-SE trend in the Pontremoli area at a depth of 30004000 m, and in the Salsoma~ore-Ponte dell’olio area at a depth of 10,000 to 12,000 m. Faults and magnetic d&continuities with NNE-SSW and SE-SW trends involving these sectors pertain to the tectonic alignments that have developed in the region. A few of the detineated structures have been confirmed by wells drilled in the area. The Monza 1 and Battuda 1 wells have cut into a Carboniferous crystalline basement, which is analogous to the outcropping “Serie dei Laghi” basement consisting of Carboniferous schists with a Permian volcanic cover. The Pontremoli 1 well on the other hand, reached a Carboniferous basement underlying a Tuscan-type succession. Map of ~~~irnen~~
ET AL
10m5 (S.I. units). These volcanites were investigated by the Monza 1 and Battuda 1 wells. The Permian volcanites are masked locally by volcanites (mostly Tertiary) that have higher susceptibility. Tertiary volcanites (dacites) in the Mortara area (1250-2880 X 10e5 S.1. units), located at a depth of 5~0-80~ m (Mortara 1 well), cover the western sector of Milan-Pavia structural high and mask the underlying Permian volcanites detected by the Battuda 1 well. The northern Apennine area is characterized by frequent ~gh-susceptib~ity markers (1250-15,000 x lo-” S.I. units) that could be related to the ophiolites of the Ligurian Units. In the LiguriaEmiiia Apennines, these ophiolites either outcrop or are located at shallow depths (2000 m); in the Rapallo area, they are located at depths ranging between 2000 and 6000 m. The area north of the “Voltri Group” is characterized by a magnetic response which is complicated by the conspicuous presence of magnetic sedimentary levels, most of which are the result of erosion of the Ligu~an-Apen~ne ophiolite and crystalline lithotypes (Oligocenic conglomerates and sandstones of the Molare Formation). These lithotypes increase in depth in the direction of the Piedmont Tertiary Basin, deepening from 1000 to 6000 m (see Fig. 9). Other magnetic sedimentary levels were also detected inside the Miocene sequences in the area southwest of Cremona at depths ranging between 5000 and 7000 m (see also Fig. 11).
magnetic markers
The interpretation of the magnetic anomalies discloses many intrasedimentary magnetic markers (Fig. 8). A tentative determination of the nature, lithostrati~ap~c position, and age of these markers were attempted through the comparison and correlation with rocks recognized and sampled both in surface and subsurface. In some places the seismic data helped to locate their position within the stratigraphic sequence. Extensive volcanic tuffs of Permian age, outcropping in the Lakes region, develop in the milan-Pavia area at a depth of 4000-7000 m and show a low susceptibility contrast of 500-700 X
The three sections represent our depiction of the geological configuration of the area. These sections tie in most of the exploration wells drilled in the western PO Plain (Fig. 1). Seismic reflection, gravimetric, and magnetometric data, integrated with the available field and borehole geological data, occur and delineate the main structural elements that characterize the area. These are, from north to south, the south Alpine thrust, the central high (Milan High), and the northern Apennine thrust. The reliability of these sections has been checked by two-dimensional (2D) gravimetric and magnetic modelling. Since the mapped seismic,
HI&ION
311,ow
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(131mw03
ClN393-l
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w oz
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10 km
PROFlLE
_
_
MEASURED PROFILE _ COMPUTED
_
FUGHT *LTI*Yoc 1500m
NORTH
are also identified in the Apennine side based on their age of deformation.
and no volcanites are present in the area. Locally sedimentary magnetic levels occur in the Miocene sequence. Two main thrust units
section no. 6 (see Fig. 1 for location): central PO Plain geological cross section. The external Apennine unit overlies the southern Alps thrust complex.
The magnetic basement shows low susceptibility
Fig. 11. Geophysical-geological
0 .
SOUTH i I 120-j ”
F
? 2
GEOPHYSICAL
DATA
gravimetric
OF NORTHERN
and magnetic
tend in the direction modelling The
is considered units
basement
SECTOR
features
normal
South-Alpine
thrusted
ITALIAN
sufficiently
ex-
to the profiles,
2-D
thrust
is involved
consists
in
in the thrust.
This
by early
faulting.
sequences
are simply
tion. Volcanites Tertiary consist
draped
of Permian,
in Tertiary
Deeper
ten-
and Tertiary
over the lower possibly
Triassic,
Apennine
flysch
units.
occur within
high-susceptibility
and
Layers
the Tertiary bodies
sec-
thrust
elastic units, locally overlain
Ligurian
susceptibility
quence.
character.
Mesozoic
Mesozoic
age occur. The northern
allochthonous higher
The Upper
the
The central
with foreland
area was disrupted
several
carbonates;
high has a rigid behaviour sional
by with
7, 9, 10, 11). In the southern deepens
se-
any reliable
further
m under
evidence
the
involved
Apennines
differs
the Apennines
without
of being
involved
Towards
in thrust-
area (Fig. 7). The
in the internal
thrust
units
of
Pontremoli
1 well,
Fig.
7)
(see
in susceptibility
ment beneath
the
a depth
ing, except in the Salsomaggiore basement
sectors,
until it reaches
contrast
from
the base-
the PO Plain. the west,
the PO Plain
basement
re-
aches a depth of over 10,000 m. The structural relationships with the Ivrea-Verbano zone are not yet clear. Towards extends
the east, in the depression
from Lake Garda
basement
reaches
a depth
to eastern
Liguria,
that the
of 14,000 m.
under-
neath the thrusted units overlie the basement and could be tentatively identified as basement wedges or Tertiary volcanics. It is apparent from the sections that the age of the south-Alpine thrust is pre-Messinian, while the northern Apenmne thrust continued to develop until the Plio-Pleistocene.
S-arY Basement
Figs.
basement
of over 14,000
adequate.
cored by Mesozoic
181
OF EGT
behaviour and characteristics
The examined PO Plain sector is characterized by a magnetic basement which is identified - in almost every location - with the pre-Mesozoic substratum. This substratum is correlated to the “Serie dei Laghi” crystalline basement which outcrops in the northwestern southern Alpine area. Permian and Tertiary volcanic bodies have been identified, the latter located in the Mortara area (for example the dacites in the Mortara 1 well, Fig. 8). A few bodies at depth of 8000-12,000 m under the outermost Apenninic thrusts (southern part of sections nos. 4, 5, 6 in Figs. 9, 10, 11) could be interpreted as being wedges of basement or magnetic bodies relating to the Tertiary volcanics (Volpedo-Casteggio-Ponte dell’olio zone in Fig. 7). In the Battuda area (Milan High) the basement is 5000 to 6000 m deep. Towards the southern Alps, the basement deepens to over 8000 m and it is locally involved in thrusted units (i.e. Cernusco, Seregna, Malossa, Brignano zones in
Time evolution The basement comprises the lowermost part of a Triassic-Liassic carbonate sequence characterized mostly by condensed sequences with sedimentary hiatuses (Battuda area in Fig. 9). The post-Liassic Mesozoic sequence evolves into basinal lithofacies in the Jurassic-Cretaceous. In the Tertiary, the whole PO Plain area deepens gradually until it reaches a very considerable depth. Subsidence is accompanied by thick elastic deposits (Oligocene-Miocene) in the south-Alpine and Apennine
foredeeps
(Figs. 9, 10, 11). During
the Oligocene-Miocene late-evolutionary, continental-erogenic, talc-alkaline magmatism occurs at least in one particular sector of the area (Mortara zone in Fig. 8, Ottobiano zone in Fig. 9). Tectonics The central-western part of the PO Plain is an area of rigid behaviour where opposite polarity south Alpine and Apennine structures, increasingly younger towards the PO Plain foreland, face each other (Figs. 9, 10, 11). The south Alpine structures are sealed by the Messinian sediments, while the Apennine structures remain tectonically active until the Plio-Pleistocene. References Cassano, E., AnelIi, L., Fichera, R. and CappeIIi, V., 1986a. Pianura Padana. Interpretazione integrata di dati geofisici e
182
E. CASSANO
geologici.
73”
Congr.
Naz. Sot. Geol.
Ital.,
1986, Rome,
25: 27 pp. Cassano,
E., Fichera,
Aeromagnetico CNR
Gruppo
R. and Arisi
d’Italia:
Alcuni
Naz. Geofis.
Rota,
F., 1986b.
Risultati
Terra
Solida,
Rilievo
Interpretativi. Atti 5”
Conv.,
of the PO plain, namica,
G., 1981. Subsurface Italy.
Sottoprogetto
CNR
geological
Progetto
“Modello
Finalizzato
Strutturale”,
structure Geodi-
Pubbl.
414:
Talwani,
M., 1965. Computation
computer
of magnetic
trary shape. Geophysics,
anomalies
with
the help
caused
30(5): 797-817.
of a digital
by bodies of arbi-
Ewing,
attraction
trary shape.
Geophysics,
Talwani,
for the magnetic
of polygonal
Obs. Columbia Talwani, gravity
M., 1960.
Rapid
computation
of three-dimensional
M. and Heirtzler,
pression
cation
l-13.
M. and
gravitational
body
Rome, II: 939-962. Pieri, M. and Groppi,
Talwani,
25(l): J.R.,
ET AL.
of
bodies of arbi-
203-225. 1962. The mathematical
anomaly
cross-section.
ex-
over a two-dimensional Lamont.
Doherty
Geol.
Univ., Tech. Rep.. 6.
M., Worzel, calculation
J.L. and
to the Mendocino
phys. Res.. 64(l):
Landisman,
for two-dimensional 49-59.
submarine
M., 1964. Rapid bodies
fracture
with appli-
zone. J. Geo-
167
176 (1990) 167-182
Elsevier Science Publishers
B.V., Amsterdam
- Printed
in The Netherlands
european
Geophysical data along the northern Italian sector of the European Geotraverse E. CASSANO,
L. ANELLI
and R. FICHERA
AGIP, P. 0. Box 12069, 20120 Milan (Iialy) (Received
March 251988;
revised version accepted
April 24,1989)
Abstract Cassano,
E., Anelli,
Geotraverse.
L. and Fichera,
In: R. Freeman
R., 1990. Geophysical
and St. Mueller
data
(Editors),
along
the northern
The European
Italian
Geotraverse,
sector
of the European
Part 6. Tectonophysics,
176:
167-182. Magnetic, northwards
gravimetric
and
from the Ligurian
geometry,
depth,
and nature
we attempt
a structural
anomalies,
the gravimetric
structures ophiolites,
volcanites
evolution Tertiary
reveal
Alpine
data provide
of the area. The study
by Permian
extensional
tary faults during characterized
structures, tectonics
the Mesozoic.
by large-scale
side, the panorama
bodies
Apenmne having
structural
evidence
area consists
basement
natures
slabs beneath
of the sedimentary
we depicted the central
coupled
with volcanism,
Beginning
in the Tertiary
uplifted
of localized
46”OO’ (Fig. 1). Our study consists of a series of maps and three geophysical-geological sections which all together furnish a tectonic-structural outline of the southern Alps-P0 Plain-northern Apennine system. Qualitative analysis of the data was performed with filtered maps, while the quantitative interpretation was obtained using 0 1990 Elsevier Science Publishers
sequence.
B.V.
From
By filtering and
a band
the presence
These
the southern
and
provide
crust).
system. High”
data indicate
and origins.
bodies
By integrating
geometries
involving
the Bouguer of translated to
Apetines.
seismic interpreta-
as well as the chronological zones, having
zone was affected
and dislocated
to gradual
the pre-Mesozoic
thick ophiolitic
on
these factors
of a substratum
and two erogenic
in the Triassic-Lias,
Pontremoli evidence
can be ascribed
Alps and northern
as a foreland
the area was subjected
Bouguer anomalies and the residual magnetic field were obtained for the PO Plain area. Part of these data were used for a synthesis of the area enclosed between longitudes 8”37’ and 10°07’E of Greenwich, and the N latitudes 44O 20’ and
Genoa
zone to the north and south. The central
overthrusting
by the presence
Apennine
the structural
of a rigid zone acting
which overthrust
between
(superficial
to the “Milan
runs. Magnetic
various
basement
data,
in the area
sector. Data and interpretation
relative
Introduction
0040-1951/90/$03.50
obtained
Basin-northern
anomalies
disrupted
Paleogene-Neogene
is complicated
Alps-P0
residual
geological
were
South-Alpine
down to the magnetic
and northern
and magnetic
and surface
compressive
data
of the southern
data
and tectonically
Seismic reflection tions with borehole
reflection
of the subsurface
outline
on the southern
with high susceptibility
seismic
coast to the Lombardy
by synsedimen-
sinking.
The fault zones are
basement.
On the Apennine
bodies.
graph systems checked by 2-D and 3-D computerized models (Talwani and Ewing, 1960; Talwani and Heirtzler, 1962; Talwani et al., 1964; Talwani, 1965). Borehole data and the PO Plain regional seismic sections (Pieri and Groppi, 1981) were integrated with the magnetic and gravimetric data by interactive modelling to obtain the geophysical-geological
sections.
Gravimetry The gravimetric survey, which was carried out by AGIP or by a subcontractor during hydrocarbon research operations, includes approxi-
E CASSANO
ET AL.
phase to help the qualitative analysis. The filtering operation can be done directly in the space domain by means
of a 2-D convolution
with the filter
operator,
main by means
of the product
trum (signal Fourier operator
spectrum
of the signal
or in the frequency
of the signal spec-
Transformation) (operator
do-
and the filter
Fourier
Transforma-
tion). Since the object the structures immediately
of this work is to investigate
of the sedimentary underlying
made using a Gaussian-type, a 52 km cutoff wavelength The amplitude-averaged
cover
basement,
and
a map
the was
high pass filter with (Fig. 3). radial
spectrum
of the
Bouguer anomalies and the dimensions of the studied area were taken into account when this cutoff wavelength was chosen. Therefore, the filtered map (Fig. 3) essentially represents the NNINES
components of the Bouguer anomalies with short and medium wavelengths. The Bouguer anomaly map (Fig. 2) shows a regional drop of 165 mGa1 between the Ligurian Sea (+ 15 mGa1) and the Apermine-Po Plain margin (-150 mGal), with a rise towards the pre-Alpine area where a maximum value of - 30 mGa1 is reached north of Bergamo. Certain sectors were differentiated by analyzing the anoma-
Fig. 1. Index map of the southern Alps-PO Plain-northern Apennine System area.
lies having Apennine
mately 20,000 stations equipped with highly sensitive gravimeters (0.01 mGa1) of the Western 4A, Worden 654, W. Wilde and Lacoste-Romberg type. Station densities vary from l/km* in the PO Plain to 0.5/km2 in the Apennines and O.l/km* in the Alps. The Bouguer anomaly map (fig. 2) was obtained using a density value of 2400 kg/m3 in the topngraphic and Bouguer reduction calculations. This map and a few elaborations were used to make a qualitative analysis and quantitative interpretation. The anomaly wavelength depends on the depth of the source; under certain conditions the filtered maps can be used, in a qualitative way, to identify and separate these sources from the regional context. Seismic, borehole data, and the quantitative interpretation itself are commonly used in this
shorter
wavelengths.
sector
This sector is characterized by almost-parallel isoanomalies having an average NW-SE trend (Fig. 2). The weak density contrasts between the geological formations do not cause isolated anomalies. The isoanomalies suddenly become denser at the longitude of Genoa and their trend rotates from NW-SE to E-W. This indicates that there might be an element with a NNE-SSW trend separating the two zones of the Apennine sector which appears homologous to the SestriVoltaggio Line. The anomalies with the shorter wavelengths (Fig. 3) have dispersed trends and are associated with frequent stratigraphic and tectonic contacts. PO Plain Sector This sector is characterized by a zone of minimum values (-150 mGa1) at the boundary with
GEOPHYSICAL
DATA
OF NORTHERN
8’37 1’
ITALIAN
SECTOR
OF EGT
169
’
10-07
BEG,G(O
1 ’
f
\
\+\
(
\
iL’bilO1~
-
\\L-GALSOMAGGI~RE
44’20’ -
CONTOUR
INTERVAL
50 mGal Y
CONTOUR
’
INTERVAL
5 mGsl
Fig. 2. Bouguer anomaly map of the study area.
\
1 11
170
E. CASSANO
44”20’ -
CONTOUR
INTERVAL
10 mGal \
CONTOUR
INTERVAL
2 mGal
Fig. 3. Bouguer anomaly map made using a highpass filter
ET AL.
GEOPHYSICAL
DATA
OF NORTHERN
ITALIAN
-
SECTOR
OF EG’I
CONTOUR
INTERVAL
50 nT \
CONTOUR
INTERVAL
5 nl DATUM
PLANE
= 4000
mt
a.s.1.
Fig. 4. Map of the residual magnetic field.
172
the outcropping Apenmne folds (Fig. 2). A series of short wavelength anomalies with amplitudes up to 10 mGal (Fig. 3) form an arc which goes from Cremona wards
to Casteggio
and
northwest.
These
the
gravimetric
expression
rato folds already The
area
acterized
structural “Milan
and Monfer-
(Cassano
A pseudocircular length
of about
nT, extends is connected ceptibility
which
Pavia has
a medium
of about
is attributed
is char30 mGa1
to a known called the
et al., 1986a). This high,
also depicted on the map of magnetic interpretation (Fig. 7), is confirmed by the reduced section encountered in the Battuda 1 well (Figs. 7 and 9).
Magnetometry
anomaly
which
having
and
high sus-
(Figs. 4 and 5).
SSW trend
in the Genoa
area with a NNE-
and an amplitude
of 900 nT (Figs. 4
and 5) is due both to a deep substratum susceptibility
and to the outcropping
the Voltri Group.
Anomalies
lengths are present (Fig. 6).
throughout
with high ophiolites
having
shorter
the studied
In the Milano-Voipedo-Mortara anomalies have N-S and WNW-ESE plitudes Tertiary
of 100
to Volpedo-Mortara,
with a substratum
as
has a wave-
60 km and an amplitude
from Milan
The anomaly and
high in the PO Plain basement High”
the
1981). Milan
and an amplitude
2). This anomaly
1 toare
from seismic interpreta-
by an anomaly
wavelength (Fig.
between
Volpedo
anomalies
of the Emilia
known
tion (Pieri and Groppi,
from
a 52 km cutoff wavelength which was chosen the most representative for the study area.
of
wavearea
area, these trends, am-
of about 15 nT, and are associated volcanic bodies.
with
The anomalies in the Rapallo zone, with a NW-SE trend and an amplitude of 130 nT, indicate the presence
of thick ophiolitic
bodies.
The study area was surveyed by AGIP when the Magnetic Map of Italy was being prepared. A total of 15,000 km of survey lines were used for this study, flown at altitudes of 4800 ft, 5000 ft,
In the Pontremoli, Salsomaggiore and Bergamo zones, low-amplitude anomalies (lo-30 nT) indicate low-susceptibility sources related to cristalline basement wedges (Cassano et al., 1986b). The
8500 ft, and 13300 ft with various grids measuring 2 x 7.5 km, 5 x 5 km and 1.5 X 3 km. CFS and Varian magnetometers, with 0.01 and 0.02 nT
trends of the anomalies at Pontremoli and Salsomaggiore are “Apenninic” (i.e. NW-SE) and those at Bergamo are “South-Alpine” (E-W). The negative anomaly zones (Figs. 4, 5 and 6)
sensitivities were used to make the measurements. After making the appropriate corrections and sub-
are indicative of depressed basement largest of these zones has a NE-SW extends from Genoa to Lake Iseo.
areas. trend
The and
stracting the Geomagnetic Reference Field (IGRF 1978), the recorded values were used for plotting the residual magnetic field (RMF) anomaly map. These anomalies are either caused by susceptibility contrasts within the basement or by the presence of rocks with high susceptibility in the sedimentary cover. Although various values were recorded at different flight altitudes, an “upward continuation” operation was used to calculate the
We carried out a magnetic interpretation to (a) define the depth and structural setting of the magnetic basement and (b) identify the magnetic markers located inside the sedimentary cover. The
values for the same altitude, thus obtaining an homogeneous map (Fig. 4). Since the magnetic anomalies in the studied area were quite complex, the RMF map was treated with a “reduction to the pole” operator (Fig. 5). Therefore this map can be examined in a manner which is analogous to that of the gravimetric map. AC with the gravimetry, a filtered map was also made for the magnetometry using a highpass Gaussian-type filter with
term “magnetic basement” refers to the deepest marker revealed by the interpretation. The magnetic basement is generally characterized by relatively low susceptibility contrasts (125-377 X 10e5 S.I. units), with the Milan-Pavia high (“Milan High”) showing a local susceptibility increase to 2ooO X lop5 (S.I. units). The isobaths (Fig. 7) show a culmination in the Pavia zone (5000 m below sea level), which is
Structural map of the magnetic basement
GEOPHYSICAL
DATA
OF NORTHERN
ITALIAN
-
SECTOR
OF EGT
CONTOUR
173
INTERVAL
50 n-r -
CONTOUR
INTERVAL
5nT DATUM
PLANE
= 4000 mt a.s.I.
O’Pkm
Fig. 5. Map of the residual magnetic field reduced to the pole.
174
E. CASSANO
44”20’ -
CONTOUR
INTERVAL
20 I-IT -
CONTOUR
INTERVAL
2 nT DATUM
PLANE=
4000mt
S.S.I.
Fig. 6. Highpass filter map of the residual magnetic field reduced to the pole.
ET Al.
GEOPHYSICAL
DATA
OF NORTHERN
ITALIAN
SECTOR
175
OF EGT
S. CQLOMSANO
n
4
,
,
44’20’ +
+
+
STRUCTURAL
HIGH
AXIS
-
-
-
STRUCTURAL
LOW
AXIS
-r -
MAGNETIC -
BASEMENT DEPTH CONTOUR IN km BELOW THE SEA LEVEL TUSCAN
DISCONTINUITV
FAULT OVERTHRUST
.3-
.q?y
LIGURIAN
D.
Fig. 7. Map of the magnetic basement structure.
BASEMENT UNITS
E. CASSANO
176
46”OC
MORTARA
1
44”20’ ‘4s. 3/ .d**..
DEPTH CONTOUR IN km BELOW THE SEA LEVEL ~Di~ERENliAlE~ MAGNETIC LAYERS
/...
\
\
I
,,“Ey 0 .“2p.
Fig. 8. Map of the intrasedimentary
* MAGNETIC
CLASTIC
PERMIAN
VOLCANITE
TERTIARY
,uv++-ww OPHlOLlTE
... ..
&w #x*-*x.
3 WELL 30km
magnetic
markers.
VOLCANITE
BODY
ET AL
I
0 A
SOUTH
Miocene.
Surface idealized
the south,
where strong
structural
model indicated
data show that the Apennines
towards
and subsurface
that thin basement
tilting
The Garlasco-Sartirana in the thrust detachment.
Apemtines. volcanites
opposite
(dacites)
with
polarity.
The
date from the
to the Tertiary
A basement
NORTH
is thin compared faults having
section
Alps to the northern The Mesozoic
the PO Plain area with low-angle
are present.
are present.
from the southern
sheets are involved
Alps overthrust
and regional and the southern
subsidence
volcanites
cross section magmatic-stage
PO Plain geological
sector where Permian
western
LEGEND
no. 4 (see Fig. 1 for location):
is seen in the Sartirana-Lachiarella
section
20 km
of the latter increases
susceptibility
the thickness
Early-Middle
section;
high magnetic
Fig. 9. Geophysical-geological
a
3 loo-
178
E. CASSANO
dislocated by faults and magnetic discontinuities having a NNW-SSE trend. There is a very deep depression on the eastern side of this high zone, which extends from Genoa to Lake Iseo where the basement reaches its maximum depth (over 15,000 ml. The Milan High is bordered on the north and on the south by a few magnetic horizons, which have been associated with the South-Alpine and Apennine basements respectively. Those horizons bordering the high on the north develop with an E-W trend in the Bergamo area at a depth that varies between 0 and 8OfKl m. Their structural geometry is compatible with the tectonics of the sedimentary cover. Those horizons bordering the high on the south develop with an average NW-SE trend in the Pontremoli area at a depth of 30004000 m, and in the Salsoma~ore-Ponte dell’olio area at a depth of 10,000 to 12,000 m. Faults and magnetic d&continuities with NNE-SSW and SE-SW trends involving these sectors pertain to the tectonic alignments that have developed in the region. A few of the detineated structures have been confirmed by wells drilled in the area. The Monza 1 and Battuda 1 wells have cut into a Carboniferous crystalline basement, which is analogous to the outcropping “Serie dei Laghi” basement consisting of Carboniferous schists with a Permian volcanic cover. The Pontremoli 1 well on the other hand, reached a Carboniferous basement underlying a Tuscan-type succession. Map of ~~~irnen~~
ET AL
10m5 (S.I. units). These volcanites were investigated by the Monza 1 and Battuda 1 wells. The Permian volcanites are masked locally by volcanites (mostly Tertiary) that have higher susceptibility. Tertiary volcanites (dacites) in the Mortara area (1250-2880 X 10e5 S.1. units), located at a depth of 5~0-80~ m (Mortara 1 well), cover the western sector of Milan-Pavia structural high and mask the underlying Permian volcanites detected by the Battuda 1 well. The northern Apennine area is characterized by frequent ~gh-susceptib~ity markers (1250-15,000 x lo-” S.I. units) that could be related to the ophiolites of the Ligurian Units. In the LiguriaEmiiia Apennines, these ophiolites either outcrop or are located at shallow depths (2000 m); in the Rapallo area, they are located at depths ranging between 2000 and 6000 m. The area north of the “Voltri Group” is characterized by a magnetic response which is complicated by the conspicuous presence of magnetic sedimentary levels, most of which are the result of erosion of the Ligu~an-Apen~ne ophiolite and crystalline lithotypes (Oligocenic conglomerates and sandstones of the Molare Formation). These lithotypes increase in depth in the direction of the Piedmont Tertiary Basin, deepening from 1000 to 6000 m (see Fig. 9). Other magnetic sedimentary levels were also detected inside the Miocene sequences in the area southwest of Cremona at depths ranging between 5000 and 7000 m (see also Fig. 11).
magnetic markers
The interpretation of the magnetic anomalies discloses many intrasedimentary magnetic markers (Fig. 8). A tentative determination of the nature, lithostrati~ap~c position, and age of these markers were attempted through the comparison and correlation with rocks recognized and sampled both in surface and subsurface. In some places the seismic data helped to locate their position within the stratigraphic sequence. Extensive volcanic tuffs of Permian age, outcropping in the Lakes region, develop in the milan-Pavia area at a depth of 4000-7000 m and show a low susceptibility contrast of 500-700 X
The three sections represent our depiction of the geological configuration of the area. These sections tie in most of the exploration wells drilled in the western PO Plain (Fig. 1). Seismic reflection, gravimetric, and magnetometric data, integrated with the available field and borehole geological data, occur and delineate the main structural elements that characterize the area. These are, from north to south, the south Alpine thrust, the central high (Milan High), and the northern Apennine thrust. The reliability of these sections has been checked by two-dimensional (2D) gravimetric and magnetic modelling. Since the mapped seismic,
HI&ION
311,ow
3lklo1d
a3N”sv3yY
(131mw03
ClN393-l
- - -
w oz
0
10 km
PROFlLE
_
_
MEASURED PROFILE _ COMPUTED
_
FUGHT *LTI*Yoc 1500m
NORTH
are also identified in the Apennine side based on their age of deformation.
and no volcanites are present in the area. Locally sedimentary magnetic levels occur in the Miocene sequence. Two main thrust units
section no. 6 (see Fig. 1 for location): central PO Plain geological cross section. The external Apennine unit overlies the southern Alps thrust complex.
The magnetic basement shows low susceptibility
Fig. 11. Geophysical-geological
0 .
SOUTH i I 120-j ”
F
? 2
GEOPHYSICAL
DATA
gravimetric
OF NORTHERN
and magnetic
tend in the direction modelling The
is considered units
basement
SECTOR
features
normal
South-Alpine
thrusted
ITALIAN
sufficiently
ex-
to the profiles,
2-D
thrust
is involved
consists
in
in the thrust.
This
by early
faulting.
sequences
are simply
tion. Volcanites Tertiary consist
draped
of Permian,
in Tertiary
Deeper
ten-
and Tertiary
over the lower possibly
Triassic,
Apennine
flysch
units.
occur within
high-susceptibility
and
Layers
the Tertiary bodies
sec-
thrust
elastic units, locally overlain
Ligurian
susceptibility
quence.
character.
Mesozoic
Mesozoic
age occur. The northern
allochthonous higher
The Upper
the
The central
with foreland
area was disrupted
several
carbonates;
high has a rigid behaviour sional
by with
7, 9, 10, 11). In the southern deepens
se-
any reliable
further
m under
evidence
the
involved
Apennines
differs
the Apennines
without
of being
involved
Towards
in thrust-
area (Fig. 7). The
in the internal
thrust
units
of
Pontremoli
1 well,
Fig.
7)
(see
in susceptibility
ment beneath
the
a depth
ing, except in the Salsomaggiore basement
sectors,
until it reaches
contrast
from
the base-
the PO Plain. the west,
the PO Plain
basement
re-
aches a depth of over 10,000 m. The structural relationships with the Ivrea-Verbano zone are not yet clear. Towards extends
the east, in the depression
from Lake Garda
basement
reaches
a depth
to eastern
Liguria,
that the
of 14,000 m.
under-
neath the thrusted units overlie the basement and could be tentatively identified as basement wedges or Tertiary volcanics. It is apparent from the sections that the age of the south-Alpine thrust is pre-Messinian, while the northern Apenmne thrust continued to develop until the Plio-Pleistocene.
S-arY Basement
Figs.
basement
of over 14,000
adequate.
cored by Mesozoic
181
OF EGT
behaviour and characteristics
The examined PO Plain sector is characterized by a magnetic basement which is identified - in almost every location - with the pre-Mesozoic substratum. This substratum is correlated to the “Serie dei Laghi” crystalline basement which outcrops in the northwestern southern Alpine area. Permian and Tertiary volcanic bodies have been identified, the latter located in the Mortara area (for example the dacites in the Mortara 1 well, Fig. 8). A few bodies at depth of 8000-12,000 m under the outermost Apenninic thrusts (southern part of sections nos. 4, 5, 6 in Figs. 9, 10, 11) could be interpreted as being wedges of basement or magnetic bodies relating to the Tertiary volcanics (Volpedo-Casteggio-Ponte dell’olio zone in Fig. 7). In the Battuda area (Milan High) the basement is 5000 to 6000 m deep. Towards the southern Alps, the basement deepens to over 8000 m and it is locally involved in thrusted units (i.e. Cernusco, Seregna, Malossa, Brignano zones in
Time evolution The basement comprises the lowermost part of a Triassic-Liassic carbonate sequence characterized mostly by condensed sequences with sedimentary hiatuses (Battuda area in Fig. 9). The post-Liassic Mesozoic sequence evolves into basinal lithofacies in the Jurassic-Cretaceous. In the Tertiary, the whole PO Plain area deepens gradually until it reaches a very considerable depth. Subsidence is accompanied by thick elastic deposits (Oligocene-Miocene) in the south-Alpine and Apennine
foredeeps
(Figs. 9, 10, 11). During
the Oligocene-Miocene late-evolutionary, continental-erogenic, talc-alkaline magmatism occurs at least in one particular sector of the area (Mortara zone in Fig. 8, Ottobiano zone in Fig. 9). Tectonics The central-western part of the PO Plain is an area of rigid behaviour where opposite polarity south Alpine and Apennine structures, increasingly younger towards the PO Plain foreland, face each other (Figs. 9, 10, 11). The south Alpine structures are sealed by the Messinian sediments, while the Apennine structures remain tectonically active until the Plio-Pleistocene. References Cassano, E., AnelIi, L., Fichera, R. and CappeIIi, V., 1986a. Pianura Padana. Interpretazione integrata di dati geofisici e
182
E. CASSANO
geologici.
73”
Congr.
Naz. Sot. Geol.
Ital.,
1986, Rome,
25: 27 pp. Cassano,
E., Fichera,
Aeromagnetico CNR
Gruppo
R. and Arisi
d’Italia:
Alcuni
Naz. Geofis.
Rota,
F., 1986b.
Risultati
Terra
Solida,
Rilievo
Interpretativi. Atti 5”
Conv.,
of the PO plain, namica,
G., 1981. Subsurface Italy.
Sottoprogetto
CNR
geological
Progetto
“Modello
Finalizzato
Strutturale”,
structure Geodi-
Pubbl.
414:
Talwani,
M., 1965. Computation
computer
of magnetic
trary shape. Geophysics,
anomalies
with
the help
caused
30(5): 797-817.
of a digital
by bodies of arbi-
Ewing,
attraction
trary shape.
Geophysics,
Talwani,
for the magnetic
of polygonal
Obs. Columbia Talwani, gravity
M., 1960.
Rapid
computation
of three-dimensional
M. and Heirtzler,
pression
cation
l-13.
M. and
gravitational
body
Rome, II: 939-962. Pieri, M. and Groppi,
Talwani,
25(l): J.R.,
ET AL.
of
bodies of arbi-
203-225. 1962. The mathematical
anomaly
cross-section.
ex-
over a two-dimensional Lamont.
Doherty
Geol.
Univ., Tech. Rep.. 6.
M., Worzel, calculation
J.L. and
to the Mendocino
phys. Res.. 64(l):
Landisman,
for two-dimensional 49-59.
submarine
M., 1964. Rapid bodies
fracture
with appli-
zone. J. Geo-