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Collision tectonics of the Wanni and Highland complexes in Sri Lanka
XIV
Note
the significant
shift
in 6’BO from
Collision tectonics of the Wanni and Highland complexes in Sri Lanka
> + 20?6~
to + 15.3% and also the shaft In 613C (Hoffbauer and Spiering, 1994). Thus, the indications are that the Eppawala carbonate rock is not a carbonatite but a marble which has been intruded lighter and
by
granite
and
rendered
due to the interaction fluids
which
derived
is very
from
much
isotopically
between the
the marble
granitic
in evidence
dolomitic
have
marble
produced
such
as
diopside,
phlogopite,
and
chalcopyrite
metasomatizing
granite
in
including
of carbonate
rock
Thus the intense greatly
to
to as a skarn as that
deposit
two
granite
to
the
552
Ma and 556
It is most
granitic
intrusion
likely
means
the age of the
Eppawala
took
Eppawala region
place
that
while
of Eppawala
thus
belong
namely,
the
located
close
1994). to the
dated
(Holzl
that
the
at the
at
al.,
et
the
Eppawala
age,
i.e. about
this is most
probably
mineralization time
of
the
1994) same
M9
in the
time
(Precambrian
Zone 3) the Ml 3 metamorphism (Hapuarachchi,
be same
been
apatite
during
so
is not known
(Hapuarachchi,
area
west
have
is of the same
550 Ma, which
metamorphism
and
be referred
Ma respectively
1994).
which
granite granites,
deposit
at
at Eppawala.
occurrences,
and Tonigala
Eppawala
to have
skarn
may
intrusion
in the
complex
was in progress
The apatite
deposit
may
Pan-African.
REFERENCES Hapuarachchi, D. J. A. C. 1994. Professional Paper 63~. Hoernes, E. et al. 1994. Precambrian Research 66, 183-198. Hoffbauer, R. and Spiering, 8. 1994. Precambrian Research
66,
Osaka City University, Japan
of
amphibolite
an
(Vijayan from
(Cooray,
1994). and
WC
(AG),
of the
325349.
Holzl, S. et al. 1994. Precambrian Research 66, 123-149. Jayawardena, D. E. de S. 1976. Geological Survey Dept. Colombo 2, Economical Bulletin 3, 4 1 p.
between
and
west
which
1994).
The relationship
still obscure. area
near
WC and HC, as well are carried Structural
the
and the
latter
between
(BDchel,
WC and HC is field studies
boundary
as structural
and kinematic field
in and around
between
studies
Kurunegala
areas.
of WC
The deformational
Dn-5
(banding Dn-3
a southward
(east-west
trending in the
folds),
showing
east-west
(asymmetric
folds),
area,
while
(earlier
a southward
structures
(asymmetric Dn Dn + 1
and Dn + 2 (local shear
Dn-2
trending
by
showing
vergence),
upright
Kurunegala
and foliation),
structures
Dn-1
major
Dn-4
formed
structures
an eastward
trending
the earliest
and foliation),
vergence), showing
(north-south
out and
sequences
from
(structures
Dn-2 (asymmetric
structures
carried
Gadaladeniya-Aranayake
folds),
flattening),
of WC, based
were
of the following
to the latest: (recumbent
analyses
observations,
the
are composed
(banding
Sri Lanka.
out In this study.
on detailed
zones)
in five boundary
by a thrust
the
the The
to form
the
this, detailed
surrounding
are
into
is exposed
over
To clarify
which
respectively
complexes.
WC and HC in central is superposed
later
VC),
is considered
WC,
synforms
former
terrain
amphibolite-
to east,
HC and VC are separated
of the
an
Wanni
eastern
are
terrain
facies
is subdivided
eastern
gneiss
facies
complex:
the
East
and are composed
granulite HC)
of gneisses
WC), a granulite
complex:
western
fragments
high-grade
to
complex: terrain
Arena
the
in Sri Lanka
doubly-plunging
rocks
it to
distributed
a part
apatite.
and its age would
The age of the Eppawala but
the
appears
deposit
for the granitic
Galgamuwa
for
carbonate
converting apatite
the
process
metasomatism
account
the
thus
Eppawala
bodies
from
widely (Wanni
of
Precambrian
distributed
the marble
derived
metasomatism
modified
Eppawala the
skarn-like
chlorine
is one
Lanka
facies
pyrite,
metasomatic
and
Srr
(Highland
biotite,
between
fluids
a complex fluorine
tremolite,
including
These
to
minerals
actinolite,
by the reaction
and
appears with
hornblende,
and apatite.
are formed
deposit
granite
bodies
sulphides,
of Geosciences, Osaka 558,
Gondwana.
Eppawala
scapolite,
magnetite
and
at
skarn-like
Department
intrusion
in the
area (Jayawardena, 1976). Interaction between the intrusive the
Y. TANI
vergence
upright showing
Dn-3
asymmetric folds),
and Dn-1
an eastward
vergence), Dn (north-south trending upright folds), Dn + 1 (en echelon veins showing a dextral shear sense), and Dn + 2 (east-west trending folds) from the earliest to the latest in the GadaladeniyaAranayake area. On the other hand, structural and kinematic analyses of HC that were carried out in the Kegall-Peradeniya area show the following deformational sequence from the earliest to the latest:
Dn-3
(banding
and
foliation),
Dn-2
xv
(asymmetric
structures
showing
material.
a southward
This
vergence), Dn-1 (asymmetric structures an eastward vergence), Dn (north-south
showing trending
surrounded
upright
showing
Eastern
folds),
a dextral
Dn + 1 (en echelon
shear sense
Dn + 2 (east-west Shear
sense
folds,
trending
and
S-C
such
following
two
southward
asymmetric observed
Together
the
in this
WC were
enclosing These
suggest
Lankan piled
directions.
This were
regimes
during
Garnet
HC and a topMa
and kinematics that
Sri
by the movement present terrains
convergent
Pan-African
period.
amounts
along
boundary of
GBG
that
the
garnet
Sri Lanka
P. 1994.
Journal
Geological
5, 41-57.
of migmatitic Eastern
rocks in Tekkali,
Ghats,
T. YAMAMOTO,’
India
A. T. RAO’
and
M. YOSHIDA’ ‘Department
of Geoscience, Osaka City University, Osaka 558 Japan 2Department of Geology, Andhra University, Visakhapatnam, 530003 India
leucosome
coronal
rims
Ti-rich
of garnet
which
of garnet
Furthermore,
the
zoning
in most minerals
that
might
have
When
hypersthene
considered
or
as a residue,
Bt + Qtz
+ PI +
and Montel,
Opx
event
absense indicates
uplifted
quickly.
garnet
in
the
GBG + melt
may promote
partial
melting and produced the migmatitic appearance. So far as the occurrence is concerned, the concept of dehydration melting seems reasonable. On the other hand, it has not yet been sure whether this migmatitic rocks were created by in situ melting or not. The possibility that this leucosome is a derived channel of the main plutonic body remains to be solved by future study. Our on going project aims to evaluate all these alternatives by further field and
geochemical
works. REFERENCES
In Tekkali, South
Srikakulum
India,
hundreds
many
rock
is
granite
of quarries
100 km*. Light mined
district,
companies
Pradesh, are running
in an area approximately
grayish-blue and
Andhra
sold
coloured as
migmatitic
a construction
is
reaction:
+ Grt + Kfs
1994)
that this
cooling
of compositional this massif
of
between
indicates
an isobaric
and
textures
especially
from
provides
pressure
Reaction
and plagioclase, 1989).
that
This texture about
quartz,
suffered
to that
suggesting with
from
conditions. with
in minor
be xenocrystic.
information
temperature
(Vielzeuf
Study
may
uniform
similar thus
composition
(IBC) (Harley,
Society
a “greasy” has
also occurs
in GBG (Py,,Alm,,Sps,Grs,,).
garnet
a charnockitic
leucosome-mesosome
in the
exhibits
important
mafic
interstitial
exhibit
and has a composition
has a different
rock type
39-57.
the
Hypersthene lamellae
not
(Py,,Alm,,Sps,Grs,),
orthopyroxene
Btichel, G. 1994. Precambrian Research 66, 77-94. Cooray, P. G. 1994. Precambrian Research 66, 3-20. Kleinschrodt, R. 1994. Precambrian Research 66,
does
has
of An,,.
REFERENCES
KrGner, A. and Jaeckel,
leucosome
composition
that
the
the
Ma (Kroner
indicate
by the
plagioclase,
plagioclase
of the Precambrian formed
Although
of
of
granoblastic
and clinopyroxenes.
and
570-550
different
indicates
structure
Sri Lanka
tectonic
two
consist
across
as massive
number show
appearance
is characterized
having
fundamental of
study,
large enclaves
this
over VC with
Structures
in this
ortho-
cuts
also occurs
it
hand,
at about
and
biotite, is
HC with and
700-800
thrusted
WC
texture
leucosome
which
assemblage,
movement,
megastructure nappe
that over
On the other
1994).
clarified
data
and the kinematic
of
(garnet
The
as net-veins
enclaves.
geochronological
of gneissic
association
orthopyroxene
leucosome.
occurs
outcrops
vergence,
(Kleinschrodt, of WC
mainly
in the
GBG) and orthopyroxene-bearing
HC.
at about
altogether
eastward
gneiss:
coarse-grained
eastward
southward
to-the
biotite
by the
minor
a later
study
1994).
with
in WC and
a top-to-the and Jaeckel,
the
biotite
rocks
lithology
are comprised
and
to HC and thrusted
possibly
and show
main
characterized
garnet,
massif
belt.
rocks
the GBG. The leucosome
allochthonous occured
in
mobile
an earlier
so far, the structural
analyses
Ghats
The migmatitic
a migmatitic
the
kinematics:
gneisses
with
published
were
the areas
different
of the
as asymmetric
is
metasedimenta’ry
series),
mesosome
megacrysts,
movement,
movement
and
fabrics,
WC and HC throughout
(khondalite
folds).
indicators,
asymmetric
boudinage
veins
and local shear zones),
area by
Harley, S. L. 1989. Geological Magazine Veilzeuf, D. and Montel, J. M. 1994. Mineralogy
Petrology
117,
375-393.
126,
215-247.
Contributions
Note
the significant
shift
in 6’BO from
Collision tectonics of the Wanni and Highland complexes in Sri Lanka
> + 20?6~
to + 15.3% and also the shaft In 613C (Hoffbauer and Spiering, 1994). Thus, the indications are that the Eppawala carbonate rock is not a carbonatite but a marble which has been intruded lighter and
by
granite
and
rendered
due to the interaction fluids
which
derived
is very
from
much
isotopically
between the
the marble
granitic
in evidence
dolomitic
have
marble
produced
such
as
diopside,
phlogopite,
and
chalcopyrite
metasomatizing
granite
in
including
of carbonate
rock
Thus the intense greatly
to
to as a skarn as that
deposit
two
granite
to
the
552
Ma and 556
It is most
granitic
intrusion
likely
means
the age of the
Eppawala
took
Eppawala region
place
that
while
of Eppawala
thus
belong
namely,
the
located
close
1994). to the
dated
(Holzl
that
the
at the
at
al.,
et
the
Eppawala
age,
i.e. about
this is most
probably
mineralization time
of
the
1994) same
M9
in the
time
(Precambrian
Zone 3) the Ml 3 metamorphism (Hapuarachchi,
be same
been
apatite
during
so
is not known
(Hapuarachchi,
area
west
have
is of the same
550 Ma, which
metamorphism
and
be referred
Ma respectively
1994).
which
granite granites,
deposit
at
at Eppawala.
occurrences,
and Tonigala
Eppawala
to have
skarn
may
intrusion
in the
complex
was in progress
The apatite
deposit
may
Pan-African.
REFERENCES Hapuarachchi, D. J. A. C. 1994. Professional Paper 63~. Hoernes, E. et al. 1994. Precambrian Research 66, 183-198. Hoffbauer, R. and Spiering, 8. 1994. Precambrian Research
66,
Osaka City University, Japan
of
amphibolite
an
(Vijayan from
(Cooray,
1994). and
WC
(AG),
of the
325349.
Holzl, S. et al. 1994. Precambrian Research 66, 123-149. Jayawardena, D. E. de S. 1976. Geological Survey Dept. Colombo 2, Economical Bulletin 3, 4 1 p.
between
and
west
which
1994).
The relationship
still obscure. area
near
WC and HC, as well are carried Structural
the
and the
latter
between
(BDchel,
WC and HC is field studies
boundary
as structural
and kinematic field
in and around
between
studies
Kurunegala
areas.
of WC
The deformational
Dn-5
(banding Dn-3
a southward
(east-west
trending in the
folds),
showing
east-west
(asymmetric
folds),
area,
while
(earlier
a southward
structures
(asymmetric Dn Dn + 1
and Dn + 2 (local shear
Dn-2
trending
by
showing
vergence),
upright
Kurunegala
and foliation),
structures
Dn-1
major
Dn-4
formed
structures
an eastward
trending
the earliest
and foliation),
vergence), showing
(north-south
out and
sequences
from
(structures
Dn-2 (asymmetric
structures
carried
Gadaladeniya-Aranayake
folds),
flattening),
of WC, based
were
of the following
to the latest: (recumbent
analyses
observations,
the
are composed
(banding
Sri Lanka.
out In this study.
on detailed
zones)
in five boundary
by a thrust
the
the The
to form
the
this, detailed
surrounding
are
into
is exposed
over
To clarify
which
respectively
complexes.
WC and HC in central is superposed
later
VC),
is considered
WC,
synforms
former
terrain
amphibolite-
to east,
HC and VC are separated
of the
an
Wanni
eastern
are
terrain
facies
is subdivided
eastern
gneiss
facies
complex:
the
East
and are composed
granulite HC)
of gneisses
WC), a granulite
complex:
western
fragments
high-grade
to
complex: terrain
Arena
the
in Sri Lanka
doubly-plunging
rocks
it to
distributed
a part
apatite.
and its age would
The age of the Eppawala but
the
appears
deposit
for the granitic
Galgamuwa
for
carbonate
converting apatite
the
process
metasomatism
account
the
thus
Eppawala
bodies
from
widely (Wanni
of
Precambrian
distributed
the marble
derived
metasomatism
modified
Eppawala the
skarn-like
chlorine
is one
Lanka
facies
pyrite,
metasomatic
and
Srr
(Highland
biotite,
between
fluids
a complex fluorine
tremolite,
including
These
to
minerals
actinolite,
by the reaction
and
appears with
hornblende,
and apatite.
are formed
deposit
granite
bodies
sulphides,
of Geosciences, Osaka 558,
Gondwana.
Eppawala
scapolite,
magnetite
and
at
skarn-like
Department
intrusion
in the
area (Jayawardena, 1976). Interaction between the intrusive the
Y. TANI
vergence
upright showing
Dn-3
asymmetric folds),
and Dn-1
an eastward
vergence), Dn (north-south trending upright folds), Dn + 1 (en echelon veins showing a dextral shear sense), and Dn + 2 (east-west trending folds) from the earliest to the latest in the GadaladeniyaAranayake area. On the other hand, structural and kinematic analyses of HC that were carried out in the Kegall-Peradeniya area show the following deformational sequence from the earliest to the latest:
Dn-3
(banding
and
foliation),
Dn-2
xv
(asymmetric
structures
showing
material.
a southward
This
vergence), Dn-1 (asymmetric structures an eastward vergence), Dn (north-south
showing trending
surrounded
upright
showing
Eastern
folds),
a dextral
Dn + 1 (en echelon
shear sense
Dn + 2 (east-west Shear
sense
folds,
trending
and
S-C
such
following
two
southward
asymmetric observed
Together
the
in this
WC were
enclosing These
suggest
Lankan piled
directions.
This were
regimes
during
Garnet
HC and a topMa
and kinematics that
Sri
by the movement present terrains
convergent
Pan-African
period.
amounts
along
boundary of
GBG
that
the
garnet
Sri Lanka
P. 1994.
Journal
Geological
5, 41-57.
of migmatitic Eastern
rocks in Tekkali,
Ghats,
T. YAMAMOTO,’
India
A. T. RAO’
and
M. YOSHIDA’ ‘Department
of Geoscience, Osaka City University, Osaka 558 Japan 2Department of Geology, Andhra University, Visakhapatnam, 530003 India
leucosome
coronal
rims
Ti-rich
of garnet
which
of garnet
Furthermore,
the
zoning
in most minerals
that
might
have
When
hypersthene
considered
or
as a residue,
Bt + Qtz
+ PI +
and Montel,
Opx
event
absense indicates
uplifted
quickly.
garnet
in
the
GBG + melt
may promote
partial
melting and produced the migmatitic appearance. So far as the occurrence is concerned, the concept of dehydration melting seems reasonable. On the other hand, it has not yet been sure whether this migmatitic rocks were created by in situ melting or not. The possibility that this leucosome is a derived channel of the main plutonic body remains to be solved by future study. Our on going project aims to evaluate all these alternatives by further field and
geochemical
works. REFERENCES
In Tekkali, South
Srikakulum
India,
hundreds
many
rock
is
granite
of quarries
100 km*. Light mined
district,
companies
Pradesh, are running
in an area approximately
grayish-blue and
Andhra
sold
coloured as
migmatitic
a construction
is
reaction:
+ Grt + Kfs
1994)
that this
cooling
of compositional this massif
of
between
indicates
an isobaric
and
textures
especially
from
provides
pressure
Reaction
and plagioclase, 1989).
that
This texture about
quartz,
suffered
to that
suggesting with
from
conditions. with
in minor
be xenocrystic.
information
temperature
(Vielzeuf
Study
may
uniform
similar thus
composition
(IBC) (Harley,
Society
a “greasy” has
also occurs
in GBG (Py,,Alm,,Sps,Grs,,).
garnet
a charnockitic
leucosome-mesosome
in the
exhibits
important
mafic
interstitial
exhibit
and has a composition
has a different
rock type
39-57.
the
Hypersthene lamellae
not
(Py,,Alm,,Sps,Grs,),
orthopyroxene
Btichel, G. 1994. Precambrian Research 66, 77-94. Cooray, P. G. 1994. Precambrian Research 66, 3-20. Kleinschrodt, R. 1994. Precambrian Research 66,
does
has
of An,,.
REFERENCES
KrGner, A. and Jaeckel,
leucosome
composition
that
the
the
Ma (Kroner
indicate
by the
plagioclase,
plagioclase
of the Precambrian formed
Although
of
of
granoblastic
and clinopyroxenes.
and
570-550
different
indicates
structure
Sri Lanka
tectonic
two
consist
across
as massive
number show
appearance
is characterized
having
fundamental of
study,
large enclaves
this
over VC with
Structures
in this
ortho-
cuts
also occurs
it
hand,
at about
and
biotite, is
HC with and
700-800
thrusted
WC
texture
leucosome
which
assemblage,
movement,
megastructure nappe
that over
On the other
1994).
clarified
data
and the kinematic
of
(garnet
The
as net-veins
enclaves.
geochronological
of gneissic
association
orthopyroxene
leucosome.
occurs
outcrops
vergence,
(Kleinschrodt, of WC
mainly
in the
GBG) and orthopyroxene-bearing
HC.
at about
altogether
eastward
gneiss:
coarse-grained
eastward
southward
to-the
biotite
by the
minor
a later
study
1994).
with
in WC and
a top-to-the and Jaeckel,
the
biotite
rocks
lithology
are comprised
and
to HC and thrusted
possibly
and show
main
characterized
garnet,
massif
belt.
rocks
the GBG. The leucosome
allochthonous occured
in
mobile
an earlier
so far, the structural
analyses
Ghats
The migmatitic
a migmatitic
the
kinematics:
gneisses
with
published
were
the areas
different
of the
as asymmetric
is
metasedimenta’ry
series),
mesosome
megacrysts,
movement,
movement
and
fabrics,
WC and HC throughout
(khondalite
folds).
indicators,
asymmetric
boudinage
veins
and local shear zones),
area by
Harley, S. L. 1989. Geological Magazine Veilzeuf, D. and Montel, J. M. 1994. Mineralogy
Petrology
117,
375-393.
126,
215-247.
Contributions