Aras Geopark


Proposed Aras Geopark is located in eastern Azerbaijan Province of Iran. The Geopark has an area of about 1670 square kilometers and spread across the whole Jolfa county.

From a natural geographical view, this mountainous area is the southern end of little Caucasus that encompasses countries include Armenia, Nakhchivan Autonomous Republic and northern Azerbaijan of Iran. This mountain alongside with Alborz and Zagros are forming middle part of Alpine-Himalayan Orogeny that stretches from southern Europe to eastern Asia and acting as a natural barrier, caused a great diversity in climate, life and cultures in each two sides slopes.

 The main source of precipitations is the Mediterranean wet air fronts which enter the area on early autumn to mid-spring from northwest and west, and forms an average precipitation about 250-350 mm per year.

The topography is generally extremely steep, and forms astonishing landscapes, so that the highest point in Jolfa region is the Kiyamaki mount with 3347 m and the lowest points include the northern boundary and the Aras river valley with 720 to 390 meters. Given to its climate, the area has a diverse vegetation, so that Aras valley is covered by subtropical trees, since the western and middle parts are dominated by steppe, and Arasbaran dense forests are seen on eastern slopes. The permanent snow line is located above the altitude of 3000 meters.

The main river in the area is the Aras river that make the northern boundary of the geopark with Armenia and Nakhchivan Autonomous Republic. The continues roaring steam of the river passing from northwestern to northeastern drains surface waters in the area. The river in downstream meets the Kura River and at last flows into the Caspian Sea.

The area has an appropriate geo-tourism attraction, because of its mountainous landscapes, and outcropping different sedimentary and igneous rocks, diversity in tectonic structures, semi-cold and semi-arid climate and diverse flora and fauna.

Main geosites in the Geopark include Kamtal, Marakan, Darediz and Kiyamaki localities, that given to their diverse flora and fauna, are protected by Iranian Department of Environment. Among the most notable geological features of the Geopark can mention to Paleozoic-Mesozoic sedimentary rocks sequence, especially the conformity of Permian to Triassic sediments, that is very interesting for geologists, plutonic provinces and extensive granitic rocks which is covered eastern part of area, volcanic and sub-volcanic provinces that form Kiyamaki dome, compression regime resulting from Alpine Orogeny which causes developing different structural features such as faulting, trusting and folding of rocks, fossil site localities, mineral springs which deposit travertine, and at last the Aras River and its related geomorphic features. Each of these phenomena can shows different orogenic phases, its forming processes and life history on our planet.

Aras Geosites

Geosite is a part of a Geopark where a number of geological features are located near to each other, and its important geological phenomena can be visited completely in a short time. Geological heritage in each geosite include astonishing landscapes and amazing geological phenomena with scientific, educational and aesthetic significance that enchanted visitors and imply them to the mysterious Earth’s history.

Aras Geopark is located where the string of micro-continents or Cimmeria collided with paleo-continent Laurasia, and its outcrops cover a wide range of different rocks from Paleozoic to Cenozoic sediments, plutonic, volcanic and well as metamorphic rocks. The maximum height difference is more than 2900 meters, so one can expect so many geological features and topographic views in each of its geosites. Among the important geosites in the area are Aras River, Kamtal National Park, Marakan Protected Area, Dare-diz Protected Area, Asiyab-kharabe (broken mill) water fall, Kiyamaki volcanic dome, and Maharan waterfalls.

Aras River

Aras River is located in the northern part of the Geopark that flows from west to east of the area. The river is the political border between Iran in the south and Armenia and Nakhchivan Autonomous Republic in the north.

The most distant sources of Aras river are Bingöl mountains in the south of Erzurum province in Turkey, 240 km far from Iranian border, passing through countries include Armenia, Iran and Azerbaijan, with a length of 1072 km, flow into Kura River and at last into Caspian Sea. Morphologically, Aras channel is mostly braided and longitudinal braid bars as long single islands can be seen along its channel. These braid or mid-channel bars are resulted from deposition of river gravel load when the discharge is low.

Kamtal National Park

Geologically, Kamtal National Park is located on a huge granitic intrusion, formed in Eocene Epoch (56 to 34 Ma), in the Cretaceous sedimentary rocks (145 to 66 Ma). Thermal contact metamorphism is restricted to the zone surrounding the intrusion. So that, a wide range of various rocks include intrusive igneous rocks, and volcanic and sub-volcanic (as sills and dikes), contact metamorphic and sedimentary rocks, especially travertine (around the hot springs) are observable in a limited distance, less than 10 km length. Such a diverse lithology is very unique all over the area. Among the most significant geological features can be name from mineralization as veins contain copper and iron, fossil localities, numerous caves and plenty of dikes that occur as long dark continues walls in limestone cliffs.

Kamtal National Park contain some of most beautiful intact landscapes in the Geopark, as a last stand castle for wild life, that fortunately save its bio-diversity. Its green meadows replete with flowers mesmerizes any visitor.

Marakan Protected Area

Marakan protected area is located at the west of Geopark. In this region we can see the oldest lithological units in the Geopark, namely Jairood Formation aging Devonian Period (420 to 360 Ma) which constituted most extended outcrops as well. Permian and Triassic sedimentary rocks including limestone, dolomite and sandstone outcrop in the area too. These rocks are rich in term of fossil content, and fossils of some of the extinct ancient animals like brachiopods, pelecypoda (bivalve) and ammonites can be found in these sedimentary rocks.

Faults and thrusts in the area caused a significant strike-slip and reverse movements, and there is rhyolite-dacite extrusions, sills and dikes with dark colors outcrops.

Marakan region with sharp cliffs and steeped crags resulted from missive limestone and dolomitic beds and fault scarps, is blessing gift for wild life as well as who love natural astonishing perspectives.

Dare-diz Protected Area

Another important geosite in the Geopark is the Dare-diz Protected area. Visitors who enter the Geopark via Tabriz road from the south way, whether by car or train, first of all, encounter with huge cliffs and elevated hilltops of this geosite.

Competent limestone and dolostone beds from Devonian, Permian and Triassic Periods, as well as Devonian Andesitic lavas constituted main part of outcrops in the region. Compression caused by continental collision in Alpine orogeny from the late Triassic Period to present, has led to significant bed folding on each other and thrusting them in a large distance.

Stunning scenic views of the geosite area with observable thrusts and strike-slip faults, systematic joints, fault related folding and micro-folds can excite every visitor and create ineffaceable memories. Vast outcrops of limestone-dolostone formations with missive well bedded can help to detect structures like different type of folds and faults. Sedimentary layers rich in fossils of Brachiopods, Pelecypoda, Corals, Echinodermata and Ammonites has completed this beautiful picture.

Apart from its unique structural geology specifics, Dare-diz geosite has a significant biodiversity, both in flora and fauna, that placed it in the list of protected areas in department of Environment.

Kiyamaki Volcanic Dome

One of the most important factors in creating such a sharp and steep topography in the Geopark is volcanism in geological history of the area. Most significant volcanic activity has occurred in Oligocene Epoch (34 to 24 Ma), which lead to creating Kiyamaki mount.

The dominant lithology of its volcanic rocks is Dacite. It is extrusive igneous rock that form in result of magma eruption from the depth in the Earth. Large silica content of Dacitic magma make it very viscous. So these types of magmas flow hardly and slowly on the ground. In the way to waterfalls, looking carefully, one can distinguish the boundary between this Dacitic lava and their underlying limestone rocks.

With elevation of 3347 m above sea level, topographic prominence of 2000, and height of 2600 above Jolfa Plain, the Kiyamaki summit is snowy and cloudy in most of the year. The summit is iconic, it is among the popular climbing targets and many climbers try to ascent it every year.

Maharan Waterfalls

One of the geo-tourism interesting in the Geopark is the western steep slopes of Kiyamaki mountains and the valley ended with Maharan waterfalls. Maharan valley with its roaring waterfall cascades can be reached by walking on a rural road from Qeshlaq village to its nearby valley.

Some of the most interesting geological features in the area include prismatic joints formed in volcanic rocks, also Quaternary glacial evidences in the hemispherical valley of Qeshlaq village. The latter has formed as a great depression like a large scale amphitheater which presents a glacial cirque.

Breathtaking mountain views and significant climate change from this region to its downstream is so that has a pleasant weather with relatively low temperature even in early summer, attracting many visitors.

Asiyab-kharabe Waterfall

Asiyab-kharabe (broken water mill) waterfalls is located in 25 km east of Jolfa city, along the Jolfa-Siahrood road. In this location, near an abandoned watermill, there is a travertine spring that flows from a cleft in the rocks. The cleft, in fact, is the entry of a cave that long 150 m and end to a chamber where is the main appearance of the spring. Its water stream passing close to the abandoned watermill end to a waterfall with a height of 10 m, where dense hydrophilic plants are grown.

Beautiful folding stretched in Cretaceous flysch deposits on the left side slopes of Asiyab-kharabe valley. These chevron folds in the alternate sandstone-shale layers provide a wonderful perspective and attract the interest and curiosity of people. Fossils and various sedimentary structures in the base of sandstone beds complete this stunning picture, phenomena that represent bioactivity in the Neotethys seabed living near 70 million years ago and probably are ancestors of some of the present day animals.

How to get there!

Aras Geopark area is located in the northwest of Iran,east Azerbaijan Province and spread across the whole Jolfa county. The county has three cities: Jolfa, Hadishaher and Siah-rood. It is easily accessible from various parts of Iran and neighbouring countries by air, rail and road.


This area is mountainous and features semi-arid and semi-cold climate. Average annual precipitation ranges between 250 to 350 mm and the mean temperature is about 15 oC.

Approximately seventy days of the year are considered as the number of freeze days. In seasons, particularly spring and fall, the temperatures are more moderate and it is the best time to visit this area.

 By car

There is 136 Km distance between Tabriz and Jolfa. It would take 1 hour 40 minutes to go there. It will pass by Sofian and Marand cities which is the shortest way to get there. The old road which is run a little way to the north and is crossed Kalibar city, is another way to travel from Tabriz to the Geopark and Jolfa area. Although it takes longer time to reach your destination, you will be interested in Iran’s natural sceneries.

The Geopark region is located in Aras free trade-industrial zone, therefore imported cars that intend to travel in free zone must have a special license plate. These cars are free of customs duty and are allowed to travel anywhere within a radius of 135 km, even city of Tabriz.

By bus

Every day numerous buses from all over the country especially Tabriz and Tehran, travel to the area and Jolfa city. Hadishahr city is the terminal for the buses going to the Geopark. If you want to know, it just takes 10 minutes to get from Jolfa to Hadishahr by car.

By train

Trains from Tabriz have regular services into Jolfa. Tabriz trains travel to and from Jolfa on a Daily basis drop-off at 8:15 and 8:45 and pick up at 19:00 and 19:45 from Jolfa station. It’s takes 2 hours and 45 minutes. You should know that the passengers who travel by train during New Year’s Eve in late March to early April are free of charge.

If you want to travel to Tabriz and Jolfa from Tehran and elsewhere, the time of arrival from Tehran to Jolfa is at least 17 hours. Although it is a long journey, you can enjoy your trip by sightseeing and relaxing along the way.

By Air

Tabriz airport is the nearest airport to Jolfa. To get from the airport to Jolfa county only takes one and a half hours by car.

Recently for the first time in Iran, an Air taxi services has been launched between Tabriz and Jolfa by helicopter in Aras free zone. This allows you to travel faster and more conveniently than before as it takes just 40 minute to reach your destination.


Paradise for geologists

Welcome to incredible Iran: Paradise for geologists!

Give us your hands until to familiar with beauties of Iran. Geological history of Iran is full of events, created widespread volcanic, magmatic and metamorphic outcrops. Thick stratigraphic sequences are naked across the country.

Our country hosts so many major faults, long anticlines and perched synclines, the beauty phenomena for structural geologists. Iran also is the country of Quaternary deposits and landforms extend from mountains top (glaciers) to the hill slope (alluvium) and from there to the lowlands in central Iran where the fascinated deserts, salt lakes, sand dunes and Yardangs have created a very attractive landscape for geologist and geomorphologists.

West of Iran is domain of karstic features, such as beautiful caves and large sinkholes which are formed during the last glacial stage.

Landslides are frequent in everywhere, including the Seimareh landslide with kilometers in length and width, well known as the largest landslide in the world.

The Zagros Mountain is located in the south and southwest of Iran. The famous structural – sedimentary zone contains the largest oil and gas reservoirs.

Our international guests can see the continuous stratigraphic sequence with several kilometers thick from Jurassic up to Pliocene, bare and easily to investigations.

The south of Iran also is the best place for visit unique salt domes, mud volcanoes and recent reefal limestone.

Iran also has an exceptional geographic and climatic conditions. The difference temperature between north and south sometimes reaches to 30 centigrade.

In the North, the shore line of the Khazar Sea, as the largest lake in the world, and its surrounding area with mountainous forest, are the attractive place for millions of tourists in all seasons. In this region, the natural beauties are in your path.

Toward central and southern parts of Iran can enjoy the magnificent and beautiful deserts, Kavirs as well as salt lake and playas have extended far away.

Damavand, Sabalan and Sahand as the most famous volcanoes of Iran and their young volcano-clastic rocks welcome to all volcanologists throughout the world.

There are so many Geo-parks and Geo-sites that increase your familiar with other natural beauties of Iran.

All attractions with low cost traveling, unbeatable security and hospitable people will excite you for travelling to Iran again and again.

“ZaminGasht” is a window to meet you the natural beauty and geological phenomena of Iran. We have numbers of Iranian experts in all branches of geoscience who can identifying natural beauty of Iran to all international geoscientists and geo-tourists.

Orogenic Events


The Pan-African orogeny is equivalent to Asynitic in other parts of the earth. This event was associated with metamorphism, magmatism, folding, and faulting during Late Precambrian–Early Cambrian in Iran (e.g., south of Zanjan–Mahabad in Azerbaijan, Bafq in Central Iran. This tectonic phase started with tension or extension leading to the formation of rifts and generation of oceanic crust (e.g., in Takab and Anarak) and ended with folding, closure, metamorphism, growth of the continental crust, and development of regional faults.


There was no considerable folding or faulting related to this event in Iran. The Caledonian orogeny in Iran is characterized by facies change in sedimentary basins, hiatuses, and epeirogenic movements (e.g., parts of Alborz, Zagros, and Central Iran). This phase, starting from Late Cambrian, caused the marine facies of Barut and Zaigoon Formations to change into the continental facies of Lalun Formation, and continued on to Late Devonian.


The effects of this orogenic episode in Iran can be traced from the Late Devonian. Due to the scarcity of magmatism, metamorphism, and folding related to this episode, the role of the Hercynian orogeny in Iran is controversial; the Hercynian in Iran is largely represented by extensional rather than compressional tectonics (e.g., Sanandaj–Sirjan). Iranian microplates east and northeast of the Zagros were detached from Gondwana in the Carboniferous during this orogenic phase.

Early Cimmerian

The Early Cimmerian orogeny is one of the most important tectonic events in the geological history of the earth. Many diverse features are associated with this phase, including metamorphism, magmatism, folding, faulting, creation of new basins, and facies change. This event was associated with compressional tectonics in the northern Iran and tensional tectonics in the south. There is evidence that the compressional phase was preceded by tension and rift development. The compressional phase, happening in the Late Triassic, finally led to the closure of the Paleotethys (e.g., southeast to southwest of Caspian Sea). Iranian microplates that had been detached from Gondwana in the Carboniferous and that had been submerged and had moved northwards toward Laurasia finally collided with the Eurasian section of the northern supercontinent Laurasia in the Late Triassic.

Late Cimmerian

The Late Cimmerian orogeny occurred as a significant tectonic event in Iran in Late Jurassic–Early Cretaceous times. This event is represented by folding, facies changes in sedimentary environments, angular unconformity, magmatism, and metamorphism (e.g., Alborz, Sanandaj–Sirjan, and Central Iran). The Jurassic granite of Kolah Ghazi, Shir Kuh, and Shah Kuh was made during this orogenic phase.


The Laramide orogeny happened in the Late Cretaceous–Paleocene and played a great role in the geological evolution of Iran. This event started under a compressional regime, followed by an extensional one. The compressional regime, that was associated with significant intrusive magmatic activities, led to the closure of the oceanic basins and Neothetyan rifts. In some areas, slices of the oceanic crust have obducted onto the continental margins producing what could be called ophiolite assemblages or coloured melanges (e.g., mostly seen suture zone between Sanandaj–Sirjan and Zagros, and alongside Nehbandan fault in the east of Iran). The Upper Cretaceous-Paleocene granite of Mount Alvand was formed during the Laramide orogeny.

Alpine (Pyrenean and Styrian)

With regards to the geological evidence, this event was of compressional nature. This tectonic phase is represented by significant changes in the sedimentary environments, plutonism, and metamorphism (e.g., west of Central Iran, south of Central Alborz, Lut). The Sahand-Bazman volcanic arc or belt was mainly formed during the Eocene volcanism of the Alpine orogeny. The northern movement and the final collision of Afro-Arabia (significantly the Arabian Plate) with the Iranian Plate and the clockwise rotation of the Eurasian Plate towards the Iranian Plate caused the Alpine orogeny with the Pyrenean phase in the Late Eocene- Early Oligocene and the Styrian phase in the Middle Miocene respectively. The Zagros, Alborz, and Kopet-Dagh mountains were mainly formed in the Miocene during this orogenic phase.


This orogenic phase began in the Late Pliocene and continued in the Pleistocene. The Pasadenian orogeny is the most important phase in forging the current shape of Iran. Some younger orogenic events might be the continuation of this orogenic phase (e.g., Alborz–Azerbaijan axis, Zagros, Central Iran). Sahand, Sabalan, Damavand, Bazman and Taftanwere mainly formed during the volcanism of this orogenic phase. With an elevation of 5,610 metres, Mount Damavand is the highest peak in Iran. This volcano first erupted in the Pleistocene about 1.78 million years ago and after several known eruptions around 600,000 and 280,000 years ago, it finally erupted in the Holocene almost 7300 years ago.

References: wikipedia

picture from: The Shanderman eclogites: a Late Carboniferous high-pressure event in the NW Talesh Mountains (NW Iran)

Magmatism and Igneous Rocks

Magmatic rocks of all ages, from the Precambrian to the Quaternary, are widespread in Iran (e.g., Doran granite, Zarigan–Narigan granite, Torghabeh granite, Ghaen granite, Chaghand gabbro, Alvand granite, Natanz granite). A correlation exists between distribution of magmatic rocks and certain types of ore deposits (e.g., iron deposits in Bafq related to Zarigan–Narigan-type granites, Mazraeh copper deposits related to Sheyvar–Daghi granite, Sarcheshmeh porphyry deposit related to Sarcheshmeh porphyry body).

Several episodes of magmatic activity have been identified in Iran. These episodes could be described as:

Upper Precambrian–Lower Cambrian

Volcanic and plutonic rocks with an age of 630–۵۳۰ million years have been reported from many localities in Iran, particularly in Central Iran and Azerbaijan. These magmatic rocks seem to be related to the Pan-African tectonic-magmatic episode. Most magmatic rocks of this time bear an alkaline nature. The following magmatic series can be attributed to this phase: Doran-type intrusions in Azerbaijan. Narigan and Zarigan-type intrusive bodies extend from Anarak to Bafq and Kuhbonan. Volcanic rocks, mostly of rhyolite composition, in Ghareh Dash, Azerbaijan. Volcanic rocks associated with Kushk Series in the Bafq area. Volcanic rocks of Rizu, Dezu, and Kushk Formations in Central Iran. Most Precambrianmetamorphic rocks of greenschist or even amphibolite facies, such as in Takab and Anarak areas, seem to have originally been volcanic materials, either lava or pyroclastic rocks.

Lower Paleozoic

Magmatic rocks of this time have been reported from many areas in Iran. Examples include basaltic rocks of Shahrud and Khosh Yeilagh, andesitic-basaltic units of Niur Formation in Central Iran, and tuffaceous materials in the upper parts of Mila Formation in Eastern Iran.

Upper Paleozoic

Volcanic rocks of andesitic-basaltic composition accompany Upper Paleozoic sedimentary strata in many areas all over Iran. Basaltic rocks associated with Jeyrud Formation of Upper Devonian are a typical example. There is strong evidence for significant magmatic activities in Late Paleozoic–Early Mesozoic (Early Permian to Early Jurassic) in Iran. Examples include: Magmatic rocks in the Southern Sanandaj–Sirjan (granites and gabbros of Sirjan area) and volcanic rocks of Songhor Series in Northern Sanandaj–Sirjan. Ultramafic and mafic rocks and their metamorphosed equivalents could be observed in Eastern Iran (Fariman area), Taknar Series, Gorgan schists, and Shanderman mafic/ultramafic metamorphic series.


The Mesozoic magmatic rocks are associated with Cimmerian and Laramide orogenic events that caused continental and oceanic rifting, followed by closures and collisions in vast areas of Iran (e.g., Sanandaj–Sirjan). The Mesozoic magmatic rocks can be divided into three groups: Volcanic rocks: These rocks occurred mainly as a result of extension or tension related to the continental rifting, or subduction of the developed oceanic lithosphere under the continental lithosphere (e.g., Central Alborz for continental rifting; Saghez-Sanandaj axis for subduction). Intrusive rocks: Many intrusive bodies of mafic to granitic composition, with ages varying from early Triassic to Late Cretaceous, have been identified in Iran (e.g., Borujerd–Shamsabad axis). In Triassic–Jurassic, volcanic rocks predominated the plutonic rocks. They are mainly alkaline in nature and are more abundant in Sanandaj–Sirjan. In Jurassic–Cretaceous, intrusive rocks exceed volcanic rocks; a significant number of batholiths in Iran occurred at this time. Kolah Ghazi, Shir Kuh, and Shah Kuh were formed by Jurassic granite; and Mount Alvand was made by Upper Cretaceous-Paleocene granite.


The Tertiary is of great concern in Iran because of the great volumes and highly diverse types of igneous rocks and associated mineral deposits. Magmatic rocks of this age are widespread all over Iran, except in the Zagros and Kopet Dagh. Data from various structural zones indicate that the volcanic and plutonic activities started in the Late Cretaceous, peaked in the Eocene, and continued, with short stops, into the Quaternary. Some of the more important regions in terms of the Tertiary magmatic activities include: Sahand-Bazman(or Urumiyeh-Dokhtar) volcanic-plutonic belt with a series of famous mountain ranges including the Karkas Mountains and Jebal Barez and important peaks such as Karkas, Marshenan, Hezar and Lalehzar. The Tertiary magmatism could also be observed in Azerbaijan, Tarom–Taleghan, Central Alborz and its southern margins, Kavir–Sabzevar, Kashmar–Torbat-e Jam, Lut and Kavir, Central Iran, Sistan, Bam, Bazman, Taftan, East Iran, and Southern Jazmurian–Sabzevaran. The Quaternary volcanism produced very high peaks such as Sahand, Sabalan, Damavand, Taftan, Bazman and many others.



The consolidation of the Iranian basement by metamorphism, partial granitization and partly by intense folding took place in the Late Precambrian. This event has been attributed to the ‘Baikalian’ or Pan–African Orogeny by various authors. Isotopic data of Iranian basement rocks give ages between 600 and 900 Ma. A similar range of isotopic data had been obtained for Arabian Shield rocks. An important post-Pan-African magmatism is documented by the widespread Doran Granite, which cuts the Upper Precambrian rocks and is covered by Lower Cambrian sediments. Late Precambrian postorogenic volcanics, mainly alkali rhyolite, rhyolite tuff and basic dikes are known in the Eocambrian formations. In North and Central Iran, Kahar and Gharehdash Formations and the lower half of the Soltanieh Formation are of Precambrian age. The oldest rocks in Iran belong to the Kushk Series consisting of clastic sediments, acidic volcanic, tuff, and carbonates (mainly dolomite). Other formations of Late Precambrian–Early Cambrian ages include Rizu volcanic-sedimentary Formation, Dezu and Tashk Formations, Aghda limestone, Kalmard Series, Shorm Beds, and Anarak metamorphic units. The sedimentary facies of Precambrian–Lower Cambrian rocks in Northern Iran is different from that of Central Iran.


With the Pan-African orogeny and following this orogenic episode, shallow marine sediments formed in Late Vendian. The influence of the orogenic episode is evident at the base of the Vendian sediments. Deposition of shallow marine sediments covered large areas in Iran during Paleozoic (e.g., Alborz, East of Iran, Zagros). There is strong stratigraphic evidence that transition from Vendian to Lower Cambrian was a progressive one, without hiatuses; there is no evidence for any orogenic or epeirogenic movements in Iran at this time (e.g., south of Zanjan, Valiabad Chalus, Shahin Dezh). Early Cambrian started with an alternation of shale, phosphate-bearing limestone, and dolomite sitting conformably and transitionally over Vendian dolomites. Transition from Soltanieh Formation to Barut, Zaigoon, and Laloon Formations is very difficult to recognize in the field. Middle Cambrian is characterized by uplift and regression; however, a renewed progression at this time led to the deposition of Mila and Kuhbonan Formations, consisting of limestone, dolomite, and shale, over older units. These formations bear trilobites and brachiopods of Middle and Late Cambrian. In some areas, the Late Cambrian carbonate facies turns transitionally into Ordovician graptolite shales, known as Lashkarak Formation in Alborz, Shirgasht Formation in Central Iran and Ilbeyk and Zardkuh Formations in Zagros. In Kalmard area, Ordovician sediments are sitting on the Vendian sediments through an angular unconformity. In Late Ordovician, most parts of Iran were affected by epeirogenic movements; this coincides with Caledonian orogeny in Europe and some other parts of the earth. The epeirogeny caused a distinct hiatus at the Ordovician–Silurian boundary. Where present, the Silurian rocks in Iran consist mainly of limestone, sandstone, shale and volcanic materials, known as Niur Formation in Central Iran. The Lower Devonian rocks have been reported from several localities in Central Iran (e.g., Tabas, Sourian, Kerman, Zagros); however, they seem to be missing in Alborz and parts of Zagros. Upper Devonian is characterized by marine transgression, particularly in Alborz, that extends into Lower Carboniferous. With exception of Tabas area, no record of Middle Carboniferous marine deposits has yet been discovered in Iran. Upper Carboniferous deposits are not significantly present in Iran and have only been identified in several localities from index goniatites. After a general regression and a distinct hiatus in Upper Carboniferous, Permian marine transgression deposits cover most parts of Iran (e.g., Alborz, Zagros, Central Iran); The Permian sediments are represented by Dorood sandstones, Ruteh and Nesen limestones in Alborz.


The Lower Triassic sediments in Iran are mainly of shallow marine or continental shelf nature (e.g., Doroud sandstones and Elika dolomites in Alborz, Sorkh shales and Shotori dolomites in Central Iran. A continuous Permian–Triassic sequence has been reported from several areas in Iran, including Jolfa (northwest of Iran), Abadeh (Southern Central Iran), and Southern Urumiyeh (the continuation of the Taurus in Turkey), north of Kandovan and Southern Amol. Transition from Middle to Upper Triassic coincides with Early Cimmerian orogenic episode, which led to the segmentation of the sedimentary basin into three sub-basins: Zagros in the south and southwest, Alborz in the north, and Central Iran. The Lower Jurassic rocks conformably overlie the Upper Triassic units; so are the Early Cretaceous deposits over the Upper Jurassic strata (e.g., Zagros). In North and Central Iran, the Upper Triassic and Lower–Middle Jurassic sediments have a detrital nature, consisting mainly of shale and sandstone with thicknesses varying from a few meters to more than 3,000 m. The presence of plant remains and coal beds suggest a continental or lagoon environment for the deposits. The Cretaceous deposits, characterized by diverse sedimentary facies, are widespread all over Iran. In Late Cretaceous, tectonic movements related to the Laramide orogeny affects most parts of Iran, leading to uplift, folding, and faulting. This is a prelude to significant developments in the geological evolution of Iran.


In Iran the Cenozoic begins with the Cretaceous–Paleocene boundary that is characterized by striking changes in sedimentary environments (e.g., Alborz, Central Iran). An unconformity has been reported from many locations in Iran. Both continuous and discontinuous transitions have been discovered between Paleocene and Eocene strata; as is the case with Eocene and Oligocene (e.g., Central Iran). The Oligocene and Miocene stages are characterized by rapid subsidence, deposition, and facies changes in both marine and continental sedimentary basins (e.g., Mahneshan and Halab south of Zanjan). Oligocene sediments in most parts of Iran are of shallow marine character, turning into marine facies in Upper Oligocene through Lower Miocene (e.g., Qom). The Middle–Upper Miocene sediments are mostly of continental nature. The Quaternary is the prominent feature of the plains of Iran.

Geological and Structural Units

Considering geological and structural units of Iran, three main structural units or zones could be distinguished in Iran. These units or zones are separated from each other by ophiolite–bearing sutures. Other criteria such as structural style, crustal character and age of basement consolidation, age and intensity of deformation, age and nature of magmatism, are used to subdivide these major zones into smaller elements. The three major units and their main constituents could be defined as the southern, central and northern units. The southern unit has a crystalline basement consolidated in the Precambrian time and a platform–type Paleozoic development and comprises the Zagros folded belt, southern and southwestern parts of the Zagros. This section made a part of the Arabian Plate that was located on the margin of Rodinia and Pannotia in the Neoproterozoic, and of Gondwana in the Paleozoic and Mesozoic. The central unit, which comprises the central Iran and the Alborz, is interpreted as an assemblage of fragments that were in the vicinity of the Arabian Plate and formed a marginal section of Rodinia and Pannotia in the Neoproterozoic and of Gondwana in the Cambrian, Ordovician, Silurian and Devonian. These fragments were detached from Gondwana in the Carboniferous. They were submerged, moved northwards, and were finally attached to the Eurasian section of the northern supercontinent Laurasia in the Late Triassic. These fragments or microplates were fused together and made the Iranian Plate which was rejoined by Gondwanic Afro-Arabia in the Late Cretaceous. As Afro-Arabia moved northwards towards Eurasia, the Arabian Plate ultimately collided with the Iranian Plate in the Miocene. Finally there is the northern unit which is separated from the central unit by the North Iran Suture. It is characterized by continental crust including remnants of more or less cratonized former Paleozoic oceanic crust that seems to reflect the Paleotethys. The northern unit represents a marginal strip of the Hercynian realm of Central Asia- broadly overlapped by the Alpine realm. It was deformed and largely consolidated by the Early Cimmerian folding and the Late Alpine folding. The northern unit comprises the South Caspian Depression and the Kopet Dagh Range.

These three main structural units are divided into some smaller geological and structural subdivisions which include the following zones:


This zone extends from Bandar Abbas in the south to Kermanshah in the northwest and continues through to Iraq. Zagros is in fact the northeastern edge of the Arabian plate. Some important features of Zagros include: Absence of magmatic and metamorphic events after Triassic, and low abundance of the outcrops of Paleozoic rocks. Structurally, it consists of large anticlines and small synclines and continuous marine sedimentation from the Carboniferous to the Miocene. On the whole, a sequence of Precambrian to Pliocene rocks about 8-10 kilometres in thickness has undergone folding from the Miocene to the Recent time in the Zagros Mountains. The Zagros fold and thrust belt was formed by the collision of two tectonic plates — the Iranian Plate and the Arabian Plate. This collision primarily happened during the Miocene and folded the entire rocks that had been deposited from the Carboniferous to the Miocene in the geosyncline in front of the Iranian Plate. The process of collision continues to the present and as the Arabian Plate is being pushed against the Iranian Plate, the Zagros Mountains and the Iranian Plateau are getting higher and higher. The Zagros mountain range, itself, has a totally sedimentary origin and is made primarily of limestone. In the Elevated Zagros or the Higher Zagros, the Paleozoic rocks could be found mainly in the upper and higher sections of the peaks of the Zagros Mountains along the Zagros main fault. On the both sides of this fault, there are Mesozoic rocks, a combination of Triassic and Jurassic rocks that are surrounded by Cretaceous rocks on the both sides. The Folded Zagros (the mountains south of the Elevated Zagros and almost parallel to the main Zagros fault) is formed mainly of Tertiary rocks, with the Paleogene rocks south of the Cretaceous rocks and then the Neogene rocks south of the Paleogene rocks.


This zone is located to the south-southwest of Central Iran and the northeastern edge of Zagros range. In the north and northeast, this zone is separated from Central Iran by depressions like Lake Orumiyeh, Gavkhouni and faults like Shahr-e-Babak and Abadeh, and to the south-southwest by the main thrust fault of Zagros. A striking feature of this zone is the presence of immense volumes of magmatic and metamorphic rocks of Paleozoic and Mesozoic eras. As far as the trends, and particularly the folding style is concerned, some researchers consider the Sanandaj–Sirjan Zone as being similar to Zagros; however, considerable differences exist in rock types, magmatism, metamorphism, and orogenic events. There are some similarities between Sanandaj–Sirjan and Central Iran.

Sahand–Bazman Volcanic Belt

This volcanic belt, which is usually called the Central Iranian Range, runs east and almost parallel to the Sanandaj–Sirjan Zone, and owes its existence to the widespread and intensive volcanic activity which developed on the Iranian plate from the Upper Cretaceous to Recent time. The peak of this volcanism happened in the Eocene. The Sahand-Bazman volcanic belt is supposed to have resulted from the collision of the Arabian and Central Iranian continental plate margins. It is represented by sub-alkaline volcanics that vary in composition from basaltic through andesitic to rhyolitic composition.

Central Iran

Located in a triangle in the middle of Iran, Central Iran is one of the most important and complicated structural zones in Iran. In this zone, rocks of all ages, from Precambrian to Quaternary, and several episodes of orogeny, metamorphism, and magmatism can be recognized. Central Iran in a broad sense, comprising the whole area between the North and South Iranian ranges. Within the Iranian plate the Central-East Iran microplate is bordered by the Great Kavir Fault in the north, by the Nain–Baft Fault in the west and southwest and by the Harirud Fault in the east. It is surrounded by the Upper Cretaceous to Lower Eocene ophiolite and ophiolitic melange. The microplate consists of different structural components; Kerman-Tabas Block, Yazd Block and Anarak-Khur Block.

Eastern Iran

Eastern Iran can be divided into two parts: Lut Block and Flysch Zone (flysch or coloured melange of Zabol–Baluch Zone). Located to the west of Zabol–Baluch Zone, Lut Block is the main body of Eastern Iran. Lut Block extends for about 900 km in a north–south direction. It is bounded in the north by Dorooneh fault and in the south by Jazmurian depression. In the east, it is separated from Flysch Zone by the Nehbandan fault, whereas the western boundary with Central Iran is Nayband fault and Shotori Mountains. The oldest units include upper Precambrian Lower Cambrian schists overlain by Permian limestone and other Paleozoic sedimentary rocks. Flysch Zone (Zabol–Baluch) is located between Lut Block to the west and Helmand (in Afghanistan) to the east. In contrast to Lut Block, the Flysch Zone is highly deformed and tectonized and consists of thick deep-sea sediments like argillaceous and silicic shales, radiolarite, and pelagic limestone and volcanic rocks such as basalt, spilitic basalt, diabase, andesite, dacite, rhyolite, and subordinate serpentinized ultramafic rocks. The basement is likely composed of an oceanic crust. Most rock units in this zone fall into three main groups: flyschoid sediments; volcanic, volcanosedimentary, and intrusive rocks; and ophiolitic series.

Southeastern Iran or Makran

Southeastern Iran or Makran zone is located to the south of Jazmurian depression. Its western boundary is Minab fault; to the south, it is restricted by the Gulf of Oman, and to the east, it extends into Pakistan. The northern part is characterized by dominance of east–west trending faults, Bashagard fault being the most important one. Along these faults lies large section of ophiolite series. The oldest rocks in this zone are the ophiolites of Late Cretaceous–Paleocene overlain by a thick sequence (about 5,000 m) of sandstone, shale, and marl. The whole sequence is deformed prior to Early Miocene. Thick sequence of Neogene rock units, in excess of 5,000 m, covers the older series.

Kopet Dagh

The northeastern active fold belt of Iran, the Kopet Dagh, is formed on the Hercynian metamorphosed basement at the southwestern margin of the Turan Platform. The belt is composed of about 10 kilometres of Mesozoic and Tertiary sediments (mostly carbonates) and, like the Zagros, was folded into long linear northwest-southeast trending folds during the last phase of the Alpine Orogeny, in the Miocene and Plio-Pleistocene time. No magmatic rocks are exposed in Kopet Dagh except for those in the basement in the Aghdarband and some Triassic basic dikes. This basin was located in the northeastern Iran. From Middle Jurassic, it was covered with a vast continental shelf sea. In this period of time and due to transgression as well as rapid subsidence basin, the western part became deeper. In this basin, a thick sequence of continuous marine and continental sediments was deposited (about 10 km). No major sedimentary gap or volcanic activities during Jurassic to Miocene have ever been reported. This sedimentary complex provides suitable conditions for accumulation of hydrocarbons. Kopet Dagh sedimentary rocks were placed in their current position due to uplifting at the end of the Miocene. The Kopet Dag Range, itself, is made chiefly of Cretaceous rocks with a smaller portion of Jurassic rocks in the southeastern parts. The mountains were mainly formed in the Miocene during the Alpine orogeny. As the Tethys Sea was closed and the Arabian Plate collided with the Iranian Plate and was pushed against it, and with the clockwise rotation of the Eurasian Plate towards the Iranian Plate and their final collision, the Iranian Plate was pressed against the Turan Platform. This collision folded the entire rocks that had been deposited in this geosyncline or basin from the Jurassic to the Miocene and formed the Kopet Dag Mountains.


The Alborz mountain range forms a barrier between the south Caspian and the Iranian plateau. This range is located in northern Iran, parallel to the southern margin of Caspian Sea. Alborz is characterized by the dominance of platform-type sediments, including limestone, dolostone, and clastic rocks. Rock units from Precambrian to Quaternary have been identified, with some hiatuses and unconformities in Paleozoic and Mesozoic. Unlike its northern and southern boundaries, (Caspian Sea and Central Iran, respectively) there is not a consensus regarding the eastern and the western limits of Alborz. The Binalud Mountains in the east, although the continuation of the Alborz, bear features comparable to those of Central Iran. The Alborz mountain range is only 60–۱۳۰ km wide and consists of sedimentary series dating from Upper Devonian to Oligocene, prevalently Jurassic limestone over a granite core. Continental conditions regarding sedimentation are reflected by thick Devonian sandstones and by Jurassic shales containing coal seams. Marine conditions are reflected by Carboniferous and Permian strata that are composed mainly of limestones. In the Eastern Alborz Range, the far eastern section is formed by the Mesozoic (chiefly Triassic and Jurassic) rocks, while the western part of the Eastern Alborz Range is made primarily of the Paleozoic rocks. The Precambrian rocks can be found chiefly south of the city of Gorgan situated in the southeast of the Caspian Sea and in much smaller portions in the central and western parts of the Central Alborz Range. The central part of the Central Alborz Range is formed predominantly of the Triassic and Jurassic rocks, while the northwestern section of the range is made chiefly of Jurassic rocks. Very thick beds of the Tertiary (mostly of the Eocene) green volcanic tuffs and lavas are found mainly in the southwestern and south-central parts of the range. The far northwestern part of the Alborz that constitutes what is called the Western Alborz Range or the Talish Mountains is made mainly of the Upper Cretaceous volcano-sedimentary deposits with a strip of Paleozoic rocks and a band of Triassic and Jurassic rocks in the southern parts, both in a northwest-southeast direction. With the northward movement of Africa and the Arabian plate and with the closure of the Tethys Sea as the Arabian Plate collided with the Iranian Plate and was pushed against it, and with the clockwise movement of the Eurasian Plate towards the Iranian Plate and their final collision, the Iranian Plate was pressed from both sides. The collisions finally caused the folding of the Upper Paleozoic, Mesozoic, and Paleogene rocks, and the Cenozoic (chiefly the Eocene) volcanism to form the Alborz Mountains mainly in the Miocene. The Alpine orogeny began, therefore, with Eocene volcanism in southwestern and south-central parts of the Alborz and continued with the uplift and folding of the older sedimentary rocks in the northwestern, central and eastern parts of the range during the orogenic phases of importance that date from the Miocene and the Pliocene epochs.


There is no agreement regarding the geological setting of Azerbaijan. According to some authors, the northeastern corner could be included in Alborz and the southeastern part in Sanandaj–Sirjan. Some believe that most of Azerbaijan lies in a zone called Azerbaijan–Alborz, and as they indicate, this zone is bounded in the north by Alborz fault, in the west by Tabriz–Urumiyeh fault, and in the south by Semnan fault. According to the some authors, the northern part of Azerbaijan continues to the Caucasus Mountains in Caucasia and the Pontus Mountains in Turkey and the Southern Azerbaijan is comparable with Central Iran and Western Iran and extends to the Taurus Mountains in Turkey. The significant structural event occurring in Early Devonian was accompanied by faulting and fragmentation that led to a different sedimentary facies in Azerbaijan. This orogenic episode generated the Tabriz fault, extending in a northwest–southeast direction from Zanjan depression to the northern mountains of Tabriz (Mishu, Morou) and northwest of Azerbaijan and the Caucasus. This event divided Azerbaijan into two blocks, one block in the northeast with subsidence and sedimentation in Early Devonian and the other in the southwest which remained high until Late Carboniferous.


lahar is a type of mudflow or debris flow composed of a slurry of pyroclastic material, rocky debris, and water. The material flows down from a volcano, typically along a river valley.

Lahars are extremely destructive: they can flow tens of meters per second (22 mph or more), be 140 meters (460 ft) deep, and destroy any structures in their path.

A lahar is a volcanic mudflow or debris flow. Lahars have the consistency, viscosity and approximate density of wet concrete: fluid when moving, solid at rest. Lahars can be huge.

A lahar of sufficient size and intensity can erase virtually any structure in its path, and is capable of carving its own pathway, making the prediction of its course difficult. Conversely, a lahar quickly loses force when it leaves the channel of its flow: even frail huts may remain standing, while at the same time being buried to the roof line in mud. A lahar’s viscosity decreases with time, and can be further thinned by rain, but it nevertheless solidifies quickly when coming to a stop.

Lahars vary in size and speed. Small lahars less than a few meters wide and several centimetres deep may flow a few meters per second. Large lahars hundreds of meters wide and tens of meters deep can flow several tens of meters per second (22 mph or more): much too fast for people to outrun. With the potential to flow at speeds up to 100 kilometers per hour (60 mph), and flow distances of more than 300 kilometers (190 mi), a lahar can cause catastrophic destruction in its path.

Lahars have several possible causes:

  • Snow and glaciers can be melted by lava or pyroclastic flows during an eruption.
  • Lava flows out of open vents and can mix with wet soil and mud on the slope of the volcano making a very viscous, high energy lahar. (The higher up the slope of the volcano the more gravitational potential energy the flow will have.)
  • A flood caused by a glacier, lake breakout, or heavy rainfall can release a lahar, also called glacier run or jökulhlaup
  • Water from a crater lake, combined with volcanic material in an eruption.
  • Heavy rainfall on unconsolidated pyroclastic deposits.
  • Volcanic landslides.

In particular, although lahars are typically associated with the effects of volcanic activity, lahars can occur even without any current volcanic activity, as long as the conditions are right to cause the collapse and movement of mud originating from existing volcanic ash deposits.

  • Snow and glaciers can melt during periods of mild weather
  • Earthquakes underneath or close to the volcano can shake material loose and cause it to collapse triggering a lahar avalanche.
  • Rainfall can cause the still-hanging slabs of solidified mud to come rushing down the slopes at a speed of more than 30 kilometers per hour (20 mph), causing devastating results.

Damavand volcano is the tallest volcano in Iran and Asia (5671m.). This volcano is currently a semi-active volcano. Smoke and steam come out from the volcano, but it has not erupted for years. Its last volcanic activity was 38,500 years ago (based on age determination by carbon 14). The mountain range is covered by frequent lava streams that have been flooded with peaks from the summit or sub-cones, as well as pyroclastic materials such as Pumice, Tuff and Lahar.

Lahar deposits accumulated around the city of Rudehen (near Tehran) are shown in the image. These deposits were flowing down the slopes of the Damavand volcano in ancient times. These deposits consist of fine grained deposits (ash) and large and small boulder(lava).

Keywords: Iran Geology , Iran Geotourism , Lahar , Rudehen , Tehran province , zamingasht

Reference: wikipedia

Alborz Mountain Range

Alborz (Persian: البرز‎‎), also spelled as Alburz, Elburz or Elborz, is a mountain range in northern Iran that stretches from the border of Azerbaijan along the western and entire southern coast of the Caspian Sea and finally runs northeast and merges into the Aladagh Mountains in the northern parts of Khorasan. This mountain range is divided into Western, Central, and Eastern Alborz Mountains. The Western Alborz Range (usually called the Talish Mountains) runs south-southeastward almost along the western coast of the Caspian Sea. The Central Alborz (the Alborz Mountains in the strictest sense) runs from west to east along the entire southern coast of the Caspian Sea, while the Eastern Alborz runs in a northeasterly direction towards the northern parts of the Khorasan region southeast of the Caspian Sea. Mount Damavand, the highest mountain in Iran, is located in the Central Alborz Mountains.

The Alborz mountain range forms a barrier between the south Caspian and the Iranian plateau. It is only 60–۱۳۰ km wide and consists of sedimentary series dating from Upper Devonian to Oligocene, prevalently Jurassic limestone over a granite core. Continental conditions regarding sedimentation are reflected by thick Devonian sandstones and by Jurassic shales containing coal seams. Marine conditions are reflected by Carboniferous and Permian strata that are composed mainly of limestones. In the Eastern Alborz Range, the far eastern section is formed by Mesozoic (chiefly Triassic and Jurassic) rocks, while the western part of the Eastern Alborz Range is made primarily of Paleozoic rocks. Precambrian rocks can be found chiefly south of the city of Gorgan situated in the southeast of the Caspian Sea and in much smaller portions in the central and western parts of the Central Alborz Range. The central part of the Central Alborz Range is formed mainly of the Triassic and Jurassic rocks, while the northwestern section of the range is made mainly of the Jurassic rocks. Very thick beds of the Tertiary (mostly of the Eocene) green volcanic tuffs and lavas are found mainly in the southwestern and south-central parts of the range. The far northwestern part of the Alborz that constitutes what is called the Western Alborz Range or the Talish Mountains is made mainly of the Upper Cretaceous volcano-sedimentary deposits with a strip of Paleozoic rocks and a band of Triassic and Jurassic rocks in the southern parts, both in a northwest-southeast direction. As the Tethys Sea was closed and the Arabian Plate collided with the Iranian Plate and was pushed against it, and with the clockwise movement of the Eurasian Plate towards the Iranian Plate and their final collision, the Iranian Plate was pressed from both sides. The collisions finally caused the folding of the Upper Paleozoic, Mesozoic, and Paleogene rocks, and the Cenozoic (chiefly the Eocene) volcanism to form the Alborz Mountains mainly in the Miocene. The Alpine orogeny began, therefore, with Eocene volcanism in southwestern and south-central parts of the Alborz and continued with the uplift and folding of the older sedimentary rocks in the northwestern, central and eastern parts of the range during the orogenic phases of importance that date from the Miocene and the Pliocene epochs.

In the photo above, the mountain overlooking the plain of Tehran (capital of Iran) can be seen. The mountains have formed the southern boundary of Alborz Mountain. The highest peak in this section, is Tochal (3962 meters). In the far right of the photo, Mount Damavand (5671 m), the highest peak in Iran is seen. This peak is the highest volcano in Asia.

In the southern part of Alborz in northern Tehran, pyroclastic rocks, shale and volcanic rocks are abundant. This stones are called green series or “Karaj formation”. More than 3,000 meters of sediments were deposited at the Eocene in this part of the Alborz, and the Karaj formation is created.

The Photo was taken by Amir Hossein Azizian, over “Milad Tower” in Tehran.

Keywords: Alborz Mountain , Elborz , Elburz , Eocene , Iran Geology , Iran Geotourism , Karaj formation , Milad tower , Mountain range , Orogeny , Pyroclastic ,Tehran , Tochal peak , Volcanism , zamingasht

Chahkuh Gorge

Chahkuh Gorge is located in the northwest part of the Qeshm Island, near West Chahu village. This Geosite is a good example of running water erosion and formation of a canyon form valley. The erosion was the secondary parameter to create this valley; it was happened along a deep joint and crack resulting the Salakh Anticline movement. So the primary parameter was the structural forces.

Chahkuh Gorge is located in the northwest part of the Qeshm Island, near West Chahu village.

Chahkuh Gorge is located in the northwest part of the Qeshm Island, near West Chahu village.

Chahkuh geological formation are inside the Salakh Anticline, near the salt dome appearance location. Anticline is a ridge-shaped fold of stratified rock in which the strata slope downward form the crest. Resulting the internal pressures and stretches many cracks, joints and faults appear on the anticline flanks those are the weakest points toward erosion. Chahkuh Gorge is a primary joint developed by erosion.

Aerial photo of Chahkuh Gorge

Aerial photo of Chahkuh Gorge

There is another gorge perpendicular to the main gorge; also created by the same mechanism. In general, anticlines and unstable locations so there always appear many faults and joints.

There is another gorge perpendicular to the main gorge; also created by the same mechanism.

There is another gorge perpendicular to the main gorge; also created by the same mechanism.

There is variety of shapes and form namely orbicular, dished, oval and linear on the walls or floor of the gorge all created by the powerful running water after raining. In some cases pieces of rock moves fast and circular inside the gorge and curves the surface to create wells and bowl shape holes (pot-hole).

There is variety of shapes and form namely orbicular, dished, oval and linear on the walls or floor of the gorge all created by the powerful running water after raining.

There is variety of shapes and form namely orbicular, dished, oval and linear on the walls or floor of the gorge all created by the powerful running water after raining.

Geological formations in Chahkuh is impermeable (Aghajari Fm.); it causes rain water to run over the surface. Local people invented a genius innovation using this feature; they dug some shallow wells in the surface to reserve rain water and use it. While Qeshm Island is an extremely dry area, water is worthy and important there; that’s why this innovation is very interesting and practical.

One of the main reasons to name this place as Chahkuh (barrow-well) is because of the water wells in this area and the usage of them by local people in years.

One of the main reasons to name this place as Chahkuh (barrow-well) is because of the water wells in this area and the usage of them by local people in years.

Chahkuh Gorge is created inside alternation of sandstone and marl formation of Aghajari – Mishan (Miocene-Pliocene). This formation comprises of cream color thin bedded limestone that gets thicker on the top part. Over the limestone part, soft sandstone bed appears. The sandstone consist of carbonate particles so it is not very resistance to the erosion. There are some parameters which affects the resistance of the sandstone and creating erosion forms: context and existence of vertical joints.

Keywords: Aghajari formation , Chahkuh , Geosite , Gorge , Hormozgan province , Iran Geology , Iran Geotourism , Island , Qeshm , zamingasht

Namakdan Salt Cave

Namakdan cave is among the most important geosites in the Qeshm Island Geopark (Hormozgan province, Iran). The salt dome (diapir) of Namakdan is a unique structure in the Island including several outstanding structural, mineralogical, erosional and sedimentary sceneries. In this Geosite the world record Namakdan Cave exists, the world longest salt cave, 6500 meters.

The Namakdan Salt Complex (Combrian) actually includes several smaller geosites. There are Salt flats, Playa, Salt springs, Amazing salt outcrops, Sink holes and many other structure and forms. This geosite has been registered in the National List of Natural Heritages (2010).

The main entrances of cave are N1, N2 and N3. N1 is open for general visits; visit to N2 needs arrangements with geopark management and should be done by geopark guide assistance. N3 is very delicate and also dangerous; it is possible to visit just for speleology professionals, geology specialist’s holded particular, written permission from the Qeshm Island Geopark management.

There is a spectacular polygonal form on the southern wall of salt dome in front of the sea. This structure created by salt surface fractures and step erosion in the beddings surface at the same time.

Geology of Salt Dome and Salt Cave

Namakdan Salt dome has an outcrop of 7 kilometer in diameter. This feature has covered the western plunge of Salakh Anticline. Namakdan Salt Dome has been formed from Hormoz Series deposits (preCambrian-Cambrian).

Because of its plasticity nature, it was always inclined to rise up to escape the pressure by upper rocks. Field evidences and seismic logs shows that Hormoz Series had a very slow movement and uplifting; so caused to thinness of the sedimentary formations and making slop in the basement.

Namakdan Salt Cave is located inside Namakdan Salt Dome resulting Karst process and salt dissolution and forming underground channels and galleries. Inside the cave there are different types of sedimentary forms and speleothems. Erosion forms are more than sedimentary forms because of the water high capacity of saturation.

Keywords: diapir , Geopark , Hormoz Series , Hormozgan province , Iran Geology , Iran Geotourism , Namakdan Cave , Namakdan dome , Qeshm Island , world longest salt cave , zamingasht