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SEDIMENTARY BASINS
SEDIMENTARY BASINS
BASIN TYPES ACCORDING TO
BASIN TYPES ACCORDING TO
TECTONIC SETTING
TECTONIC SETTING
by
by
Prof. Dr.
Prof. Dr. Abbas
Abbas Mansour
Mansour

Types of sedimentary basins
• We can distinguish between (1) active
sedimentary basins still accumulating
sediments, (2) inactive, but little deformed
sedimentary basins showing more or less
their original shape and sedimentary fill,
and (3) strongly deformed and incomplete
former sedimentary basins, where the
original fill has been partly lost to erosion,
for example in a mountain belt.

Tectonic Basin Classification
• Basin-generating tectonics is the most
important prerequisite for the accumulation
of sediments. Such a basin classification
must be in accordance with the modern
concept of global plate tectonics and hence
will differ from older classifications and
terminology.

Types of plate boundaries
• There are three types of plate boundaries, characterised by the way
the plates move relative to each other. They are associated with
different types of surface phenomena. The different types of plate
boundaries are:
• Transform boundaries occur where plates slide, or perhaps more
accurately grind, past each other along transform-faults. The
relative motion of the two plates is therefore either sinistral or
dextral.
• Divergent boundaries occur where two plates slide apart from
each other.
• Convergent boundaries (or active margins) occur where two
plates slide towards each other commonly forming either a
subduction zone (if one plate moves underneath the other) or an
orogenic belt (if the two simply collide and compress).

The system of Classification
• In this text we essentially use the system
described by Mitchell and Reading, but add
some minor modifications.
• The different types of sedimentary basins
can be grouped into seven categories, which
in turn may be subdivided into two to four
special basin types

To identify the various basin categories
• In order to identify the various basin
categories, one must know the nature of the
underlying crust as well as the type of
former plate movement involved during
basin formation, i.e., divergence or
convergence. Even in the case of transform
movement, either some divergence or
convergence must take place. Small angles
of convergence show up as wrenching or
fold belts, and small angles of divergence
appear as normal faulting or sagging.

Rift-related basins
Rift basin
• Geological Origin: The down-dropped
basin formed during rifting because of
stretching and thinning of the continental
crust
• Example: East Africa Rift

Rift-related basins
Rift basin

Continental graben strictures and rift zones
• Continental graben strictures and rift
zones form narrow elongate basins bounded
by large faults. Their cross sections may be
symmetric or asymmetric (e.g., half-
grabens). If the underlying mantle is
relatively hot, the lithosphere may expand
and show updoming prior to or during the
incipient phase of rifling. Substantial
thinning of the crust by attenuation, which
is often accompanied by the up- streaming
of basaltic magma, thus forming transitional
crust, causes rapid subsidence in the rift
zone. Subsequent thermal contraction due
to cooling and high sedimentary loading
enable continuing subsidence and therefore
the deposition of thick sedimentary
infillings.

A. Divergent plate margin settings
• 1. CONTINENTAL RIFT ZONES – NARROW
• Origin
– large scale mantle convection
– regional updoming
• ± regional basaltic (flood) volcanism
– extensional failure of crust
• lystric normal fault system
• subsided/rotated half grabens
– widening to form central rift graben
– may:
• rupturing of crust
• spreading ridge, oceanic basin

• two associated basin types
1. central rift graben basin
2. rim basins
– environments & facies
1. alluvial fan, fluvial, lake
• volcanism
1. initial (flood) basaltic (arch phase)
• lavas
2. intra-rift bimodal volcanism
• basalt-rhyolite lavas & pyroclastics
• often peralkaline
• calderas, stratovolcano, shields
• mantle magmas melt crust

• Sediment compositions
1. mixed provenance
2. exposed crustal rocks at rift margin
• contemporaneous volcanic sources
• Examples
1. East Africa rift zone
2. Rio Grande rift; Rhine graben
• May be subsequently deformed by compressional
deformation
1. e.g. Proterozoic Mt. Isa rift
2. Devono-Carb. Mt. Howitt province, Victoria

Failed rifts and aulacogens
• If divergent plate motion comes to an end before
the moving blocks are separated by accretion of
new oceanic crust, the rift zone is referred to as
"failed". A certain type of such failed rifts is an
aulacogen. Aulacogens represent the failed arm of
a triple junction of a rift zone, where two arms
continue their development to form an oceanic
basin. Aulacogen floors consist of oceanic or
transitional crust and allow the deposition of thick
sedimentary sequences over relatively long time
periods. Basins similar to aulacogens may also be
initiated during the closure of an ocean and during
orogenies

• 2. AULACOGENE BASINS
• Narrow continental rifts which do not evolve into spreading ridge
oceanic basins.
– e.g North Sea basins, Europe; Gippsland Basin, Bass Basin.
• Dominated by initial alluvial fan, fluvial, lake facies; up to 4 km thick.
• May extend enough
– crustal subsidence & extension
– marine transgression; no oceanic crust
– coastal plain rivers, coal swamp shoreline, shelf & slope
environment (e.g. Gippsland, Bass basins
• Provenance
– continental, mixed
– plutonic, metasedimentary, metavolcanic, contemporaneous
volcanic
– ± marine carbonates

• 3. CONTINENTAL RIFT ZONES
• Origin
– regionally extensive mantle convection
– = ? driven by subduction oceanic spreading ridge under continent
• e.g. ?Western U.S.A.
– extensional failure of crust
– complex lystric fault system
• down to 15 km, Western U.S.A.
– uprise of mantle + metamorphic core complexes - regional uplift, up to 2-
3 km
– widespread volcanism in complex multiple graben rift basins
• Environments and facies
– alluvial fan, fluvial, lacustrine
• Volcanism
– flood basalts, bimodal basalt-rhyolite-andesite: lavas & pyroclastics
– tholeiitic, alkaline, calc-alkaline: lavas & pyroclastics.
• Provenance
– mixed crustal sources
– contemporaneous volcanic sources

• 4. OCEANIC RIFT BASINS, Initially narrow (e.g. Red Sea)
– may evolve into open oceanic basins
• Origin
– narrow continental rifts evolve
– break-up
– oceanic spreading ridge
– oceanic crust inaxial basins
– continental crust at basin margin
• Environments & facies
– alluvial fans, fan deltas, shoreline narrow shelf, slope, abyssal plain
• Volcanism
– MORB tholeiitic oceanic crust
– lavas, hyaloclastite
• Provenance
– mixed continental
– contemporaneous volcanics
– shelf carbonate, evaporites
– oceanic carbonate, evaporites
– oceanic pelagic, hemi-pelagic

• 5. OPEN OCEAN-PASSIVE MARGIN BASINS
• Evolve from oceanic rift basins
• Become passive margin basins when MOR’s - large, wide ocean
basins.
• Half graben system evolves into coastal plain-continental shelf &
slope
– oceanic abyssal plain system
• Volcanism
– none expected after break-up
– perhaps intraplate hot spot volcanism
• Sedimentation & provenance
– as for oceanic rift basin
– + well developed shelf-slope seds (± carbonate seds.)
• Tectonics
– post-break-up thermal & later isostatic subsidence of continental
margin
• transgression

Rift-related basins
Passive margin basin
• Geological Origin: Subsidence along a
passive margin, mostly due to long-term
accumulation of sediments on the
continental shelf
• Example: East coast of North America

Rift-related basins
Passive margin basin

Passive margin basins
• The initial stage of a true oceanic basin setting (or
a proto-oceanic rift system) is established when
two divergent continents separate and new oceanic
crust forms in the intervening space. This does not
necessarily mean that such a basin type fills with
oceanic sediments, but it does imply that the
central basin floor lies at least 2 to 3 km below sea
level. When such a basin widens due to continued
divergent plate motions and accretion of oceanic
crust (drifting stage), its infilling with sediments
lags more and more behind ocean spreading.

• Consequently, the sediments are deposited
predominantly at the two continental margins of
the growing ocean basin. The marginal "basins"
developing on top of thinned continental crust are
commonly not bordered by morphological highs
and represent asymmetric depositional areas.
Their underlying crust increasingly thins
seaward; hence subsidence tends to become
greater and faster in this direction. Here,
sediments commonly build up in the form of a
prism (Fig. D).

• Some of these marginal basins may be
affected and bordered by transform motions
(tension-sheared basins). In a sediment-
starved environment, subsided transitional
crust can create deep plateaus (sunk basins).
In general, subsidence of these marginal
basins tends to decrease with passing time,
unless it is reactivated by heavy sediment
loads.

Oceanic sag basins or nascent ocean basins
• Oceanic sag basins or nascent ocean basins
occupy the area between a mid-oceanic ridge,
including its rise, and the outer edge of the
transitional crust along a passive continental
margin (Fig. f). They commonly accumulate deep-
sea fan or basin plain sediments. Due to the
advanced cooling of the aging oceanic crust,
subsidence is usually low, unless it is activated by
thick sedimentary loading near the continental
margin. Fault-bounded basins of limited extent are
common in conjunction with the growth of mid-
oceanic ridges

Oceanic sag basins or nascent ocean basins

B. Convergent plate margins
• Another group of basins is dominated
by convergent plate motions and
orogenic deformation. Basins related
to the development of subduction
complexes along island arcs or active
continental margins include deep-sea
trenches, forearc basins, backarc
basins (Fig. 1.2a and b), and smaller
slope basins and intra-arc basins.

• 6. CONTINENTAL MARGIN ARC-SUBDUCTION
ASSOCIATED BASINS
• Sediment compositions
– Trench
• metasedimentary debris eroded off accretionary prism
• v. minor volcanic debris
• pelagic sed.
– Forearc basin
• voluminous volcanic debris
– Back-arc basin
• arc & thrust belt derived
• mixed volc., meta-sed., metamorphic, plutonic
– Intra-arc basins
• lavas,volcanic seds, pyroclastics

• Deep-sea trench floors are composed of
descending oceanic crust. Therefore, some of
them represent the deepest elongate basins present
on the globe. In areas of very high sediment influx
from the neighboring continent, however, they are
for the most part filled up and morphologically
resemble a continental rise. Deep-sea trenches
commonly do not subside as do many other basin
types. In fact, they tend to maintain their depth
which is controlled mainly by the subduction
mechanism, as well as by the volume and
geometry of the accretionary sediment wedge on
their landward side

Subduction-related basins
Trench (accretionary wedge)
• Geological Origin: Downward flexure of
the subducting and non-subducting plates
(sites of accretionary wedges)
• Example: Western edge of Vancouver
Island

Forearc basin
• Geological Origin: The area between the
accretionary wedge and the magmatic arc,
largely caused by the negative buoyancy of
the subducting plate pulling down on the
overlying continental crust
• Example: Georgia Strait

• Forearc basins occur between the trench slope
break of the accretionary wedge and the magmatic
front of the arc. The substratum beneath the center
of such basins usually consists of transitional or
trapped oceanic crust older than the magmatic arc
and the accretionary subduction complex. Rates of
subsidence and sedimentation tend to vary, but
may frequently be high. Subsequent deformation
of the sedimentary fill is not as intensive as in the
accretionary wedge .

• Backarc or interarc basins form by rifling and
ocean spreading either landward of an island
arc, or between two island arcs which originate
from the splitting apart of an older arc system
(Fig. 1.2a). The evolution of these basins
resembles that of normal ocean basins between
divergent plate motions. Their sedimentary fill
frequently reflects magmatic activity in the arc
region.

• 7. ISLAND ARC-SUBDUCTION ASSOCIATED
BASINS
• E.g. Marianas, Tonga-Kermadec arcs
• Origin
– oceanic plate is subducted under another oceanic plate
– trench, accretionary prism, volcanic island arc
– volcanic arc on oceanic lithosphere
– back arc basin(s) originate by rifting of arc block, development of
small spreading ridge
• widening basin; oceanic crust
– arc block migrates trenchward as subducting plate "rolls back".
• Volcanism
– island arc tholeiitic volcanics
• basalts, basaltic andesites
– back arc basin tholeiitic crust

• 7. ISLAND ARC-SUBDUCTION ASSOCIATED BASINS
• Basin types, environments, facies, provenance
– Trench basin
• turbidites, pelagic sediments
• metasedimentary sed. from accretionary prism
• arc derived volcanic sediment
– Fore-arc basin
• on accretionary prism
• volcanic seds., carbonates
• turbidites
– Back arc basin
• arc derived volcaniclastic turbidite apron
• pelagic sediments, especially where basin is large
– no continental derived sediment
– only rare silicic volcanism

• Temne-related basins are situated between
micro-continents consisting at least in part
of continental crust ( Nur and Ben-Avraham
1983) and larger continental blocks. The
substratum of these basins is usually
oceanic crust. They may be bordered by a
subduction zone and thus be associated with
either basins related to subduction or
collision.

• 8. CONTINENTAL COLLISION BELTS & BASINS
• E.g. Himalayan mountain chain, European Alps
• Origin
– long term subduction of oceanic plate under continental margin, will
bring "passenger" continent into collision with arc host continent.
– oceanic basin closes during collision
– subducting continent under thrust over-riding continent
– uplift, mountain range, double continental crust thickness
• Volcanism
– subduction related volcanism stop at collision, when subduction stop
– granitoid plutonism may occur due to extremely thickened crust
• magmas won't rise because of compressional stress field
• Basin types, environments, facies provenance
– foreland basin at foot of fold & thrust belt
– subject to isostatic subsidence
– huge sediment flux off mountain belt
– alluvial fan, braided river, meandering river, lake environments & facies
– metasedimentary, met. (include high grade plutonic, reflecting deep
crustal erosion)

Basins related to collision
• Partial collision of continents with irregular shapes
and boundaries which do not fit each other leads
to zones of crustal over thrusting and, along strike,
to areas where one or more oceanic basins of
reduced size still persist (Fig. 1.2c). These
remnant basins tend to collect large volumes of
sediment from nearby rising areas and to undergo
substantial synsedimentary deformation
(convergence, also often accompanied by strike-
slip motions).

Foreland basin
• Foreland basins. and peripheral basins in front
of a foldthrust belt, are formed by depressing
and flexuring the continental crust ("A-
subduction", after Ampferer, Alpine-type)
under the load of the overthrust mountain belt
(Fig. 1.2c and Fig. 1.3a). The extension of
these asymmetric basins tends to increase with
time, but a resulting large influx of clastic
sediments from the rising mountain range
often keeps pace with subsidence

Foreland basin
• Geological Origin: A depression caused by
the weight of a large mountain range
pushing the adjacent crust below sea level
Example: The sediment filled plain south
of the Himalayas

• As a result of the collision of two
continental crusts, the overriding plate may
be affected by 'continental escape', leading
to extensional graben structures or rifts
perpendicular to the strike of the fold-thrust
belt (Fig. 1.2c).

• Retroarc or intramontane basins (Fig. 1.2b)
occur in the hinterland of an arc orogen ('B-
subduction" zone). They may affect
relatively large areas on continental crust.
Limited subsidence appears to be caused
mainly by tectonic loading in a backarc
fold-thrust belt.

• Pannonian-type basins originate from post-
orogenic divergence between two fold-
thrust zones (Fig. 1.3a). They are usually
associated with an A-subduction zone and
are floored by thinning continental or
transitional crust .

• During crustal collision, some foreland (and
retroarc) basins can get broken up into separate
smaller blocks, whereby strike-slip motions may
also play a role (Fig. 1.2c). Some of the blocks are
affected by uplift, others by subsidence, forming
basinal depressions. The mechanics of such tilted
block basins were studied, for example, in the
Wyoming Province of the Rocky Mountain
foreland. So-called Chinese-type basins result
from block faulting in the hinterland of a
continent-continent collision.

• 9. CONTINENTAL STRIKE-SLIP BASINS
• E.g. California borderland basins associated with San Andreas
strike-slip fault system , Various locations on the San Andreas
Fault or the Anatolian Fault
• Origin
– strike-slip along non-linear faults
– opening "holes" or basins at fault jogs or bends
– A pull-apart block (eg. between two transform faults) that subsides
significantly
• Volcanism
– usually none, unless "accidental" intraplate
• Basin types, environments, facies, provenance
– "pull-apart" or strike-slip basins
– alluvial fans, rivers, lakes
– alluvial, lacustrine, coal, ?evaporite seds.
– provenance: whatever is being eroded from exposed crust

Transform-fault basins
Strike-slip basin

Strike-slip and wrench basins
• Transform motions may be associated either with a
tensional component (transtensional) or with a
compressional component (transpressional). Transtensional
fault systems locally cause crustal thinning and therefore
create narrow ،elongate pull-apart basins. If they evolve
on continental crust, continuing transform motion may lead
to crustal separation perpendicular to the transform
faults and initiate accretion of new oceanic crust in limited
spreading centers. Until this development occurs, the rate
of subsidence is usually high. Transpressional systems
generate wrench basins of limited size and endurance.
Their compressional component can be inferred from
wrench faults and fold belts of limited extent (Fig. 1.3c ).

• 10. STABLE CONTINENTAL INTERIOR BASIN
• E.g. Lake Eyre Basin
• Intracratonic (= within stable continental crustal mass)
• Long term stability
• Flat topography
• River, desert, lake environments & facies
• Mature basement derived sed. ± evaporites

Continental or interior sag basins
• Basins on continental crust are
commonly generated by
divergent plate motions and
resulting extensional structures
and thermal effects. In the case
of large interior sag basins,
however, major fault systems
forming the boundaries of the
depositional area or a central
rift zone may be absent.
Subsidence occurs
predominantly in response to
moderate crustal thinning or to
a slightly higher density of the
underlying crust in comparison
to neighboring areas.

• In addition, slow thermal decay after a heating
event and sedimentary loading can promote and
maintain further subsidence for a long time.
Alternatively, it was recently suggested that long-
term subsidence of intracratonic basins may be
related to a decrease of the mantle heat flow above
a "cold spot", i.e., abnormal cooling (Ziegler
1989). In general, rates of subsidence are low in
this geodynamic setting.

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