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Two types of rifting: dependence on the condition of extension
Tectonophysics,
85
143 (1987) 85-92
Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
Two types of rifting: dependence of extension
on the condition
V. KAZMIN Shirshov Institute of Oceanology, Academy of Science of the U.S.S.R., (Received August 8,1985;
I I 7218 Moscow (U.S.S.R.)
revised version accepted April 10,1987)
Abstract Kaxmin, V., 1987. Two types of rifting: dependence on the condition of extension. In: I.B. Ramberg, E.E. Milanovsky and G. Qvale (Editors), Continental Rifts-Principal
and Regional Characteristics. Tectonophysics,
143:85-92.
Rifting of continental lithosphere occurs in two ways: (I), through continuous extension and subsequent sinking and (2), in a series of pulses separated by quiet periods, sometimes of considerable duration. In the first case rifting is not accompanied by significant uplifts; in the second, uplifts of various sixes from 100 to 2000 km are typical. Rifting of the first type takes place when continental fragments are freely dispersed, as was the case with Pangea during its Late Triassic-Early
Jurassic break up. In the Cenozoic, rifts developed in the course of continental collision, when
relative plate motion was restricted and occurred in short pulses. Uplift is caused by accumulation of anomalous mantle at the base of the crust during the intervals between phases of extension. Geological evidence is not consistent with the idea of rifting being directly related to a local source of energy in the mantle (mantle plumes and diapirs). It is produced by regional stresses in the lithosphere which, in their turn, may have different origins. The “lithospheric inhomogeneities” observed below the present day rifts are not the cause, but a consequence of extension.
Introduction
ing is regarded as an “active” process (Gass, 1975;
As was pointed out by Talwani and Langseth (1981), the cause of continental rifting remains
Gratchev, 1977; Gass et al., 1978; Artyushkov, 1979; Ramberg, 1981; Logatchev et al., 1983 and many others). However, in this case the litho-
poorly understood. Geophysical studies indicate that large-scale lithospheric inhomogeneities exist below continental rifts. These inhomogeneities are in fact uplifts of the asthenosphere, forming large domes, much wider than individual rifts or grabens and elongated concordantly with the strike of the
sphere must be linked to the energy source for a long period to produce an appreciable effect on the surface. Consequently, rifting is correlated to “stable” intervals in plate motion (Burke and Dewey, 1973; Gass, 1975; Gass et al., 1978; Kazmin, 1980).
rift systems. Usually they are interpreted as active mantle diapirs rising from the deeper mantle. The light material of diapirs (or mantle plumes) accumulates at the base of the crust, resulting in isostatic uplift. Lateral flow of this material due to gravitational instability creates tensional stress in the crust, which finally breaks up to form grabens. According to this point of view, rifts are linked to energy sources immediately below them, and rift-
On the other hand, in many cases there is no visible indication of plume activity (volcanism, uplift etc.) and rifts appear to be “passive” fractures of the lithosphere caused by regional stresses applied to a plate or to an assemblage of plates (Kazmin, 1984 and others). The stress can be created by convective flow causing viscous friction at the bases of the lithosphere (Sorochtin, 1974), by gravity pull of the subducted plate (Bott, 1982),
0040-1951/87/$03.50
0 1987 Elsevier Science Publishers B.V.
86
by
membrane
stresses
(Oxburg
1974), or by the impact and Tapponier,
and
Turcotte,
of plate collision
(Molnar
1975). Pulses of the Earth’s expan-
to be controlled
great rift systems originated
1980). Passive rifting seems
in Europe,
by inherited
zones of weakness
in
pends
evidence
and an attempt
that the difference
on the conditions
is made to
between
in which
for the rifts de-
extension
oc-
Conditions of rifting
were epochs
in geological
history
when
we would
developed Pichakun,
and Antarctica.
In some
areas (South Africa and Antarctica), initial rifting was accompanied by extensive plateaubasalt volcanism which occurred simultaneously with subsidence. Other rifts of this epoch had practically no volcanism although extension was of the same order as in the volcanic rifts. An even more impressive example
Fig. 1. Triassic-Early
of a world-
Jurassic rifts of Pangea. (Reconstruction
to assume
margin
Siberia.
Some of
of kilometers
above
mantle
the unlikely
of a great number
rifts on the southern are of great interest.
of
long. plumes,
simulta-
of plumes. margin
of the
Comparatively
small slices of continental lithosphere (microcontinents of Palagonia, Kirsehir, South Armenia and Iran) split from the Gondwana continent and were carried away across the Tethys. A linear system of
rifting of Gondwana,
in Africa, India, Australia
have
The Triassic
continental Afghanistan
systems formed
and in Western
were thousands
neous development
numerous rifts developed sim~taneousIy over a wide area. A good example is the Late Paleozoic when graben
of
in the North
along the southern
If all these rifts originated
Paleo-Tethys
curs.
There
the Paleo-Tethys, these systems
the geological
break-up
Pangea (Fig. 1). In addition to the Late Paleozoic rifts of Gondwana, of which many continued to develop,
origin of rifts is studied demonstrate
is the Triassic
Atlantic,
as a possible
the plate body. In this paper,
of rifting
cause
sion have also been considered of rifting (Milanovsky,
wide epoch
rifts extending from Greece to was formed behind them and later into the Iiawasina,
deep-sea basins of Pind, and others. This disruption
of the margin can hardly be accounted for by local plumes or diapirs, but instead agrees with the conception of tension created by NE-directed convective flow. Development of some rifts is related to continent-continent collision. As demonstrated by Molnar
and Tapponnier
f 1975) and Tapponnier
et
of Pangea after Zonenshain and Savostin, 1979). I = faults; 2 = major
rift faults; 3 = subduction zones; 4 = mid-oceanic ridge; 5 = areas of diffused extension and volcanism.
al. (1982),
the Baikal rift is part of a structural
pattern resulting from the collision of India and Eurasia. Since the Late Eocene-Oligocene,
South-
east Asia has divided into a system of microplates with independent movements (Zonenshain and Savostin, 1979). In particular, the relative motion of the Siberian and Amur plates produce tension which is responsible for the opening of the Baikal rift. In the same way, movements on the faults of the Rhine rift system are caused by stresses generated in the collision zone of the Alps, where the Apulian microcontinent
collided with Europe (Il-
lies, 1975; Bergerat and Geyssant, 1980; Illies and Baumann, 1982). Stages of Rhine graben development coincide with the stages of collision; changes in the direction of collision resulting in transition from normal faulting to strike-slip displacement on major faults. Both the Baikal and the Rhine rift systems are apparently passive; however, their deep structure is similar to that of the East African rift which is usually considered to be active (Fig. 2). It thus seems that the domal projections of the asthenosphere below all these rifts do not represent active mantle structures (plumes and asthenoliths) and therefore represent the consequence and not a cause of rifting. To
produce
a visible
change
140
/
l.l
in the plate’s
surface (doming, rifting etc.), a mantle plume must be in contact with a specific part of the plate for a considerable time, i.e., the plate must be stable or slowly moving. This condition was applicable to Africa and Eurasia in the Late Cenozoic, when “absolute” motion of these plates was slowed down due to collision (Burke and Dewey, 1973; Gass, 1975; Kazmin, 1980). However, reconstructions of the “absolute” plate motion with reference to hot spots has shown that in the Late Paleozoic all major plates moved rapidly (Zonenshain et al., 1984). Nevertheless, extensive rifting occurred at that time. It is generally believed that domal uplift of the crust precedes rifting. In the mantle plume or diapiric models of rifting this is an essential point: the light material (“anomalous mantle”) accumulates at the base of the crust so that isostatic uplift is generated. Tensional features (grabens and normal faults) appear later when lateral flow
B
Fig. 2. Lithospheric inhomogeneities and rifts. A. In Central Asia (after Zorin et al., 1982) B. In Africa (after Fairhead and Reeves,
1977).
I = normal
faults;
2 = other
faults;
3 =
plateaubasalts; I = volcanic centers; 5 = depth of the asthenosphere-lithosphere
boundary measured from the base of the
crust in A and from the surface in B (in kilometers);
6=
boundary of the lithospheric inhomogeneity.
of the anomalous mantle begins. In fact, many rifts in the past were not accompanied by domal uplift. This applies to the Triassic rifts of Europe and North Atlantic, the Neo-Tethys, Western Siberia, Late Paleozoic rifts of Gondwana and the Mesozoic rifts of the North Sea. Moreover, when rifting is accompanied by uplifts, the succession of events is usually inverse-the uplift follows stages of extension (rifting) and subsidence. A good example is the Red Sea and the Gulf of Aden (Azzaroh, 1968; Kazmin, 1987). In the prerift
88
50-70
Ma
period,
most of the future Red Sea and Aden rifts
were covered by a shallow Late Cretaceous-Paleogene sea (Fig. 3A). The first protorift
depressions
were formed
in the Late Eocene close to sea level.
Immediately
after
sions were partly
sinking, invaded
these shallow
depres-
by sea which advanced
from the east (the Gulf of Aden and the southemmost
part
formation
of the Red Sea, Fig. 3B). Uplift of half-domes
in the Early Miocene, coarse
elastics
bordering
as indicated
to the marginal
and
the rifts began by the influx of parts
of grabens
(Fig. 4). The first stages of rifting in the Baikal rift system
occurred
in the Oligocene
m.y. or more ago), whereas
uplift
or Eocene
(30
and mountain
building is relatively young (3.5 m.y. ago) (Logatchev et al., 1983). The pattern in the Kenya rift is less clear. An uplift of the Kenya dome presumably began in the Middle Miocene, whereas the first indication
“\
35-40
Ma
of subsidence
(extension?)
is
dated as Early Miocene (McCall, 1967). However, some authors relate the start of doming to the Late Cretaceous (Milanovsky, 1976), although the nature of this early uplift is not clear (whether it was the Kenya dome sensu stricto or a larger uplift of the entire continental plate). In summary, geological evidence indicates that rifts are not connected to local sources of energy (mantle plumes and diapirs), but are created by regional stresses. At the same time, two groups of rifts can be recognized; those developing significant uplifts and those accompanied lifts on various scales. The first group includes
rifts developed
without by upduring
the Mesozoic break-up of Pangea. Their evolution is well estimated by models of uniform or of nonuniform extensions described by McKenzie (1978), Le Pichon and Sibuet (1981) and Beaumont et al. (1982). In this group of rifts, rapid extension and attenuation of the lithosphere are followed by Fig
3. Paleogeology of the Red Sea-Gulf
Late Cretaceous-Paleocene B. Late Eocene-Early
of Aden area. A.
(partly after Basahel et al., 1982).
Oligocene. Note the area of diffused
extension in the southern part of the Red Sea rift coinciding with the area of plateau-basalts. To the north this diffused extension is substituted with concentrated extension within the Red Sea graben. I = continental sediments, 2 = shallow marine sediments;
3 = evaporites,
ci = major, b = others.
4 = voIcanies, 5 = normal faults:
isostatic subsidence. Isostatic subsidence is replaced in the time by slow thermal subsidence due to thickening of the cooling lithosphere from below. Extension may lead to the break-up of continental lithosphere and spreading or to formation of rifts with strongly attenuated continental crust. This type of development is typical when continental fragments move freely. in this case volcanism occurs against a background of subsi-
89 2. 51O-
3% O-
S:: O-
Fig. 5. Possible
origin
moved with convective tal collision
block movements
tion created
tension,
causing
ness. I = continental volcanic
in lithospheric
2:::;3*4-
A, Fig. 4. Stages continental
of the development
crust,
4 = direction
2 = anomalous
of the Red Sea rift. mantle,
3 = oceanic
Arabian
fric-
lithosphere,
4 = ancient
flow, 6 = direction plate,
3=
zone of weak-
E-Eurasian
of tension plate,
plate.
I=
of movement.
as is seen in the Mesozoic
A-African
and viscous
along old zones of weak-
2 = oceanic
type,
of convective
plate.
plate
crust,
can rifts which originated and developed simultaneously with the Africa-Eurasia collision. This collision
dence,
of lithosphere rupture
lithosphere,
belt of the Andean
ness, 5 = direction q+++
of the Red Sea rift. The African
flow until the end of Eocene. Continen-
plateau-basalts,
in the Triassic deep-water basins of the Tethys passive margin and in the rifts of Western Siberia. The development of Cenozoic rifts is different. They are accompanied by uplifts varying in size from gigantic (East Africa and Baikal) to moderate (the Rhine rift system). Plateau-basalts related to Cenozoic rifts erupted on the uplifts (the Trap Series of the Ethiopian plateau, plateau-phonolites in Kenya and plateau-basalts of the Baikal
began in the Late Eocene and at the same
time, tensional structures were formed behind the collision zone (Fig. 5). The kinematics were different from that in the Baikal and the Rhine rifts. It seems plausible that when the subduction zone was blocked by continental lithosphere, the convective flow created an excessive tension in the African plate and finally ruptured the latter.
area). As already mentioned, these uplifts are caused by accumulation of light material (anomalous mantle) at the base of the crust. Seismic data show that the anomalous mantle forms 5-30 km thick lenses separated from the asthenosphere by mantle rocks of normal density. Structural interpretations based on seismic and gravity data were presented by Makris et al. (1975), Ginsburg et al. (1981) and Prijdehl (1981) for the Dead Sea and Ethiopian rifts, the Afar region and the Central European rifts. Anomalous mantle has also been demonstrated by geoelectric studies of the Baikal rift (Vanian and Shilovsky, 1983). In contrast to Mesozoic rifts (with free dispersion of Pangean fragments), Cenozoic rifting occurs invariably under the conditions of continental collision. This is true not only for the Baikal and the Rhine rift systems but also for the East Afri-
Fig. 6. Extensional occurs
in the area extension rifts.
structures
in northeastern
not only in Afar (I) and the Ethiopian of the Ethiopian
plateau.
is 700 km wide. 1 = normal
Africa.
Extension
rift (II) but also
The zone of diffused faults,
2 = axial zones of
90
Regardless of the kinematics, all Cenozoic rifts possess an important common feature: Their opening occurred in infrequent pulses separated by long, quiet periods. In the East African rift system, major rifting events are dated at 40, 22, 15, 10 and 5 Ma. These events are reflected in uncomformities, sharp changes in the character of sedimentation, outbursts of volcanism etc., whereas between events, the situation was stable. Similar short pulses of rifting are known in the Baikal rift and the Rhine graben (Illies, 1975; Logatchev et al., 1983). Pulses in rift development (as well as phases of folding in the fold belts) reflect the character of plate motion in the course of collision. This motion, obstructed by collision, apparently occurs periodically at the time of maximum stress release. Another important characteristic of continental rifting should be considered. In early stages, extension is usually diffuse occurring within a zone 300-1000 km wide (Fig. 6), and only later is it concentrated in single grabens, axial zones, and so forth. The pattern of deformation in early stages can be rather complex, with areas of both diffuse and concentrated extension substituting for each other along the strike of the rift system (Fig. 3b). When extension of the continental lithosphere
takes place, it results not only in subsidence of the rift floor but also in passive rise of the asthenosphere. Combination of the two processes leads to nonsymmetrical attenuation of the lithosphere: The rise of the asthenosphere is much greater than surface subsidence {Fig. 7). Physical models of this phenomenon were presented by Shemenda (1984). It may be further assumed that rapid (instantaneous) rise of the asthenosphere at near-solidus temperature causes an increase in partia1 melting. The light material (anomalous mantle) starts to rise to the base of the crust and accumulates there. Conclusion
The differences between Mesozoic and Cenozoic rifts may be explained if one takes all the above points into consideration. When the movement of plates was unrestricted (the Mesozoic rifts), a considerable attenuation of the lithosphere occurred over a short time interval (Fig. 7a). In this case the process proceeds as described by McKenzie (1978) and Le Pichon and Sibuet (1981), i.e., initial isostatic subsidence accompanied the extension and was followed by thermal subsidence of the cooling and thickening lithosphere. The extension may lead directly to the break-up of the
Fig. 7. Two types of continental rifting. A. Extension and subsidence during free dispersion of lithospheric plates (the Mesozoic rifting of Pangea). B. Extension in pulses during collision (the Cenozoic rifts). I = continental crust, 2 = Lithospheric part of the mantle, 3 = top of the asthenosphere, 4 = lens of low-density material (anomalous mantle) at the base of the crust, 5 = volcanism. &I = direction of vertical motion, b = direction of the relative plate motion, 7 = flow direction of light. rising material (anomalous mantle), 8 = boundary of the hthospheric i~omogen~ty.
91
continental lithosphere and onset of spreading, or it may cease before that occurs. In the latter case, large areas of subsidence are formed, e.g., the North Sea and Western Siberia. Anomalous mantle accumulated at the base of the crust, but no uplift occurred since attenuation and subsidence were the dominant factors. If rifting occurs in periodic pulses, and attenuation of the lithosphere during each pulse is small (the Cenozoic rifts), the picture is different (Fig. 7b). Initial attenuation occurs in a zone several hundred kilometers wide and the corresponding rise of the asthenosphere is followed by a long quiet period. During this period, anomalous mantle accumulates in the domal part of the rise and then ascends to higher levels due to the density difference. A lense of anomalous mantle is formed at the base of the crust, causing isostatic uplift. The whole cycle is repeated at the next stage of extension. From geological evidence it seems that large uplifts are formed 15-30 m.y. after the first stage of extension. This time span is probably needed for the anomalous mantle to migrate through the lithosphere mantle.
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85
143 (1987) 85-92
Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
Two types of rifting: dependence of extension
on the condition
V. KAZMIN Shirshov Institute of Oceanology, Academy of Science of the U.S.S.R., (Received August 8,1985;
I I 7218 Moscow (U.S.S.R.)
revised version accepted April 10,1987)
Abstract Kaxmin, V., 1987. Two types of rifting: dependence on the condition of extension. In: I.B. Ramberg, E.E. Milanovsky and G. Qvale (Editors), Continental Rifts-Principal
and Regional Characteristics. Tectonophysics,
143:85-92.
Rifting of continental lithosphere occurs in two ways: (I), through continuous extension and subsequent sinking and (2), in a series of pulses separated by quiet periods, sometimes of considerable duration. In the first case rifting is not accompanied by significant uplifts; in the second, uplifts of various sixes from 100 to 2000 km are typical. Rifting of the first type takes place when continental fragments are freely dispersed, as was the case with Pangea during its Late Triassic-Early
Jurassic break up. In the Cenozoic, rifts developed in the course of continental collision, when
relative plate motion was restricted and occurred in short pulses. Uplift is caused by accumulation of anomalous mantle at the base of the crust during the intervals between phases of extension. Geological evidence is not consistent with the idea of rifting being directly related to a local source of energy in the mantle (mantle plumes and diapirs). It is produced by regional stresses in the lithosphere which, in their turn, may have different origins. The “lithospheric inhomogeneities” observed below the present day rifts are not the cause, but a consequence of extension.
Introduction
ing is regarded as an “active” process (Gass, 1975;
As was pointed out by Talwani and Langseth (1981), the cause of continental rifting remains
Gratchev, 1977; Gass et al., 1978; Artyushkov, 1979; Ramberg, 1981; Logatchev et al., 1983 and many others). However, in this case the litho-
poorly understood. Geophysical studies indicate that large-scale lithospheric inhomogeneities exist below continental rifts. These inhomogeneities are in fact uplifts of the asthenosphere, forming large domes, much wider than individual rifts or grabens and elongated concordantly with the strike of the
sphere must be linked to the energy source for a long period to produce an appreciable effect on the surface. Consequently, rifting is correlated to “stable” intervals in plate motion (Burke and Dewey, 1973; Gass, 1975; Gass et al., 1978; Kazmin, 1980).
rift systems. Usually they are interpreted as active mantle diapirs rising from the deeper mantle. The light material of diapirs (or mantle plumes) accumulates at the base of the crust, resulting in isostatic uplift. Lateral flow of this material due to gravitational instability creates tensional stress in the crust, which finally breaks up to form grabens. According to this point of view, rifts are linked to energy sources immediately below them, and rift-
On the other hand, in many cases there is no visible indication of plume activity (volcanism, uplift etc.) and rifts appear to be “passive” fractures of the lithosphere caused by regional stresses applied to a plate or to an assemblage of plates (Kazmin, 1984 and others). The stress can be created by convective flow causing viscous friction at the bases of the lithosphere (Sorochtin, 1974), by gravity pull of the subducted plate (Bott, 1982),
0040-1951/87/$03.50
0 1987 Elsevier Science Publishers B.V.
86
by
membrane
stresses
(Oxburg
1974), or by the impact and Tapponier,
and
Turcotte,
of plate collision
(Molnar
1975). Pulses of the Earth’s expan-
to be controlled
great rift systems originated
1980). Passive rifting seems
in Europe,
by inherited
zones of weakness
in
pends
evidence
and an attempt
that the difference
on the conditions
is made to
between
in which
for the rifts de-
extension
oc-
Conditions of rifting
were epochs
in geological
history
when
we would
developed Pichakun,
and Antarctica.
In some
areas (South Africa and Antarctica), initial rifting was accompanied by extensive plateaubasalt volcanism which occurred simultaneously with subsidence. Other rifts of this epoch had practically no volcanism although extension was of the same order as in the volcanic rifts. An even more impressive example
Fig. 1. Triassic-Early
of a world-
Jurassic rifts of Pangea. (Reconstruction
to assume
margin
Siberia.
Some of
of kilometers
above
mantle
the unlikely
of a great number
rifts on the southern are of great interest.
of
long. plumes,
simulta-
of plumes. margin
of the
Comparatively
small slices of continental lithosphere (microcontinents of Palagonia, Kirsehir, South Armenia and Iran) split from the Gondwana continent and were carried away across the Tethys. A linear system of
rifting of Gondwana,
in Africa, India, Australia
have
The Triassic
continental Afghanistan
systems formed
and in Western
were thousands
neous development
numerous rifts developed sim~taneousIy over a wide area. A good example is the Late Paleozoic when graben
of
in the North
along the southern
If all these rifts originated
Paleo-Tethys
curs.
There
the Paleo-Tethys, these systems
the geological
break-up
Pangea (Fig. 1). In addition to the Late Paleozoic rifts of Gondwana, of which many continued to develop,
origin of rifts is studied demonstrate
is the Triassic
Atlantic,
as a possible
the plate body. In this paper,
of rifting
cause
sion have also been considered of rifting (Milanovsky,
wide epoch
rifts extending from Greece to was formed behind them and later into the Iiawasina,
deep-sea basins of Pind, and others. This disruption
of the margin can hardly be accounted for by local plumes or diapirs, but instead agrees with the conception of tension created by NE-directed convective flow. Development of some rifts is related to continent-continent collision. As demonstrated by Molnar
and Tapponnier
f 1975) and Tapponnier
et
of Pangea after Zonenshain and Savostin, 1979). I = faults; 2 = major
rift faults; 3 = subduction zones; 4 = mid-oceanic ridge; 5 = areas of diffused extension and volcanism.
al. (1982),
the Baikal rift is part of a structural
pattern resulting from the collision of India and Eurasia. Since the Late Eocene-Oligocene,
South-
east Asia has divided into a system of microplates with independent movements (Zonenshain and Savostin, 1979). In particular, the relative motion of the Siberian and Amur plates produce tension which is responsible for the opening of the Baikal rift. In the same way, movements on the faults of the Rhine rift system are caused by stresses generated in the collision zone of the Alps, where the Apulian microcontinent
collided with Europe (Il-
lies, 1975; Bergerat and Geyssant, 1980; Illies and Baumann, 1982). Stages of Rhine graben development coincide with the stages of collision; changes in the direction of collision resulting in transition from normal faulting to strike-slip displacement on major faults. Both the Baikal and the Rhine rift systems are apparently passive; however, their deep structure is similar to that of the East African rift which is usually considered to be active (Fig. 2). It thus seems that the domal projections of the asthenosphere below all these rifts do not represent active mantle structures (plumes and asthenoliths) and therefore represent the consequence and not a cause of rifting. To
produce
a visible
change
140
/
l.l
in the plate’s
surface (doming, rifting etc.), a mantle plume must be in contact with a specific part of the plate for a considerable time, i.e., the plate must be stable or slowly moving. This condition was applicable to Africa and Eurasia in the Late Cenozoic, when “absolute” motion of these plates was slowed down due to collision (Burke and Dewey, 1973; Gass, 1975; Kazmin, 1980). However, reconstructions of the “absolute” plate motion with reference to hot spots has shown that in the Late Paleozoic all major plates moved rapidly (Zonenshain et al., 1984). Nevertheless, extensive rifting occurred at that time. It is generally believed that domal uplift of the crust precedes rifting. In the mantle plume or diapiric models of rifting this is an essential point: the light material (“anomalous mantle”) accumulates at the base of the crust so that isostatic uplift is generated. Tensional features (grabens and normal faults) appear later when lateral flow
B
Fig. 2. Lithospheric inhomogeneities and rifts. A. In Central Asia (after Zorin et al., 1982) B. In Africa (after Fairhead and Reeves,
1977).
I = normal
faults;
2 = other
faults;
3 =
plateaubasalts; I = volcanic centers; 5 = depth of the asthenosphere-lithosphere
boundary measured from the base of the
crust in A and from the surface in B (in kilometers);
6=
boundary of the lithospheric inhomogeneity.
of the anomalous mantle begins. In fact, many rifts in the past were not accompanied by domal uplift. This applies to the Triassic rifts of Europe and North Atlantic, the Neo-Tethys, Western Siberia, Late Paleozoic rifts of Gondwana and the Mesozoic rifts of the North Sea. Moreover, when rifting is accompanied by uplifts, the succession of events is usually inverse-the uplift follows stages of extension (rifting) and subsidence. A good example is the Red Sea and the Gulf of Aden (Azzaroh, 1968; Kazmin, 1987). In the prerift
88
50-70
Ma
period,
most of the future Red Sea and Aden rifts
were covered by a shallow Late Cretaceous-Paleogene sea (Fig. 3A). The first protorift
depressions
were formed
in the Late Eocene close to sea level.
Immediately
after
sions were partly
sinking, invaded
these shallow
depres-
by sea which advanced
from the east (the Gulf of Aden and the southemmost
part
formation
of the Red Sea, Fig. 3B). Uplift of half-domes
in the Early Miocene, coarse
elastics
bordering
as indicated
to the marginal
and
the rifts began by the influx of parts
of grabens
(Fig. 4). The first stages of rifting in the Baikal rift system
occurred
in the Oligocene
m.y. or more ago), whereas
uplift
or Eocene
(30
and mountain
building is relatively young (3.5 m.y. ago) (Logatchev et al., 1983). The pattern in the Kenya rift is less clear. An uplift of the Kenya dome presumably began in the Middle Miocene, whereas the first indication
“\
35-40
Ma
of subsidence
(extension?)
is
dated as Early Miocene (McCall, 1967). However, some authors relate the start of doming to the Late Cretaceous (Milanovsky, 1976), although the nature of this early uplift is not clear (whether it was the Kenya dome sensu stricto or a larger uplift of the entire continental plate). In summary, geological evidence indicates that rifts are not connected to local sources of energy (mantle plumes and diapirs), but are created by regional stresses. At the same time, two groups of rifts can be recognized; those developing significant uplifts and those accompanied lifts on various scales. The first group includes
rifts developed
without by upduring
the Mesozoic break-up of Pangea. Their evolution is well estimated by models of uniform or of nonuniform extensions described by McKenzie (1978), Le Pichon and Sibuet (1981) and Beaumont et al. (1982). In this group of rifts, rapid extension and attenuation of the lithosphere are followed by Fig
3. Paleogeology of the Red Sea-Gulf
Late Cretaceous-Paleocene B. Late Eocene-Early
of Aden area. A.
(partly after Basahel et al., 1982).
Oligocene. Note the area of diffused
extension in the southern part of the Red Sea rift coinciding with the area of plateau-basalts. To the north this diffused extension is substituted with concentrated extension within the Red Sea graben. I = continental sediments, 2 = shallow marine sediments;
3 = evaporites,
ci = major, b = others.
4 = voIcanies, 5 = normal faults:
isostatic subsidence. Isostatic subsidence is replaced in the time by slow thermal subsidence due to thickening of the cooling lithosphere from below. Extension may lead to the break-up of continental lithosphere and spreading or to formation of rifts with strongly attenuated continental crust. This type of development is typical when continental fragments move freely. in this case volcanism occurs against a background of subsi-
89 2. 51O-
3% O-
S:: O-
Fig. 5. Possible
origin
moved with convective tal collision
block movements
tion created
tension,
causing
ness. I = continental volcanic
in lithospheric
2:::;3*4-
A, Fig. 4. Stages continental
of the development
crust,
4 = direction
2 = anomalous
of the Red Sea rift. mantle,
3 = oceanic
Arabian
fric-
lithosphere,
4 = ancient
flow, 6 = direction plate,
3=
zone of weak-
E-Eurasian
of tension plate,
plate.
I=
of movement.
as is seen in the Mesozoic
A-African
and viscous
along old zones of weak-
2 = oceanic
type,
of convective
plate.
plate
crust,
can rifts which originated and developed simultaneously with the Africa-Eurasia collision. This collision
dence,
of lithosphere rupture
lithosphere,
belt of the Andean
ness, 5 = direction q+++
of the Red Sea rift. The African
flow until the end of Eocene. Continen-
plateau-basalts,
in the Triassic deep-water basins of the Tethys passive margin and in the rifts of Western Siberia. The development of Cenozoic rifts is different. They are accompanied by uplifts varying in size from gigantic (East Africa and Baikal) to moderate (the Rhine rift system). Plateau-basalts related to Cenozoic rifts erupted on the uplifts (the Trap Series of the Ethiopian plateau, plateau-phonolites in Kenya and plateau-basalts of the Baikal
began in the Late Eocene and at the same
time, tensional structures were formed behind the collision zone (Fig. 5). The kinematics were different from that in the Baikal and the Rhine rifts. It seems plausible that when the subduction zone was blocked by continental lithosphere, the convective flow created an excessive tension in the African plate and finally ruptured the latter.
area). As already mentioned, these uplifts are caused by accumulation of light material (anomalous mantle) at the base of the crust. Seismic data show that the anomalous mantle forms 5-30 km thick lenses separated from the asthenosphere by mantle rocks of normal density. Structural interpretations based on seismic and gravity data were presented by Makris et al. (1975), Ginsburg et al. (1981) and Prijdehl (1981) for the Dead Sea and Ethiopian rifts, the Afar region and the Central European rifts. Anomalous mantle has also been demonstrated by geoelectric studies of the Baikal rift (Vanian and Shilovsky, 1983). In contrast to Mesozoic rifts (with free dispersion of Pangean fragments), Cenozoic rifting occurs invariably under the conditions of continental collision. This is true not only for the Baikal and the Rhine rift systems but also for the East Afri-
Fig. 6. Extensional occurs
in the area extension rifts.
structures
in northeastern
not only in Afar (I) and the Ethiopian of the Ethiopian
plateau.
is 700 km wide. 1 = normal
Africa.
Extension
rift (II) but also
The zone of diffused faults,
2 = axial zones of
90
Regardless of the kinematics, all Cenozoic rifts possess an important common feature: Their opening occurred in infrequent pulses separated by long, quiet periods. In the East African rift system, major rifting events are dated at 40, 22, 15, 10 and 5 Ma. These events are reflected in uncomformities, sharp changes in the character of sedimentation, outbursts of volcanism etc., whereas between events, the situation was stable. Similar short pulses of rifting are known in the Baikal rift and the Rhine graben (Illies, 1975; Logatchev et al., 1983). Pulses in rift development (as well as phases of folding in the fold belts) reflect the character of plate motion in the course of collision. This motion, obstructed by collision, apparently occurs periodically at the time of maximum stress release. Another important characteristic of continental rifting should be considered. In early stages, extension is usually diffuse occurring within a zone 300-1000 km wide (Fig. 6), and only later is it concentrated in single grabens, axial zones, and so forth. The pattern of deformation in early stages can be rather complex, with areas of both diffuse and concentrated extension substituting for each other along the strike of the rift system (Fig. 3b). When extension of the continental lithosphere
takes place, it results not only in subsidence of the rift floor but also in passive rise of the asthenosphere. Combination of the two processes leads to nonsymmetrical attenuation of the lithosphere: The rise of the asthenosphere is much greater than surface subsidence {Fig. 7). Physical models of this phenomenon were presented by Shemenda (1984). It may be further assumed that rapid (instantaneous) rise of the asthenosphere at near-solidus temperature causes an increase in partia1 melting. The light material (anomalous mantle) starts to rise to the base of the crust and accumulates there. Conclusion
The differences between Mesozoic and Cenozoic rifts may be explained if one takes all the above points into consideration. When the movement of plates was unrestricted (the Mesozoic rifts), a considerable attenuation of the lithosphere occurred over a short time interval (Fig. 7a). In this case the process proceeds as described by McKenzie (1978) and Le Pichon and Sibuet (1981), i.e., initial isostatic subsidence accompanied the extension and was followed by thermal subsidence of the cooling and thickening lithosphere. The extension may lead directly to the break-up of the
Fig. 7. Two types of continental rifting. A. Extension and subsidence during free dispersion of lithospheric plates (the Mesozoic rifting of Pangea). B. Extension in pulses during collision (the Cenozoic rifts). I = continental crust, 2 = Lithospheric part of the mantle, 3 = top of the asthenosphere, 4 = lens of low-density material (anomalous mantle) at the base of the crust, 5 = volcanism. &I = direction of vertical motion, b = direction of the relative plate motion, 7 = flow direction of light. rising material (anomalous mantle), 8 = boundary of the hthospheric i~omogen~ty.
91
continental lithosphere and onset of spreading, or it may cease before that occurs. In the latter case, large areas of subsidence are formed, e.g., the North Sea and Western Siberia. Anomalous mantle accumulated at the base of the crust, but no uplift occurred since attenuation and subsidence were the dominant factors. If rifting occurs in periodic pulses, and attenuation of the lithosphere during each pulse is small (the Cenozoic rifts), the picture is different (Fig. 7b). Initial attenuation occurs in a zone several hundred kilometers wide and the corresponding rise of the asthenosphere is followed by a long quiet period. During this period, anomalous mantle accumulates in the domal part of the rise and then ascends to higher levels due to the density difference. A lense of anomalous mantle is formed at the base of the crust, causing isostatic uplift. The whole cycle is repeated at the next stage of extension. From geological evidence it seems that large uplifts are formed 15-30 m.y. after the first stage of extension. This time span is probably needed for the anomalous mantle to migrate through the lithosphere mantle.
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