Five days field report of Gilgit Baltistan .
Started from Mansehra then Besham then Kohistan then Gilgit and at last stop is in Hunza.
Visited dasu and basha dam.
each and every feature realed to geology is marked in this field report.
To understand the General Tectonic setting of Pakistan which includes all tectonic segments and the currently active convergent boundaries present in Pakistan
Geology and Petrography of Sandstone of Murree formation, Kuldana formation and Abbottabad formation Nakial and Dandli section sub Himalayas district Kotli, Azad Jammu Kashmir, Pakistan.
Plate tectonics, like crustal evolution, provides a basis for understanding the distribution and origin of mineral and energy deposits. Different types of ores are characterized by distinct geological environment and tectonic settings.
Kutch is an East-west Oriented pericraton Rift basin Situated between Nagar Parkar Fault in North and Kathiawar Uplift in South.
Here we will discuss Geology and its Sequence Stratigraphy.
GEOLOGICAL THERMOMETERS
DEFINITION AND CLASSIFICATION
Proper understanding of origin of mineral deposits and their classification requires the knowledge of formation-temperatures of these deposits. Certain minerals, present over there, give information’s with regard to temperatures of their formations and of the enclosing deposits and they are known as geological thermometers. These geological thermometers may be classed chiefly into the following groups based on their preciseness:
1. The thermometers that record fairly accurately the specific temperature condition of formation of deposits.
2. The thermometers that provide an upper or a lower temperature, above or below which the deposits do not form
3. The thermometers that provide a range of temperature within which the deposits form; and
4. The thermometers that serve as rough indications of temperatures of formation of mineral deposits.
The presence of two or more of less precise geological thermometers in a deposit narrows the range of temperature of formation for the deposits
To understand the General Tectonic setting of Pakistan which includes all tectonic segments and the currently active convergent boundaries present in Pakistan
Geology and Petrography of Sandstone of Murree formation, Kuldana formation and Abbottabad formation Nakial and Dandli section sub Himalayas district Kotli, Azad Jammu Kashmir, Pakistan.
Plate tectonics, like crustal evolution, provides a basis for understanding the distribution and origin of mineral and energy deposits. Different types of ores are characterized by distinct geological environment and tectonic settings.
Kutch is an East-west Oriented pericraton Rift basin Situated between Nagar Parkar Fault in North and Kathiawar Uplift in South.
Here we will discuss Geology and its Sequence Stratigraphy.
GEOLOGICAL THERMOMETERS
DEFINITION AND CLASSIFICATION
Proper understanding of origin of mineral deposits and their classification requires the knowledge of formation-temperatures of these deposits. Certain minerals, present over there, give information’s with regard to temperatures of their formations and of the enclosing deposits and they are known as geological thermometers. These geological thermometers may be classed chiefly into the following groups based on their preciseness:
1. The thermometers that record fairly accurately the specific temperature condition of formation of deposits.
2. The thermometers that provide an upper or a lower temperature, above or below which the deposits do not form
3. The thermometers that provide a range of temperature within which the deposits form; and
4. The thermometers that serve as rough indications of temperatures of formation of mineral deposits.
The presence of two or more of less precise geological thermometers in a deposit narrows the range of temperature of formation for the deposits
This report cover the field description of in and around Kutch area. the field objectives includes the brief study of tectonic evolution of Kutch rift basin by utilizing the Structural, Sedimentological and Palaeontological aspects of field.
This field provided the overall sense of structures & tectonics of Kuchchh area as well as depositional sedimentary environment. Here is the brief of the structures and fossils seen in the field:
Mechanical Structures – These structures are formed by various processes when the sediments were being deposited. They are also known as primary structures. Structures seen – Lamination, current bedding, cross bedding, graded bedding, ripple marks, sole marks, clastic intrusions.
Chemical Structures – These structures are formed by various chemical processes and are also known as secondary structures as they are formed after the deposition of the sediments.
Structures seen – concretionary structures (Iron Nodules, Shale Nodules), oolitic structures
(Dhosa Oolite), pisolitic structures.
Biological/ Organic Structures – these structures are imposed by various organisms, which include footprints of animals, self impression of plants, makings of insect tracks and trails,
fossilized wood, moulds and casts. These rocks are fossiliferrous as it contains some organic
structures and organisms in it. Structures seen: Stromatolitic Limestone, Silicified Wood, Burrows, Bioturbated Beds.
The San Sai oil field is an important oil field in the Fang Basin. The sedimentary facies and basin
evolution have been interpreted using well data incorporated with 2D seismic profiles. The study indicates that
the Fang Basin was subsided as a half-graben in the Late Eocene by regional plate tectonism. The deposit is
thicker westward toward the major fault. The sedimentary sequence of the Fang Basin can be subdivided into
two formations which comprise five associated depositional environments. The results of total organic carbon
content (TOC), vitrinnite reflectance (%Ro), Rock-Eval pyrolysis and headspace gas analyses and the study of
basin modeling using PetroMod1D software are compiled and interpreted. They indicate that source rocks of
kerogen type II and III with 1.78 – 3.13%wt. TOC were mature and generated mainly oil at 5,600 – 6,700 feet
deep (Middle Mae Sod Formation). Source rocks of kerogen type II and III with 2.07 – 39.07%wt. TOC
locating deeper than 6,700 feet (Lower Mae Sod Formation) were mature to late mature and generated mainly
gas at this level. According to TTI (Time Temperature Index) modeling using PetroMod11.1D software,
hydrocarbon generation took place in the Middle Miocene and the generated oil and gas migrated through
fractures and faults to accumulate in traps at 2,900-4,000 feet deep (Upper Mae Sod Formation).
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1. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 1
DEPARTMENT OF GEOLOGY
FIELD REPORT Gilgit Baltistan
1. Zeeshan Wahab
2. Munsif Ahmed
3. Zia ur rehman
4. Akhtar Pervaiz
5. Atta ul Munhim
2. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 2
REGARDS :
1) Zeeshan Wahab
2) Munsif ahmad
3) Zia ur rehman
4) Akhtar parvez
5) Atta ul munhim
Remember us in ur Prayers please.
Email: Zeeshanwahab1993@yahoo.com
3. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 3
Dedication
Dedicated to our beloved parents , respected teachers ,
all student of geology and finally our batch fellows.
5. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 5
ACKNOWLEDGEMENTS
All praise to Allah Almighty; who taught us with pen and Whose
Wonders we find all around us.
We feel highly privileged to express our deep sense of gratitude to our
teacher Sir Azeem and Sir Usman , Department of Geology , University
of Haripur, for skill guidance , kind , attitude, invaluable suggestions,
positive criticism and especially continual encouragement during the
completion of this field.
We are grateful to Mr. FAWAD , incharge of Department of Geology ,
for arranging this field .
Regards:
Zeeshan Wahab
Munsif ahmad
Zia ur rehman
Akhtar Parvez
Atta ul munhim
6. GEOLOGICAL FIELD REPORT 05/26/2015
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ABSTRACT
The study area of Gilgit – Kohistan is the Northern part of the Pakistan, we study area
along the KKH and Indus river geologically that area are very complex and highly
deformed areas having plats colloid zone and triple junction of the world three largest
mountain series.
Geotectonically there are many large and observable tectonics features in the area, main
suture zone, MMT, MKT, Triple junction, Kohistan island arc, syntaxes collision zone
of Indian and Eurasian plates.
Geomorphologically large number of alluvial fans, hot spring, flysh deposit, mollase
deposited, point bar, mid channel bar, meandering stream. Structurally small fold,
faults (rakaposhi) and fracture in rocks.
The project of Dasu dam and Bhasha dam studied along informative lecture with
respect to construction and engineering geology.
Petrology of different igneous (plutonic and volcanic), metamorphic and Meta sedimentary
rocks with their brief mineralogy and petrology.
Mainly there regionally geology having different types of rock complexes of igneous bodies
and also different grade of metamorphic rocks:
1) Mansehra granitic batholiths
2) Meta sedimentary rocks of Indian continent
3) Dubair granitic complex
4) Kohistan batholiths
5) Kohistan island arc rock
6) Besham complex rock
7) Chalt volcanoes
8) Yaseen group sediments and
9) Ortho / Paragnesis rocks
10) Thilichi group
11) Augen gnesis
8. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 8
Chapter : Introduction
Our six days field tour is conducted from 11_16 may 2015 to Kohistan- Gilgit areas
1ST
DAY: We started this special field work on 10:00 am (11 may 2015) from Haripur
University. At first day we work on different location along road side and at 9:30 pm we reached
to Besham continental hotel to spend the night, and then next early morning we continued our tour
from district Shangla towards Chillas.
2nd
DAY: On 2ND day
we work on 6TH
different location along the lecture of Dasu Dam project
geologist. On that day field work done at Besham city, lower and upper Kohistan district along
KKH and the end of the day at11:00 pm we reached to Shangrilla hotel .
3rd
DAY: The next day (3rd
) of our field start at 9:15am at the hotel with the lecture of Dr
Ihsanullah about Bhasha Diamir dam and then we start field work at 10:00 am at Chillas city
Babusar top and Jaglot area. We studied SEVEN different location rocks petrology and
mineralogy.
4th
DAY: The main Day 4TH
of field tour , we spend it in Gilgit Hunza area along KKH. We
work on 5 different location along KKH and reached to Hunza at 2:00pm then return from their
and reached to palace hotel at 6:00pm.
5th
DAY: The 5TH
day of our field spend it in travelling. The location of Diamir bhasha dam
seen there. We came back from gilgit to Besham and at 10:00pm we reached to Besham continental
hotel district shangla
.6th
DAY: It was the last day of field trip at 16 of May 2015 we start our field work from
Besham area . We studied different rocks at three different locations on the way we moving toward
Haripur. And finally we reached to Haripur about 3.30 pm evening, and taken the bags and went
to hostel.
10. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 10
Chapter : Literature review
For the studying igneous and metamorphic rocks this gilgit area is best. Because in this area the
igneous and metamorphic rocks are well exposed on the surface that’swhy we selected this
area and did field work on this area.we were not the first one who studied this area but more
people also did research on this place so I would like to itroduce some of them.
1. M. ASIF KHAN1, ROBERT J. STERN2, ROBERT F. GRIBBLE2 & BRIAN F. WINDLEY3 1Centre
for Excellence in Geology, Peshawar University, Peshawar, Pakistan 2Center for
Lithospheric Studies, University of Texas at Dallas, Box 830688, Richardson, TX 75083-
0688, USA (e-mail: rjstern@utdallas.edu) 3Department of Geology, University of
Leicester, Leicester LE1 7RH, UK
Work : Geochemical and isotopic constraints on subduction polarity, magma sources, and
palaeogeography of the Kohistan intra-oceanic arc, northern Pakistan Himalaya
2. R. A. KHAN TAHIRKHELI
Work : Geology of Kohistan and adjoining Eurasian and indo –pakistan continents
,Pakistan
3. A. K. Jain* Central Building Research Institute, Roorkee 247 667, India
CURRENT SCIENCE, VOL. 106, NO. 2, 25 JANUARY 2014 254
*e-mail: himalfes@gmail.com
Work : When did India–Asia collide and make the Himalaya ?
Keywords: Batholith, collision of plates, intra-oceanic islands arc, lithosphere
12. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 12
CHAPTER : Field description
Day 1
Stop 1:
Co-ordinates:
(N=34°31′ 58.3″, E=73° 10′ 57.8″ )
Elevation = 1267m
Locality: Ahal ( Mansehra )
Rock Observed:
Granodiorite
Detail observation:
It is the part of Mansehra granitic batholith, it does not mean that granitic
batholith have only granite but it consit of granodiorite,quartzite etc. On this stop we study
three different lithology’s 1) Granodiorite 2) Granite 3) Black intrusion of biotite . Foliation,
folding and crushed material is observed, it is due to the tectonic activities (like movement
occour ) structures are disturbed and extensive foliation and folding occour . It is also called
oogi shear zone, fault zone , crush zone and fault swamp.
As we know granite is hard rock but if we see crushing, it shows us that force is so high. The
above all these activities is due to the Himalaya orogeny (25-30 Mya), so some worker called it
MCT. MCT (main central thrust ) separate highly metamorphose rock from less deformed rock
(higher Himalayas from lesser Himalayas).
In Pakistan, no evidence found of MCT . In oogi shear zone some geologist called it MCT, but
the oogi shear zone is combined with Batal fault ( in kaghan ) and its age is not same as the MCT
age. There are ten more places which different geologist says that it eas MCT. So conclusion is
that it have controversies in MCT.
13. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 13
Stop 2 :
Locality : Ahal area
This is the main locality for shear zone ( oogi shear ). Crush material ( granite ) is seen from right
side of road .
14. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 14
Stop 3:
Co-ordinates :
(N= 34° 37′ 34″ , E= 73° 5′ 50″ )
Elevation= 1497m
Locality: near Chatter plane ( Sharkool )
Rock Observed :
Orthogneisses
Detial Observation :
Before this area slate like lithology seen on raod side which was Tanawal
Quarzite. Then we moved toward north approaching to suture zone. White and dark band
aligned which are gneisses. The garnet rock now converted into gneisses so called it
Orthogenesis . We called it Orthogneisses because of texture we identify it’s parent rock. The
plutonic rock is coarse grain and sedimentary rock are very fine grain .
GRANDIORITE > CONVERT to > GNEISSES
We observed fracture, veins , joints in the formation . Dark colour is because of weathering and
fresh surface is of white color . It is very lose material, break down easily.
15. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 15
Day 2
Stop 1:
Co-ordinates:
( N=34° 65′ 39.6″, E=72° 52′ 34.96″ )
Elevation = 603m
Locality: near Besham city ( left side of the bridge )
Rock Observed :
Rocks of Besham complex.
Detail Observation:
As we know besham group rocks are very high grade metamorphic rock. All are
pre Cambrian shield rock first and after then metamorphosed . Here we observed Graphite
schists which is black in colour and consist of iron and Quartz veins , also intrusion of granite
(Aplite ) and also observed Paragneisses and meta Conglomerate . All are different Gneisses
( ortho and para ) . In this area rock of gneisses , white band material is not found or too low
because this was mafic rock ( mafic mineral high ) . Metamorphism in this is before from
Himalayas . The recent metamorphism blind the older metamorphism .
16. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 16
Stop 2:
Co-ordinates:
( N= 34° 57′ 34.3″ , E= 72° 52′ 48.16″ )
Elevation= 758m
Locality: After Besham ( along indus river , 1 or 2 hour away from besham).
Rock Observed:
Paragneisses
Detail observation:
Our main objective on that stop was mapping , so we developed the map of that
area which was attached in chapter ( ) and their we explained it in detail.
We observe metamorphic rock , it was a part of besham complex . From there we collect rock
of Paragneisses , which was quartz enrichment and have mica in it. Greenish colour is quartz
and back is mica’s biotite.
Sedimentary rock > metamorphosed > Paragneisses
17. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 17
Stop 3:
Co-ordinates:
( N= 35° 02′ 19.6″ , E= 72° 54′ 03.1″ )
Elevation= 717m
Locality: Dubair area
Rock Observed:
Granodiorite
Detail observation:
Because of too much rain, we did not observed clearly this rock ( granodiorite).
As we know grandiorite is a medium to coarse grained intermediate to acid igneous rock with
essential mineral quartz, plagioclase and feldspar.
18. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 18
Stop 4 :
Co-ordinates:
( N= 35° 2′ 40.5″ , E= 72° 56′ 37.9″ )
Elevation= 936m
Locality: Jijal
Rock Observed:
Igneous rock
Detail observation:
We observed the rock it was green in colour , mineral like pyroxene and
olivine is present we called it ultramafic rock . It may be observed at thin section that either It is
peridotite rock or dunite rock.
This is the area of Jijal complex area . From this area Kohistan Island arc sequence are started.
In this area MMT is present but for this we have search for it . MMT is thrust fault between
Indian plate and Kohistan Island arc . This area is basically ophilitic zone.
19. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 19
Stop 5:
Co-ordiantes:
( N= 35° 42′ 28.86″ , E= 72° 57′ 28.6″ )
Locality: Chanchal area
Rock observed:
Granulite
Detail Observation:
Basically, Gabbro (mafic rock) metamorphose and granulite developed.
A granulite is a fine to medium rained metamorphic rock. Granulite typically contain amphibole
, quartz , feldspar, and pyroxene with very little or no mica. We observed the brownish mineral
which is garnet , the green colour is weather colour produce due to serpentinization.
20. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 20
Stop 6:
Locality: Dasu area
Objective :
We stand on the left side of the indus river near dasu hydro project. Our main
objective on that stop was to study about the dam construction, mapping and thing related to
engineering geology .We discussed it on chapter no ( ).
DAY 3
Stop 1:
Locality: Shringrilla hotal ( Chilas).
21. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 21
Objective:
In this hotal senior geologist IHSNA ULLAH guide us on Dammer Basha Dam project. The
detail was given in chapter no ().
Stop 2:
Co-ordinates:
(N= 35° 25′ 42.7″, E= 74° 6′ 31.2″ )
Elevation: 1064m
Locality: near Chilas area
Objeactive :
The main objective of this stop is study the Geomorphology of the area, here we observed the
effect of ice age, glacier deposits, ancient channel, non-conformity and the Aeolian deposit.
We further explain it in detail in chapter no ( ). The second objective of that was to draw the
sketch of outcrop.
.
22. GEOLOGICAL FIELD REPORT 05/26/2015
Page | 22
Stop 3:
Co-ordinates :
( N= 35° 24′ 34″ , S= 74° 8′ 48.6″ )
Elevation= 1051m
Locality: Babu sar top , Gilgit Baltistan police check post
Rock Observed:
Gabbroic rock, Dunites, Pegmatite veins, hornbendite.
Detail Observation:
1) Gabbro is dense, greenish or darker colored and contain pyroxene,
plagioclase, and minor amount of amphibole and olivine . In gabrro
black amount of mineral is high , it is mafic in origin .
2) Dunites, all minerals are olivine , small amount of pyroxene( greenish
colour) . Grains are vitrous . In dunite , some time green colour is due to
serpentinization.
3) Pegmatite viens , have black hornblende mineral.
4) Hornblendite rock , In this hornblend mineral amount is high . It is the
part of Chias complex .
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Stop 4:
Co-ordinates:
( N= 35° 28′ 0″ , S= 74° 33′ 6.06″ )
Elevation= 1190m
Locality: Tatta pani
Observation:
We observed here the hot water spring. The theory behind this is nanga parbat , in
which younger granet intruded and due to the presense of hot chambar the water is hot , and
comes out of surface in the form of HOT SPRINGS. Hot spring is also the clur of Fault.
Researcher says that Nanga parbat made on MMT and they have Rikot fault and because of the
movement of the fault , fracture produced ant the water along this becomes hot . So it is called
as Hot spring of Tatta pani.
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Stop 5:
Locality: Thelechi area
Rock Observed:
Schist/Phyllite
Detail Observation:
We observed Phyllite,,, and in some places schist is present . Grains of this
was not seen , because it was fine grain. It was basically sedimentary rock and they
metamorphose and convert to phyllite/schist. It was the part of Jaglot group.
Jaglot group have different type of meta sediment. It have turbiditic sequence like Shist-
Phyllite, Shist-phylite. In Kohistan island arc sediments were deposit in Back arc and after then
because of collision they metamorphosed. In this area igneous intrusion occur i.e Kohistan
batholith intrude. In this stop rock are the Thelitic formation, which is a part of jaglot group.
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Jaglot group include Thelitic formation, Chalt volcanic formation and gilgit formation.
Stop 6:
Co-ordinates:
( N= 35° 39′ 55.8″ , E= 74° 37′ 0.6″ )
Elevation= 1305m
Locality: Jaglot area
Rock Observed:
Gabbro rock and diorite dikes
Detail Observation We observed gabrro and diorite dikes . The dike is a grey to dark grey
intermediate intrusive igneous rock composed of feldspar , biotite , hornblende and pyroxene.
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Stop 7:
Co-ordinates:
( N= 35° 44′ 9.6″, E=74° 37′ 20.6″ )
Elevation= 1371m
Locality: stop at Thriple Junction
Rock Observed:
Aplite
Detail Observation:
We observed fine grain material of granite which was aplite. Intrusion occur in
granitic rock which is younger then Kohistan batholiths . Mafic rock like gabbro intrusion occur.
In this stop three mountains joints together i.e Himalayas , hindukush and karakoram. That’s
why it is called thriple junction. At this stop we observed that Gilgit river meets with Indus river.
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Day 4
Stop 1:
Co-ordinates:
(N= 35° 59′ 27.5″ , E= 74° 19′ 32.9″ )
Locality: Jutal area
Rock Observed:
Diorite
Detail Observation:
We observed diorite rock in which we saw feldspar, biotite, hornblende .
This diorite rock was grey to dark-grey intrusive igneous rock. In some place basic dike and
intermediate dike was observed , 75 million years ago the veins intruded. We observed the
olivine rich rock known as dunite, dunite is as igneous plutonic rock of ultramafic composition.
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Stop2:
Locality: Nomal area
Objective:
The main objective of that stop was to observed the geomorphology of the area, it
have very complex geomorphology which we discussed in chapter ( ) . This area was still in
KIA.There we saw that all gilgit and nearby area are located on Fans as shown in figure.
Stop 3:
Co-ordinates:
( N= 36° 10′ 2.06″ , E=74° 17′ 6.4″ )
Elevation= 1671m
Locality: Jacot Village
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Rock Observed:
Meta- Basaltic rock
Detail Observation:
We observed volcanic rock ( basaltic rock) which was of dark colored, fine
grain igneous rock . It is most commonly form as an intrusive and extrusive , such as lava flow.
We also observed pillow basalt on right side of the road . Pillow basalt developed at the time of
extension in that area because pillow basalt erupts underwater or flows into the sea and form
pillow like structure. We also observed green schist facies, the green color is due to the mineral
chlorite and epidote mineral it is medium pressure and temperature facies. Greenish color
because of very low grade of metamorphism ( like green schist).
Stop 4:
Locality: Chalt valley (Sikandarabad)
Rock Observed:
Meta-sediments rock
Detail Observation:
It is the collision point of Indian and Eurasian plate. Nearly 50 to 55 million
year ago the two continental plates collide at this junction such as the Indian plate and Eurasian
plate. The tremendous amount of pressure created causes Earth crust to buckle producing large
horizontal and vertical displacement and producing these mountains of the Karakorum. The
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Indian plate is still moving towards north into the Eurasian landmass at about five centimeters a
year causing the mountains to raise about seven millimeters annually. The collision is shown in
the figure.
Stop 5:
Co-ordinates:
(N= 36° 4′ 15.76″ , E= 74° 19′ 35.3″ )
Elevation= 1833m
Locality : Near nagar college
Rock Observed:
Phyllite rock ( meta-sediment )
Detail Observation:
Here we observed meta-sediment rocks which was phyllite , and it was the
part of yaseen group , these rocks can break along cleavage . Yaseen group consist of meta-
sediment rocks. When yaseen group end and igneous rock start , researchers mark it MKT.
Flysch sediments metamorphose , it is Quartzite or Marble ???? It can be observe from HCL. It
was the last part of KIA.
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Stop 6:
Locality: Hunza
Objective:
The main objective is to visit hunza city. Due to our bad luck, the whole city was
closed because of Saniha Safoura (death of 45 Ismailia’s peoples in Karachi), so we come back
after spending a short time in Hunza.
Day 5
Stop 1:
Locality: Near Diamer Basha dam
Objeactive:
Our main objeactive ot that stop was to conduct site investigation information of the
dam but due to visiting of Chief Justice of Pakistan to this area , we only spend 7 mints in this
area. We discussed it in detail in chapter ( ).
Day 6
Stop 1:
Co-ordinates:
(N=34° 52′ 11.3″ , E= 72° 55′ 24.5″ )
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Elevation= 617m
Locality: Near Besham
Rock Observed:
Meta-sedimentary rocks with granitic intrusion.
Detail Observation:
This is basically the part of the Besham complex . It was high weathered zone.
Intrusion in some zone occur . Grain size too low . White rock is igneous rock . Weather zone ,
minerals formed because of weather called weather minerals. Brown color is because of iron.
May be this meta-sedmntary rock is Quartzitic rock.
Stop 2:
Co-ordinates:
(N= 34° 50′ 47.6″ , E= 72° 58′ 28.8″ )
Elevation= 717m
Locality: Near Takhot Bridge
Rock Observed:
Graphitic Schist
Detail Observation:
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Parent rock of Graphitic schist is sedimentary. All are meta sedimentary
rocks. Graphitic schist developed , mark Takhot fault. It is the pre-cambrian rock sequences.
Stop 3:
Co-ordinates:
(N= 34° 41′ 7.1″ , E= 72° 59′ 23.4″ )
Elevation= 962m
Locality: Near batagram
Rock Observed:
Orthogneisses
Detail Obsrvation:
In this igneous rock AUGEN structure is developed. It is the part of
Mansehra batholith . In this we observed non foliated minerals. Parently homogenous material
present in igneous.
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CHAPTER: geomorphology
DAY 3.
Stop 2:
LOCATION : NEAR CHILAS BAZAR
GEOMORPHOLOGICAL FEATURES OBSERVED:
Mostly glacial deposits of Pleistocene age were seen because
there was no sorting seen in field , different sizes of grains (mix-up of material) were observed
due to debris flow .mostly moraines deposits are seen. Some sand ridges also seen which were
formed due to wind (wind deposit).Some sorted grains (LENSES) were also seen which formed
in the result of melting of glaciers and stream flow. Loose material also observed. This is also
called Jalipur sediments.
Stop 4:
LOCATION : TATTA PANI
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Geomorphological observation:
We observed in this area hot spring called tatta pani. The
cause of hotness of this spring is due to deep seeded water and fault and spring were formed
due to Raikot fault. Raikot fault is basically strike slip fault and its also called tranpressional
fault.
OLD CONCEPT ABOUT TATTA PANI:
The old concept is that there were youngest granitic rocks of Nanga Parbat so there could be
the magmatic chamber trough which this water passed and became hot. Nanaga parbat
syntaxes is the part of MMT.
DAY 4
Stop 2:
LOCATION: NOMAL VILLAGE
Geomorphological observation:
We seen in this stop the following geomorphological features:
Point bar :(is a depositional feature made of alluvium that accumulates on the inside
bend of streams and rivers below the slip-off slope)
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Flood plain : It is an area of land that is prone to flooding. People realize it is prone to
flooding because it has flooded in the past due to a river or stream overflowing its
banks)
Alluvial fans: It is a fan- or cone-shaped deposit of sediment crossed and built up
by streams. If a fan is built up by debris flows it is properly called a debris
cone or colluvial fan. These flows come from a single point source at the apex of the
fan, and over time move to occupy many positions on the fan surface. Fans are typically
found where a canyon draining from mountainous terrain emerges out onto a
flatter plain, and especially along fault-bounded mountain fronts)
Bajada fans: A bajada consists of a series of coalescing alluvial fans along a mountain
front. Thesefan-shaped deposits form from the deposition of sediment)
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Chapter :Engineering Geology
Diamer-Bhasha Dam
The lecture was delivered by 4 geologist senior geologist, ihsan ullah guide us on diamer bhasha
dam.
Features of diamer –bhasha dam
LOCATION: The Dam will be located on the River Indus in Northern Pakistan, about 315
km upstream of Tarbela Dam, 165 km downstream of the Northern Areas capital of Gilgit and 40
km downstream of Chilas.
DamType Roller Compacted Concrete (RCC)
MAIN DAM Maximum Height: 270 m
DIVERSION SYSTEM 2 No. Diversion tunnels 1 No. Diversion canal Upstream and
Downstream Cofferdams
MAIN SPILLWAY No. of gates 9 Size of gate
RESERVOIR LEVEL 1160 m Gross capacity 7,300,000 acre feet (9.00×109 m3) Live
capacity 6,400,000
POWERHOUSE(S) 2 underground powerhouse Total installed capacity 4500 MW Location
and type Toe of the Dam (one each on the right and left side)
ESTIMATED COST (YEAR 2008) US$12 Billion
Total Installed Capacity: 4,500 MW
In intial investigation stage four adit were developd to know the lithology ,sub surface geology
and to know about fault.
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DASU HYDROPOWER PROJECT
The lecture was delivered by moheen ud din and habeeb shah
Dasu Hydropower Project is a run of river scheme located 7 km upstream of Dasu village on
Indus River, 74 km downstream of Diamer Basha Dam and 350 km from Islamabad. The Project
is located in District Kohistan of Khyber Pakhtunkhwa
Features of dasu dam:
Type of dam Gravity, roller-compacted concrete
Height 242 m (794 ft)
Length 570 m (1,870 ft)
Total capacity 14,100,000,000 m3(11,400,000 acre·ft)
Installed Capacity (MW) 4320
Type of Dam RCC
Dam Height (m) 242
Construction Period (Years) 18 (in four phases
Power house underground
Reservoir length
73km
We find out Rqd value which is 100
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CHAPTER : Tectonics
Regional geologic setting
The Indian Plate margin:
The Indian Plate margin The northernmost parts of the Indian continent crop out between the Main
Boundary Thrust (MBT), to the south, and the Indus Suture to the North. Northern metamorphic units
and a southern, fold-and-thrust sedimentary belt constitute the so-called Lower- (or Lesser-) Himalaya
of Pakistan (Chaudhry et al. 1997). Altogether, it is a low-grade assemblage of a 20 km thick, imbricate
thrust pile of Mesozoic sequences originally deposited on the Indian continental crust represented by
mid-Proterozoic and Paleozoic gneisses and sediments. Cambrian stromatolitic dolomites record the
epicontinental marine transgression on 1.5 - 2.2 Ga old remobilised gneisses. Around 500 Ma old
granitoids, which have been deformed into orthogneiss (Le Fort et al., 1980, Anczkiewicz 1998, DiPietro
& Isachsen 2001), record the widespread magmatic event of that time, which is documented on all
Gondwana-derived continental blocks.
Much of the Phanerozoic shelf sequence (shales, sandstones and limestones) is of Gondwana type,
starting in the Middle-Paleozoic. Early-Permian magmatic ages of metabasaltic dikes and granitegneiss
intrusive into older Indian gneiss are evidence of pervasive magmatism during rifting , which is
associated with the break-up of Gondwana. Rifting produced a suite of alkaline intrusions, including
carbonatites .Sedimentary records indicate that the onset of extension tectonics is Early Carboniferous .
Marine shelf sedimentation was re-established in the Late Triassic. The Mesozoic sedimentary history is
that of carbonates deposited during thermal subsidence of a continental margin, on the southern side of
Neo-Tethys. All these rocks were deformed and metamorphosed between 75 and 40 Ma . Subduction of
at least parts of the Indian craton to depths equivalent to 27-32 kbars at ca. 50 Ma is indicated from the
occurrence, in the Kaghan Valley, of coesite-bearing eclogites likely derived from basaltic Permian dykes
. Thermochronologic studies suggest that before 13 Ma most of the Lower Himalaya rocks were located
Figure 2 - Satellite overview of the area crossed by the field trip.
A GEOLOGICAL TRANSECT FROM THE INDIAN PLATE TO THE EAST HINDU KUSH, PAKISTAN
PR01
5 - PR01
Volume n° 1 - from PRO1 to B15
either beneath a paleo-foreland basin or beneath Main Central Thrust (MCT)-related nappes. Molasse
conglomerates siltstones and shales (termed Siwalik or Sub-Himalaya sediments) lap onto the Indian
Shield. In detail the discontinuous series comprises most of the Cenozoic but there was a general lack of
sedimentation during the Late Eocene and almost the entire Oligocene. This unconformity of 15-20 Myr
may refl ect an important change in orogenic processes. One interpretation involves the passage of a fl
exural forebulge migrating southward through India. Late Oligocene to Early Miocene fl uvial formations
record the emergence of the Himalaya Mountains. The Kohistan Island Arc Complex: Outline The
44. GEOLOGICAL FIELD REPORT 05/26/2015
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Kohistan terrane in NE Pakistan (Fig. 3) is regarded as a fossil island arc obducted between the collided
Indian and Asian plates (Bard et al. 1980, Tahirkheli et al., 1979). Owing to the admirable quality of
exposures, the Kohistan offers an unrivalled opportunity to investigate the structure of an island arc and
related subduction processes (Bard 1983, Searle et al., 1999, Treloar et al., 1996). In particular,
numerous time markers in the form of intrusive bodies make the Kohistan an exceptional place to study
the signifi cance of magmatic structures in the deep crust of an arc system.(Fig.3)
The Kohistan sequence displays a structurally coherent section of an island arc terrane, comprised of a
30 to 40 km thick section of metamorphosed, plutonic, volcanic and sedimentary rocks. This succession
is interpreted as plutons intrusive into an oceanic crust and overlain by the calc-alkaline lavas and
associated sediments. Accordingly, the interpretation is an intraoceanic arc that developed during the
Cretaceous through a north-dipping subduction in the equatorial area of the Tethys Ocean (Yoshida et
al. 1996). Six main rock assemblages from north to south, i.e. downward sequence, are present. UPPER
CRUST Upper crustal sequences pertain to two geographically distinct domains. - Just south of the
Northern Suture, they consist of interlayered volcanoclastic sediments, volcanites and rather immature
turbidites deposited in a deep-water environment. Sediments (so-called Yasin Group) are shales,
graywackes and volcanoclastic rocks form a probable back-arc basin of Cretaceous age. They grade
upward into fi ne grained shales and tuffs and contain limestones with an Albian-Aptian fauna (Pudsey
et al. 1985). Volcanites (Chalt Volcanites) are calc-alkaline andesites to rhyolites succeeding to andesitic
lavas, tuffs and agglomerates of Early Cretaceous age. Exceptionally well-preserved pillow lavas are
primitive island-arc-type, tholeiitic lavas that possibly represent part of an ophiolite assemblage
obducted during the Kohistan-Asian collision. The size of this oceanic back arc basin (with respect to the
Kohistan) is conjectural. - To the Southwest and within the Kohistan Complex, metasedimentary
sequence of deep marine origin (Dir, Utror and Kalam Groups) yielded Eocene fossils in upper-level
limestones. Depositional models point to rapid subsidence in Paleocene times in an extensional,
restricted basin. Associated volcanic and volcanoclastic series are calc-alkaline basalts, basaltic andesites
and andesites, emphasising an arc environment (Sullivan et al. 1993). PLUTONIC CRUST Kohistan
batholith: is a name that gathers intrusive calc-alkaline granitoids. The fi rst plutonic stage is dated at ca
105 Ma. Stages 2 and 3 are dated between 85 and 26 Ma. Stage 1 and early stage 2 plutons have
isotopic signatures characteristic of a mantle derivation. The isotopic signatures of younger plutons
show evidence of an increasing crust to mantle ratio, with the latest magmas being entirely crustally
derived. This evolution is interpreted as the result of arc thickening and lower arc melting following
suturing to Asia .
Gabbronorites: a massive body of locally layered gabbronorites marks the axis of the arc. It is the more
than 8 km thick and 300 km long Chilas complex thought to be a layered magma chamber intruded into
the arc in Cretaceous times. In detail, it is a stratiform complex of norites, noritic gabbros and a string of
lenses of diverse ultramafi c-mafi c-anorthosite (UMA) association. The UMA represent apices of intra-
arc mantle diapirs that served as porous fl ow conduits to feed the gabbro-norite.
The gabbro-norite cooled and equilibrated at 600-800°C and 6-8 kbar. A Sm-Nd internal isochron yields
an age of c. 70 Ma, consistent with the conventional zircon U-Pb age of 84 Ma (Schaltegger et al. 2002).
45. GEOLOGICAL FIELD REPORT 05/26/2015
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Leaders: M. Gaetani, J.P. Burg, A. Zanchi, Q.M. Jan PR01
Figure 3 - Structural sketch map of the Kohistan Island Arc Complex.
A GEOLOGICAL TRANSECT FROM THE INDIAN PLATE TO THE EAST HINDU KUSH, PAKISTAN
PR01
7 - PR01
Meta- gabbros to tonalites: (so-called Kamila amphibolites) form a thick pile of imbricated calcalkaline
laccoliths variably sheared in amphibolite facies conditions. Small inliers of metasediments and
metavolcanic rocks screen these laccoliths and rare granites belong to the plutonic association. Few
intrusion ages are available. They span from 99 to 82 Ma, giving evidence for a succession of short-lived
plutonic events; 82 Ma-old rocks are kyanite-bearing pegmatites produced by partial remelting of
deeper lithologies in the arc . ArAr cooling ages on hornblendes cluster around 80 Ma, hence providing
evidence that this part of the Kohistan island arc complex was cooled below c. 500°C in the Late
Cretaceous (Treloar et al., 1989). Shear strain localisation took place continuously from magmatic
emplacement to solid state deformation during cooling of the gabbroic and dioritic plutons, between
100 and 83 Ma (Arbaret et al., 2000). The related shear strain probably represents arc-related
46. GEOLOGICAL FIELD REPORT 05/26/2015
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deformation during subduction of the Tethys oceanic lithosphere below the Kohistan Arc Complex.
MANTLE The so-called Jijal-Patan Complex, is composed of more than 3 km thick ultramafi c rocks
overlain by garnet-plagioclase granulites. Garnet- and plagioclase-free peridotites and a few pyroxenites
dominate the lowest section. The Jijal peridotites represent the sub-arc mantle (Burg et al., 1998). The
sharp contact between the ultramafi c rocks and the overlying granulites, with well-preserved igneous
structures, is the intrusive contact of lower crustal, calc-alkaline garnet-gabbros (the granulites) within
mantle rocks (Burg et al., 1998). The contact is also the lower boundary of the arc crust, i.e. the arc-
Moho. In the granulitic gabbro, metamorphic overprint essentially marks isobaric cooling within
granulite facies conditions (starting T > 1150°C at depth > 50 km although early metamorphic pressures
may have increased. The granulitic gabbros have later re-equilibrated at >700°C and 15 + 4 kbar, which
are pressure conditions similar to those calculated from the underlying ultramafi c rocks (Ringuette et
al., 1998). Sm-Nd isochrons at c. 95 Ma date cooling and provide the minimum age of the Jijal ultramafi c
sequence (Anczkiewicz & Vance 2000, Yamamoto & Nakamura 2000). Arc splitting The calc-alkaline
Chilas norites and noritic gabbros were fi rst interpreted as having crystallised in the
sub-arc magma chamber (Bard et al., 1980). Later geochemical analyses suggested that it was generated
by intra-arc rifting and subsequent mantle diapirism (Khan et al., 1993). The latter interpretation is
consistent with the gabbro-norites having intruded volcanic and sedimentary components of the arc.
Petro-structural observation supportively suggests that the ultramafi c-mafi c-anorthosite associations
occurring as a string of lenses over the >300km length of the gabbro-norite represent apices of intra-arc
mantle diapirs that served as porous fl ow conduits to feed the gabbro-norite (Burg et al., 1998).
According to the zircon U/Pb age of gabbronorites, rifting is about 85 Ma old (Schaltegger et al., 2002).
The Chilas suite of mantle diapirs points to splitting of the Kohistan arc, with initial rifting taking place at
the island arc as documented in modern island systems (e.g. Rocas Verdes). The UMA outcrops point to
mantle diapirism as a key mechanism in opening back-arc basins between a volcanic and a remnant arc,
the latter perhaps now seen as rocks screening the Kohistan Batholith. Obduction - metamorphic record
The Kohistan Arc and India were assembled during closure of Tethys, which produced thrusting along
the Indus Suture. Within the Suture, a discontinuous but up to 20 km wide zone of imbricated ophiolites,
greenschists and blueschists is locally referred to as “mélange unit”. It is a dominantly fore-arc related
assemblage obducted onto the Indian plate (Anczkiewicz et al. 1998). In the footwall, the geology of the
northern margin of the Indian plate is remarkably uniform. However, two highpressure metamorphic
events have accompanied the India-Kohistan convergence: blueschist facies metamorphism at ca. 80 Ma
is linked to oceanic subduction, eclogite facies metamorphism at ca. 50 Ma is linked to continental
subduction. PRE-COLLISION EVENTS Blueschists imbricated within the suture between India and the
Kohistan Arc yielded 40Ar-39Ar and Rb-Sr, phengite and Na-amphibole ages at ca. 80 Ma and thus
record a pre-collisional, Early/Late Cretaceous metamorphism during subduction of the Tethys oceanic
lithosphere (Anczkiewicz et al. 2000). Rapid exhumation and cooling of these highpressure metamorphic
rocks probably took place in an accretionary prism system dominated by corner fl ow processes.
Volume n° 1 - from PRO1 to B15
PR01 -
Leaders: M. Gaetani, J.P. Burg, A. Zanchi, Q.M. Jan PR01
47. GEOLOGICAL FIELD REPORT 05/26/2015
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COLLISION-RELATED EVENTS Collision with India developed Barrovian metamorphism in the Indian
sequences. U-Pb ages of syn-metamorphic granites and Nd-Sm ages of eclogites indicate that at about
50 Ma the northern margin of India was deeply buried and being metamorphosed in high-pressure
conditions (Spencer et al. 1995). Ar/Ar mineral ages of the metamorphosed sequences on the Indian
plate give cooling ages of hornblende at 38 Ma and muscovite cooling ages of 30 Ma (Treloar et al.
1989). The metamorphic and related structural fabrics in these rocks, therefore, record an important
part of the collisions and the fi nal emplacement of the Kohistan Arc against this segment of the Indian
plate. The post-Eocene thrust directions generated complex, refolded thrust patterns, large slab folding
and rapid uplift with associated brittle faulting and seismic activity. No signifi cant movement has taken
place along the Indus Suture since 20 Ma, as indicated by similar fi ssion track ages on both sides of the
Suture (Zeitler 1985). The North-Kohistan Suture Zone The North-Kohistan Suture marks the fault
contact between the Karakoram margin of the Eurasian Plate, to the North, and the Kohistan Paleo-
Island Arc Complex, to the South. The North-Kohistan and Indus Sutures were two branches of the
Neotethys Ocean and, as such, are western continuations of the Tsangpo Suture, in southern Tibet. As
such the North-Kohistan Suture Zone eastward becomes the Shyok Suture, which separates the Ladakh
Arc from the Karakoram. It has been inferred that the North-Kohistan Suture closed in the Late-
Cretaceous on the basis of two arguments. 1) Undeformed subalkaline plutons of Eocene age are found
on both sides of the Suture (Debon et al., 1987, Coward et al., 1987) and 2) pillow lavas next to the
suture were deformed before intrusion of a 75 Ma old, mafi c dyke, (unpublished Ar-Ar age on
hornblende by D. Rex, in (Petterson & Windley 1985) and mean age despite excess Argon in (Treloar et
al., 1989). However, a signifi cant amount of the Karakoram granitoids is 25 Ma old, or younger (Debon
et al., 1986, Parrish & Tirrul 1989). (Brookfi eld & Reynolds 1981) and (Reynolds et al., 1983) suggested
that the eastern continuation of the North-Kohistan Suture, the Shyok Suture in India, did not close
before the Miocene. The age of this closure remains unsettled, probably because suturing involved
multiple events. In Pakistan, early geological information is due to (Desio 1964, Desio & Martina 1972).
The suture zone turns from its SW-NE trend, along the western Kohistan boundary to nearly E-W along
the northern boundary (Fig. 3). The North-Kohistan Suture is described as a mélange containing blocks
of serpentinite derived mostly from harzburgites, greenstones derived from both volcanic and
volcanosedimentary formations and sediments that include limestones, red shales, conglomerates and
quartzites in a turbiditic, slate-dominated matrix (Pudsey et al. 1985a, Pudsey 1986). The “mélange”
separates volcanic and sedimentary rocks of the Kohistan Arc Complex, to the south, from shelf
sediments of the Karakoram to the north. The so-called mélange is a 1-7 km wide imbricate zone in
which slices with well-defi ned lithologies are bounded by a series of anastomosing, brittle faults that
have faulted away the original suture . Sinistral faults with a minor reverse component dominate the
western segment. The reverse component is more important along the E-W segment. North and south
vergent structures are found on both sides and within the suture. The North-Kohistan Suture Zone
displays polyphase deformation. At least three ductile deformation events have been recognised,
represented by (1) the stretching lineations in conglomerates and marbles, (2) curved fold axes in green
schists and (3) crenulation lineations in black schists and slates. Brittle deformation is principally
represented by recent sinistral strike-slip faulting with the reverse component. In the Drosh area, to the
west youngest fi ssion track ages on apatite and zircon from the north of the suture, are 11 Ma and 20
Ma, respectively. They are 13Ma (apatite) and 20Ma (zircon) south of the suture. Similar apatite ages on
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both sides of the suture show that the rocks on either side passed the apatite partial annealing zone
together, around 1113Ma; accordingly, no or little vertical differential movement has taken place along
this fault zone since the late Miocene. No high-pressure rocks have been found along the North-
Kohistan suture whose real markers are therefore the serpentinites considered to derive from the
Neotethys oceanic lithosphere (oceanic back-arc basin?). The systematic organisation of the lithologic
slices, which may represent a reactivated accretionary prism, leads to redefi ne the main lithological
units according to their presumed tectonic origin. This classifi cation is tentative and thus must be
considered
A GEOLOGICAL TRANSECT FROM THE INDIAN PLATE TO THE EAST HINDU KUSH, PAKISTAN PR01
9 - PR01
Volume n° 1 - from PRO1 to B15
with caution or even suspicion, in particular because of the lack of ages. Neotethys rocks The North-
Neotethys Ocean lithologies are composed of low-grade pelagic to hemipelagic sediments, banded
cherts, pillow lavas, calcschists, black shales, serpentinites and talc-magnesite schists derived mostly
from harzburgites. However, no typical ophiolitic sequence has been recognised. Serpentinites occur
either as massive lenticular and fault-bounded blocks or (mainly) as thin schistose shreds along major
faults. Gabbros have locally intruded serpentinites. The meta-ultramafi c rocks locally occur as talc-
magnesite felsen and schists, indicating circulation of CO2 fl uids within the suture fault system. The
mineral parageneses indicate greenschist facies metamorphism. North Kohistan rocks The northern
margin of the Kohistan Arc comprises greenschist-facies basaltic and andesitic volcanites, volcanodetritic
and shelf-type sediments that overlie turbiditic red shales, sandstones and conglomerates,
and the calc-alkaline mylonitic gabbros and amphibolitic metavolcanodetritics of the Kohistan Batholith.
Pebbles in low-grade red conglomerates are elongated, hence defi ning a stretching lineation with
variable directions. Fossiliferous (rudists, orbitolinoids) reef-limestone sequences occur within green
basaltic to andesitic volcanites (Pudsey et al., 1985b). It is not clear yet, whether this unit, squeezed
within the suture zone, derived from the Karakoram or Kohistan terrane, or both.
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NOTE :
Reader must consult with teachers ,with own observation, with
Books , Class lectures , and additional material apart from this report.
Zeeshan Wahab is not Responsible for any MISHAP!!!!!
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