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Active versus passive continental rifting: Evidence from the West African rift system
473
Tec~ono$zysic.s, 94 (1983) 473-481 Elsevier Science Publishers
ACTIVE
VERSUS
THE WEST
J. GODFREY
B.V., Amsterdam
PASSIVE
AFRICAN
- Printed
in The Netherlands
CONTINENTAL
RIFT
RIFTING:
EVIDENCE
FROM
evidence
from the West African
rift system.
Rifting.
Tectonophysics, 94: 473-481.
SYSTEM
FITTON
Grani Institute of Geology, University of Edinburgh (Great Britain) (Revised
version received
May 1, 1982)
ABSTRACT
Fitton,
J.G.+ 1983. Active versus passive continental
In: P. Morgan
and B.H. Baker, Processes
The West African volcanic
superimposed stages
rift system
Cameroon
line. The
perfectly
in the geological
lithosphere
stretching
South Atlantic. otherwise
history
asthenosphere-lithosphere
volcanism systems
one with respect
of the system
rotation
to the other
are postulated.
by 7“ about
Cameroon
period of clockwise
the lithosphere
coupling
were
and the Gulf
restored
allowing
and
to Recent
size and
may
a pole in Sudan.
was produced
of Guinea. the hot
rotation
by
of the
interrupted
from the asthenosphere.
the
The hot
relative to the lithosphere (3) Anticlockwise
zone
to manifest
be
Three
the early stages of the opening
the Benue trough thus became displaced
beneath
and the Tertiary
in shape
(1) The Benue trough during
a short-lived
of Africa and decoupled
beneath
similar
and
rotation itself
and
as the
line.
The Cameroon thermal
Benue trough
are remarkably
(2) At about 80 Ma (Santonian)
anticlockwise
to a new position
Cameroon
the Cretaceous
as one arm of an RRR triple junction
zone in the asthenosphere moved
comprises
two features
by rotating
rifting:
of Continental
anomaly
line is possibly
a unique
in the asthenosphere
and uplift, the Cameroon with graben
structures
example
of what a “rift
would look like. It is si~;f~cant
line has not developed
are produced
a graben
passively by lithosphere
system”
produced
that, despite
structure.
acriuefy
by a
a long history
The implication
of
is that rift
stretching.
INTRODUCTION
Continental rifting is usually accompanied by magmatism and regional uplift. The large negative Bouguer anomalies associated with modern rifts are best explained by thinning of the lithosphere and its replacement by lower density, hotter asthenosphere (e.g. Brown and Girdler, 1980). Partial melting of the upwelling asthenosphere can account for rift magmatism while the regional uplift is an isostatic response to the lower density of the upwelling material. The processes responsible for lithosphere thinning are central to the current debate on the origins of continental rifting. Is it caused by the actioe (convective?) 0040- 195 1/83/$03.oLI
0 1983 Elsevier Science Publishers
B.V.
474
upwelling
of asthenosphere
nied by passive
upwelling
volcanism
should precede
volcanism
in “passive”
and fracture
of asthenosphere
material?
rifting whereas rifting rifts (Sengor
point out, the end products and the differences
or by stretching
of the lithosphere In “active”
and, possibly,
and Burke.
accompa-
rifts uplift
and
uplift should precede
1978). However.
as these authors
of active and passive rifting are likely to be very similar
between
the two not easy to recognise
in the geological
record.
The purpose of this paper is to show that the tectonic and magmatic development of the West African rift system provides unique evidence in support of a passive origin for continental
rifts.
THE WEST AFRICAN
RIFT SYSTEM
The West African rift system as defined here comprises the Cretaceous Benue trough and the Tertiary to Recent volcanic Cameroon line (Fig. 1). The Benue trough is a linear depression filled with up to 6000 m of marine sediments whose deposition was terminated by a period of mild deformation in the Santonian Ma). Rift faulting has not been observed directly in the trough because
I
I
I
5”
IO”
15”
80 of the (c.
Km
Fig. 1. The West African
rift system.
trough
The Cameroon
is shown stippled.
The outcrop
of Cretaceous
line volcanic
sedimentary
rocks are shown in black.
rocks defining
the Benue
475
overlying
sediments
these sediments ments
though
suggests
along basement
Wright
(1981) has argued
that the folds were caused
that the style of folding by differential
vertical
in
move-
faults.
The Benue trough is often cited (e.g., Burke and Wilson, 1976) as one of the best examples of a failed arm of an RRR triple junction. In this case the other two arms gave rise to the South Atlantic
Ocean. At its northeastern
two smaller rift structures
striking
(Chad rift). The northern
end of the Chad rift is obscured
in the Chad (Wright, The
basin.
Volcanic
respectively
rocks
have
1976) but are not extensively Cameroon
line
is a chain
eastwards
been
reported
end the trough
splits into
(Yola rift) and northwards by Quaternary from
sediments
the Benue
trough
developed. of transitional
to strongly
alkaline
volcanoes
extending 1600 km from the Atlantic island of Pagalu (formerly Annobon) across the African continental margin towards the centre of the continent (Fig. 1). The earliest magmatism is represented age from 65 to 35 Ma (Cantagrel
by syenite and granite ring complexes ranging in et al., 1978). The oldest extrusive rocks have been
dated at 45 Ma on the continental sector (PI. Okeke, unpublished data) and 31 Ma on the oceanic sector (Dunlop and Fitton, 1979). The most recent volcanic activity was on Mt. Cameroon which last erupted in 1982, though morphologically recent volcanic cones can be found in virtually all parts of the line. The Cameroon line has been almost continuously active over the past 65 Ma (Grant et al., 1972; Gouhier et al., 1974; Cantagrel et al., 1978; Dunlop and Fitton, 1979; H.M. Dunlop, unpublished data). The volcanism shows no consistent migration with time.
16
c 1
’
0 Oceanic
sector
volcanic
rocks
I
40
45
50
55 Weight
Fig. 2. Alkali-silica
60
65
70
75
% SiO,
diagram for the Cameroon line volcanic rocks. The line separating Hawaiian alkaline
and tholeiitic rocks (Macdonald
and Katsura, 1964) is shown for reference.
476
The compositional alkali-silica phonolite
diagram and
nephelinite
systems (cf. Williams, activity
of oversaturated
complexes).
Basaltic
is very similar
1972, Fig. 2; Upton.
on the continental
composed 10 Ma the Biu basaltic during
range of the Cameroon
line volcanic
in Fig. 2. The association
of alkali
to that
rocks is illustrated basalt,
found
trachyte,
in many
continental
rift
1974, figs. 3 and 4). The earliest volcanic
sector of the line (65-- 10 Ma) produced salic rocks
on an rhyolite,
(e.g. Bambouto,
rocks have only been erupted
Oku
central and
in large quantity
volcanoes
the early during
ring
the last
and are generally associated with fissure eruptions (e.g., Mt. Cameroon and and NgaoundCrC Plateaux). Volcanism in the oceanic sector has been mostly with more evolved rocks (undersaturated trachytes and phonolites) erupted the waning phases of activity (Fitton and Hughes, 1977).
Continental sector volcanism Precambrian basement of about
has been accompanied by regional uplift of the 1 km but there is no evidence of rift faulting and
graben formation. Nor is there any evidence that the siting of volcanic centres is controlled by basement structure. Volcanic fissures, often marked by lines of cinder cones, are generally aligned along the Cameroon line. These fissures run SW-NE on Mt. Cameroon and Manengouba, N-S on the Biu Plateau and NW-SE on the Ngaoundere
Plateau.
Swarms of dykes oriented
SW-NE
are found in the older lavas
on the island of Principe. In places, volcanic fissures can be seen to cut across lines of weakness in the basement as on the Ngaoundere Plateau where lines of cinder cones intersect large basement fractures at angles of about 70”. The oceanic sector is likewise unaffected by the transform faults which it crosses (Sibuet and Mascle, 1978). In their compositional range and association with regional uplift, the Cameroon line volcanoes have much in common with those found in rift valleys. However, the lack of graben structures and the restriction of basaltic fissure eruption to the most recent phases of volcanism suggest that for much of its long history the Cameroon line was not an extentional feature. In this respect it contrasts sharply with the Kenya rift where fissure eruptions have formed a large proportion of the volcanic activity
from the earliest
Though rift-like
not a rift system in the accepted feature which has implications
stages in its development
(Baker
and Wohlenberg,
1971).
sense of the phrase, the Cameroon line is a for the origin of more conventional rift
systems. ORIGIN
OF THE CAMEROON
LINE
The Cameroon line and Benue trough are complementary features. The former is composed of volcanic rocks of rift valley affinities but lacks rift faulting whereas the latter is a rift valley containing relatively few volcanic rocks. An explanation for the origin of the Cameroon line may lie in its relationship with the Benue trough (Fitton, 1980). The two features are so remarkably similar in shape and size that they may be superimposed perfectly by rotating one with respect
to the other about a pole in Sudan (Fig. 3). This geometrical coincidence cannot be accidental but probably
results from a displacement
of the African lithosphere
relative to the underlying asthenosphere. Thus the “Y”-shaped hot zone in the asthenosphere which would have been situated beneath the Benue trough in the Cretaceous became displaced (relative to the lithosphere) so that it now lies beneath Cameroon and the Gulf of Guinea. Magmas originally destined for the Benue rift, therefore, reached the surface as the Cameroon line instead. The postulated sequence of events leading to the development of the Cameroon line are illustrated schematically in Fig. 4. The model presented in these diagrams implies that for the past 100 Ma the West African lithosphere has been coupled to its underlying
asthenosphere
apart from a brief period around
70 Ma ago when the two
were decoupled. Theoretical studies on mantle convection (Davies, 1977; Parmentier and Turcotte, 1978; Hager and O’Connell, 1981) show that moving hthosphere plates will impose their motion on the upper parts if not all of the asthenosphere. However, it is likely that the inertia of asthenosphere motion will prevent its responding to short-lived changes in lithosphere motion. Such a change in plate motion during the development of the Benue rift may have been responsible for the lithosphere-asthenosphere
decoupling
+ 0
proposed
1
lb
Km
in the model.
*
500 4
. r),
Fig. 3. The Cameroon
line superimposed
the latter by 7’ about
a pole at 12.2”N, 30.2”E (from Fitton,
on the Benue trough
by rotating 1980).
the former clockwise
relative to
This
decoupling
must have
occurred
l3enue rift (80 Ma) and the earliest best
explained
Fig. 4. Evolution upper
mantle
by postulating
of the West African
measuring
between
magmatism
a short-lived
rift system.
the cessation
in the Cameroon period
of activity
of clockwise
The block diagrams
represent
in the
line (65 Ma), It is rotation
segments
which
of crust and
1000 km square by 200 km deep.
interrupted the generally anticlockwise rotation implied by the South Atlantic hot-spot traces. Evidence in support of such a wobble in the motion of Africa at this time is not hard to find. The late Cretaceous was a period of rapid sea-floor 1972) and major changes were taking place all spreading (Larson and Pitman, around the African plate. The change in orientation of the South Atlantic transform faults at magnetic anomaly 34 points to a change in the relative motion between Africa and South America 79 Ma ago (Sibuet and Mascle, 1978). The separation of
479
India
from Madagascar
the Atlantic
Ocean
and Africa (Barron
north
and Harrison,
1980) and the opening
of the Bay of Biscay (Pitman
and Talwani,
of
1972) both
occurred at about this time. The most convincing evidence, however, comes from the Walvis Ridge which has been interpreted as a hot-spot trace. This ridge is off-set at anomaly
34 in the sense predicted
(Fitton, 1980). The erratic behaviour
of the African
event. There is strong evidence but involves
by this model and by roughly the required
the jostling
plate required
that plate motion
of plates
much as ice floes do (Girdler,
a particularly
large sideways
phase
in the development
formation geological
IMPLICATIONS
FOR CONTINENTAL
If this interpretation then it has implications rift provides a unique development
line.
and
This
alternately
jammed
1980). The coincidence
lurch in the motion of a major
of the Cameroon record.
by this model is not a unique
is not a smooth, continuous
which become
then released,
amount
of the African
continental
rift
coincidence
may
process
together
and
in the timing of
plate with a critical
was responsible well be unique
for the in the
RIFTING
of the evolution of the West African rift system is correct for general models of continental rifting. The West African example of a rift system interrupted in the course of its
allows
us to examine
the
effects
of the underlying
thermal
disturbance in isolation from the rifting which produced it. The Benue trough was produced as part of the much larger rift system which gave rise to the South Atlantic course governed
Ocean.
This rift system may have been initiated
by hot spots (Burke and Dewey,
1973) but most probably
through stretching of the lithosphere in the areas around spots. An inevitable consequence of this stretching would linear zones where hot asthenosphere resulting thermal disturbance would
and its evolved
and between these hot be the development of
welled up passively into the lithosphere. The extend down into the asthenosphere. At this
point a geological accident decoupled the rift system from the deeper portions of this thermal disturbance and brought it to rest beneath what is now the Cameroon line. The disturbance could then assert itself in an active role and rise into the overlying lithosphere (Fig. 4). In this way an image of the Benue trough thermal disturbance has been imprinted on the lithosphere beneath Cameroon and its magmatic effects are still being felt today. It is significant that, despite a long history of rift-valley-type magmatism and associated uplift, the Cameroon line has never developed a graben structure. There is no reason why the Cameroon line should be under regional tension as the tension which created the Benue trough would have been relieved with the opening of the South Atlantic. The character of volcanism on the Cameroon line (mostly central volcanoes) argues against a tensional regime during most of its history. The shift to basaltic fissure eruptions over the past 10 Ma is probably the result of local tension
associated
with doming
but insufficient
line may well be the only example system”.
It follows
produced
as a passive response
to cause graben
formation.
The Cameroon
of a truly active (as opposed
that rift systems
which do develop
to lithosphere
graben
to passive) structures
“rift
must
be
stretching.
ACKNOWLEDGEMENTS
Field
work in Cameroon,
research
grant
from
Nigeria
the U.K.
and the Gulf
Natural
of Guinea
Environment
carried out with the support of the General Delegation Research, Cameroon, the Geological Survey of Nigeria cial dos Services
Geologia
e Minas,
was financed
Research
Council
by a
and
was
for Scientific and Technical and the Reparticao Provin-
Sao Tome and Principe.
REFERENCES
Baker, B.H. and Wohlenberg, 538-542. Barron,
E.J. and Harrison,
Indian
Oceans.
1980. An analysis
Academic
pp. 89- 109.
of the continents.
Press, London,
R.W., 1980. Interpretation J. Geophys.
Dewey,
J.F.,
of the Kenya
of past plate
Runcorn
Plate Tectonics.
K. and
C.G.A.,
and evolution
In: P.A. Davies and SK.
Brown, C. and Girdler, Burke,
J., 1971. Structure
(Editors).
of African
J.-M., Jamond,
Tertiaire
inftrieur:
G.F.,
Geophys. Dunlop,
1973. Plume-generated
C. and Lasserre,
don&es
gravity
and its implications
triple Junctions:
Atlantic
and
Drift and
for the breakup
key indictors
in applying
plate
1977. Viscous
mantle
J. R. Astron.
H.M. and Fitton,
Sci. Am., 235: 46657.
M., 1978. Le magmatisme
geochronologiques flow under
K/Ar. moving
alkalin de la ligne du Cameroun
au
C.R. Somm. Sot. Geol. Fr.. 6: 300-303. lithosphere
plates and under
subduction
zones.
Sot., 49: 557-563. J.G., 1979. A K-Ar and Sr-isotopic
Principe,
West Africa-evidence
Mineral.
Petrol,, 71: 125-131.
Fitton,
the South of Continental
Res., 85: 6443-6455.
Burke, K. and Wilson, J.T.. 1976. Hot spots on the earth’s surface.
Davies,
motions:
Mechanisms
229:
to old rocks. J. Geol., 8 1: 4066443.
tectonics Cantagrel,
rift valley. Nature,
for mantle
J.G., 1980. The Benue trough
study of the volcanic
heterogeneity
and Cameroon
line-a
beneath migrating
the Gulf
rocks of the island of of Guinea.
Contrib.
rift system in West Africa.
Earth
Planet. Sci. Lett., 51: 132-138. Fitton,
J.G. and Hughes,
and Guinea. Girdler,
Contrib.
D.J., 1977. Petrochemistry Mineral.
R.W.. 1980. The mechanisms
from surface
phenomena.
J., Nougier,
(“Ligne Grant,
N.K..
Rex,
Larson,
D.C.
and
rocks of the island of Principe,
drift and plate tectonics:
Press, London,
Gulf
S.J.,
conditions
of Continental
a I’etude volcanologique
du Cameroun
17: 3-48.
1972. Potassium-argon
1981. A simple
some boundary Mechanisms
I - 15.
D., 1974. Contribution
rocks in northeastern
R.J.,
pp.
(Editors),
Ann. Fat. Sci. Cameroun,
Freeth,
from volcanic
B.H. and O’Connell,
Geophys.
Academic
J. and Nougier,
du Cameroun”-Adamaoua).
measurements Hager,
of continental
In: P.A. Davies and S.K. Runcorn
Drift and Plate Tectonics, Gouhier,
of the volcanic
Petrol., 64: 257-272.
Nigeria.
Contrib.
ages
and
Mineral.
model of plate dynamics
strontium
isotope
Petrol.,
35: 277-292.
and mantle
ratio
convection.
J.
Res., 86: 4843-4867.
R.L. and Pitman,
implications.
W.C. III, 1972. World-wide
Geol. Sot. Am. Bull., 83: 3645-3662.
correlation
of Mesozoic magnetic
anomalies
and its
Macdonald,
GA.
Parmentier,
E.M.
lithosphere. Pitman,
and Katsura,
T., 1964. Chemical
and Turcotte,
D.L.,
Phys. Earth Planet.
W.C. III and Talwani,
composition
of Hawaiian
1978. Two-dimensional
Inter.,
mantle
lavas. J. Petrol., 5: 82- 133.
flow beneath
a rigid
accreting
17: 281-289.
M., 1972. Sea-floor
spreading
in the North
Atlantic.
Geol. Sot. Am. Bull.,
83: 619-646. Sengor,
A.M.C.
and Burke, K., 1978. Relative
implications.
Geophys.
timing of rifting
Sibuet, J.-C. and Mascle, J., 1978. Plate kinematic J. Geophys. Upton, Williams,
1974. The alkaline
Rocks. Wiley, London, L.A.J.,
1972. The
Tectonophysics,
15: 83-96.
Wright,
on earth and its tectonic
implications
of Atlantic
equatorial
fracture
zone trends.
Res., 83: 3401-3421.
B.G.J.,
Alkaline
and volcanism
Res. Lett., 5: 419-421.
J.B., 1976. Volcanic
Kenya
province
of South-West
Greenland.
In: H. Seensen
(Editor),
The
pp. 221-238. Rift
volcanics:
rocks in Nigeria.
In: CA.
a note
on volumes
Kogbe (Editor),
and
Geology
chemical of Nigeria.
composition. Elizabethan
Publ. Co., Lagos, pp. 93-142. Wright,
J.B., 1981. Review of the origin and evolution
98-103.
of the Benue trough
in Nigeria.
Earth Evol. Sci., 2:
Tec~ono$zysic.s, 94 (1983) 473-481 Elsevier Science Publishers
ACTIVE
VERSUS
THE WEST
J. GODFREY
B.V., Amsterdam
PASSIVE
AFRICAN
- Printed
in The Netherlands
CONTINENTAL
RIFT
RIFTING:
EVIDENCE
FROM
evidence
from the West African
rift system.
Rifting.
Tectonophysics, 94: 473-481.
SYSTEM
FITTON
Grani Institute of Geology, University of Edinburgh (Great Britain) (Revised
version received
May 1, 1982)
ABSTRACT
Fitton,
J.G.+ 1983. Active versus passive continental
In: P. Morgan
and B.H. Baker, Processes
The West African volcanic
superimposed stages
rift system
Cameroon
line. The
perfectly
in the geological
lithosphere
stretching
South Atlantic. otherwise
history
asthenosphere-lithosphere
volcanism systems
one with respect
of the system
rotation
to the other
are postulated.
by 7“ about
Cameroon
period of clockwise
the lithosphere
coupling
were
and the Gulf
restored
allowing
and
to Recent
size and
may
a pole in Sudan.
was produced
of Guinea. the hot
rotation
by
of the
interrupted
from the asthenosphere.
the
The hot
relative to the lithosphere (3) Anticlockwise
zone
to manifest
be
Three
the early stages of the opening
the Benue trough thus became displaced
beneath
and the Tertiary
in shape
(1) The Benue trough during
a short-lived
of Africa and decoupled
beneath
similar
and
rotation itself
and
as the
line.
The Cameroon thermal
Benue trough
are remarkably
(2) At about 80 Ma (Santonian)
anticlockwise
to a new position
Cameroon
the Cretaceous
as one arm of an RRR triple junction
zone in the asthenosphere moved
comprises
two features
by rotating
rifting:
of Continental
anomaly
line is possibly
a unique
in the asthenosphere
and uplift, the Cameroon with graben
structures
example
of what a “rift
would look like. It is si~;f~cant
line has not developed
are produced
a graben
passively by lithosphere
system”
produced
that, despite
structure.
acriuefy
by a
a long history
The implication
of
is that rift
stretching.
INTRODUCTION
Continental rifting is usually accompanied by magmatism and regional uplift. The large negative Bouguer anomalies associated with modern rifts are best explained by thinning of the lithosphere and its replacement by lower density, hotter asthenosphere (e.g. Brown and Girdler, 1980). Partial melting of the upwelling asthenosphere can account for rift magmatism while the regional uplift is an isostatic response to the lower density of the upwelling material. The processes responsible for lithosphere thinning are central to the current debate on the origins of continental rifting. Is it caused by the actioe (convective?) 0040- 195 1/83/$03.oLI
0 1983 Elsevier Science Publishers
B.V.
474
upwelling
of asthenosphere
nied by passive
upwelling
volcanism
should precede
volcanism
in “passive”
and fracture
of asthenosphere
material?
rifting whereas rifting rifts (Sengor
point out, the end products and the differences
or by stretching
of the lithosphere In “active”
and, possibly,
and Burke.
accompa-
rifts uplift
and
uplift should precede
1978). However.
as these authors
of active and passive rifting are likely to be very similar
between
the two not easy to recognise
in the geological
record.
The purpose of this paper is to show that the tectonic and magmatic development of the West African rift system provides unique evidence in support of a passive origin for continental
rifts.
THE WEST AFRICAN
RIFT SYSTEM
The West African rift system as defined here comprises the Cretaceous Benue trough and the Tertiary to Recent volcanic Cameroon line (Fig. 1). The Benue trough is a linear depression filled with up to 6000 m of marine sediments whose deposition was terminated by a period of mild deformation in the Santonian Ma). Rift faulting has not been observed directly in the trough because
I
I
I
5”
IO”
15”
80 of the (c.
Km
Fig. 1. The West African
rift system.
trough
The Cameroon
is shown stippled.
The outcrop
of Cretaceous
line volcanic
sedimentary
rocks are shown in black.
rocks defining
the Benue
475
overlying
sediments
these sediments ments
though
suggests
along basement
Wright
(1981) has argued
that the folds were caused
that the style of folding by differential
vertical
in
move-
faults.
The Benue trough is often cited (e.g., Burke and Wilson, 1976) as one of the best examples of a failed arm of an RRR triple junction. In this case the other two arms gave rise to the South Atlantic
Ocean. At its northeastern
two smaller rift structures
striking
(Chad rift). The northern
end of the Chad rift is obscured
in the Chad (Wright, The
basin.
Volcanic
respectively
rocks
have
1976) but are not extensively Cameroon
line
is a chain
eastwards
been
reported
end the trough
splits into
(Yola rift) and northwards by Quaternary from
sediments
the Benue
trough
developed. of transitional
to strongly
alkaline
volcanoes
extending 1600 km from the Atlantic island of Pagalu (formerly Annobon) across the African continental margin towards the centre of the continent (Fig. 1). The earliest magmatism is represented age from 65 to 35 Ma (Cantagrel
by syenite and granite ring complexes ranging in et al., 1978). The oldest extrusive rocks have been
dated at 45 Ma on the continental sector (PI. Okeke, unpublished data) and 31 Ma on the oceanic sector (Dunlop and Fitton, 1979). The most recent volcanic activity was on Mt. Cameroon which last erupted in 1982, though morphologically recent volcanic cones can be found in virtually all parts of the line. The Cameroon line has been almost continuously active over the past 65 Ma (Grant et al., 1972; Gouhier et al., 1974; Cantagrel et al., 1978; Dunlop and Fitton, 1979; H.M. Dunlop, unpublished data). The volcanism shows no consistent migration with time.
16
c 1
’
0 Oceanic
sector
volcanic
rocks
I
40
45
50
55 Weight
Fig. 2. Alkali-silica
60
65
70
75
% SiO,
diagram for the Cameroon line volcanic rocks. The line separating Hawaiian alkaline
and tholeiitic rocks (Macdonald
and Katsura, 1964) is shown for reference.
476
The compositional alkali-silica phonolite
diagram and
nephelinite
systems (cf. Williams, activity
of oversaturated
complexes).
Basaltic
is very similar
1972, Fig. 2; Upton.
on the continental
composed 10 Ma the Biu basaltic during
range of the Cameroon
line volcanic
in Fig. 2. The association
of alkali
to that
rocks is illustrated basalt,
found
trachyte,
in many
continental
rift
1974, figs. 3 and 4). The earliest volcanic
sector of the line (65-- 10 Ma) produced salic rocks
on an rhyolite,
(e.g. Bambouto,
rocks have only been erupted
Oku
central and
in large quantity
volcanoes
the early during
ring
the last
and are generally associated with fissure eruptions (e.g., Mt. Cameroon and and NgaoundCrC Plateaux). Volcanism in the oceanic sector has been mostly with more evolved rocks (undersaturated trachytes and phonolites) erupted the waning phases of activity (Fitton and Hughes, 1977).
Continental sector volcanism Precambrian basement of about
has been accompanied by regional uplift of the 1 km but there is no evidence of rift faulting and
graben formation. Nor is there any evidence that the siting of volcanic centres is controlled by basement structure. Volcanic fissures, often marked by lines of cinder cones, are generally aligned along the Cameroon line. These fissures run SW-NE on Mt. Cameroon and Manengouba, N-S on the Biu Plateau and NW-SE on the Ngaoundere
Plateau.
Swarms of dykes oriented
SW-NE
are found in the older lavas
on the island of Principe. In places, volcanic fissures can be seen to cut across lines of weakness in the basement as on the Ngaoundere Plateau where lines of cinder cones intersect large basement fractures at angles of about 70”. The oceanic sector is likewise unaffected by the transform faults which it crosses (Sibuet and Mascle, 1978). In their compositional range and association with regional uplift, the Cameroon line volcanoes have much in common with those found in rift valleys. However, the lack of graben structures and the restriction of basaltic fissure eruption to the most recent phases of volcanism suggest that for much of its long history the Cameroon line was not an extentional feature. In this respect it contrasts sharply with the Kenya rift where fissure eruptions have formed a large proportion of the volcanic activity
from the earliest
Though rift-like
not a rift system in the accepted feature which has implications
stages in its development
(Baker
and Wohlenberg,
1971).
sense of the phrase, the Cameroon line is a for the origin of more conventional rift
systems. ORIGIN
OF THE CAMEROON
LINE
The Cameroon line and Benue trough are complementary features. The former is composed of volcanic rocks of rift valley affinities but lacks rift faulting whereas the latter is a rift valley containing relatively few volcanic rocks. An explanation for the origin of the Cameroon line may lie in its relationship with the Benue trough (Fitton, 1980). The two features are so remarkably similar in shape and size that they may be superimposed perfectly by rotating one with respect
to the other about a pole in Sudan (Fig. 3). This geometrical coincidence cannot be accidental but probably
results from a displacement
of the African lithosphere
relative to the underlying asthenosphere. Thus the “Y”-shaped hot zone in the asthenosphere which would have been situated beneath the Benue trough in the Cretaceous became displaced (relative to the lithosphere) so that it now lies beneath Cameroon and the Gulf of Guinea. Magmas originally destined for the Benue rift, therefore, reached the surface as the Cameroon line instead. The postulated sequence of events leading to the development of the Cameroon line are illustrated schematically in Fig. 4. The model presented in these diagrams implies that for the past 100 Ma the West African lithosphere has been coupled to its underlying
asthenosphere
apart from a brief period around
70 Ma ago when the two
were decoupled. Theoretical studies on mantle convection (Davies, 1977; Parmentier and Turcotte, 1978; Hager and O’Connell, 1981) show that moving hthosphere plates will impose their motion on the upper parts if not all of the asthenosphere. However, it is likely that the inertia of asthenosphere motion will prevent its responding to short-lived changes in lithosphere motion. Such a change in plate motion during the development of the Benue rift may have been responsible for the lithosphere-asthenosphere
decoupling
+ 0
proposed
1
lb
Km
in the model.
*
500 4
. r),
Fig. 3. The Cameroon
line superimposed
the latter by 7’ about
a pole at 12.2”N, 30.2”E (from Fitton,
on the Benue trough
by rotating 1980).
the former clockwise
relative to
This
decoupling
must have
occurred
l3enue rift (80 Ma) and the earliest best
explained
Fig. 4. Evolution upper
mantle
by postulating
of the West African
measuring
between
magmatism
a short-lived
rift system.
the cessation
in the Cameroon period
of activity
of clockwise
The block diagrams
represent
in the
line (65 Ma), It is rotation
segments
which
of crust and
1000 km square by 200 km deep.
interrupted the generally anticlockwise rotation implied by the South Atlantic hot-spot traces. Evidence in support of such a wobble in the motion of Africa at this time is not hard to find. The late Cretaceous was a period of rapid sea-floor 1972) and major changes were taking place all spreading (Larson and Pitman, around the African plate. The change in orientation of the South Atlantic transform faults at magnetic anomaly 34 points to a change in the relative motion between Africa and South America 79 Ma ago (Sibuet and Mascle, 1978). The separation of
479
India
from Madagascar
the Atlantic
Ocean
and Africa (Barron
north
and Harrison,
1980) and the opening
of the Bay of Biscay (Pitman
and Talwani,
of
1972) both
occurred at about this time. The most convincing evidence, however, comes from the Walvis Ridge which has been interpreted as a hot-spot trace. This ridge is off-set at anomaly
34 in the sense predicted
(Fitton, 1980). The erratic behaviour
of the African
event. There is strong evidence but involves
by this model and by roughly the required
the jostling
plate required
that plate motion
of plates
much as ice floes do (Girdler,
a particularly
large sideways
phase
in the development
formation geological
IMPLICATIONS
FOR CONTINENTAL
If this interpretation then it has implications rift provides a unique development
line.
and
This
alternately
jammed
1980). The coincidence
lurch in the motion of a major
of the Cameroon record.
by this model is not a unique
is not a smooth, continuous
which become
then released,
amount
of the African
continental
rift
coincidence
may
process
together
and
in the timing of
plate with a critical
was responsible well be unique
for the in the
RIFTING
of the evolution of the West African rift system is correct for general models of continental rifting. The West African example of a rift system interrupted in the course of its
allows
us to examine
the
effects
of the underlying
thermal
disturbance in isolation from the rifting which produced it. The Benue trough was produced as part of the much larger rift system which gave rise to the South Atlantic course governed
Ocean.
This rift system may have been initiated
by hot spots (Burke and Dewey,
1973) but most probably
through stretching of the lithosphere in the areas around spots. An inevitable consequence of this stretching would linear zones where hot asthenosphere resulting thermal disturbance would
and its evolved
and between these hot be the development of
welled up passively into the lithosphere. The extend down into the asthenosphere. At this
point a geological accident decoupled the rift system from the deeper portions of this thermal disturbance and brought it to rest beneath what is now the Cameroon line. The disturbance could then assert itself in an active role and rise into the overlying lithosphere (Fig. 4). In this way an image of the Benue trough thermal disturbance has been imprinted on the lithosphere beneath Cameroon and its magmatic effects are still being felt today. It is significant that, despite a long history of rift-valley-type magmatism and associated uplift, the Cameroon line has never developed a graben structure. There is no reason why the Cameroon line should be under regional tension as the tension which created the Benue trough would have been relieved with the opening of the South Atlantic. The character of volcanism on the Cameroon line (mostly central volcanoes) argues against a tensional regime during most of its history. The shift to basaltic fissure eruptions over the past 10 Ma is probably the result of local tension
associated
with doming
but insufficient
line may well be the only example system”.
It follows
produced
as a passive response
to cause graben
formation.
The Cameroon
of a truly active (as opposed
that rift systems
which do develop
to lithosphere
graben
to passive) structures
“rift
must
be
stretching.
ACKNOWLEDGEMENTS
Field
work in Cameroon,
research
grant
from
Nigeria
the U.K.
and the Gulf
Natural
of Guinea
Environment
carried out with the support of the General Delegation Research, Cameroon, the Geological Survey of Nigeria cial dos Services
Geologia
e Minas,
was financed
Research
Council
by a
and
was
for Scientific and Technical and the Reparticao Provin-
Sao Tome and Principe.
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