Geology of Ethiopia and the Horn PDF

Summary

This document introduces the study of the geology of Ethiopia and the Horn. It covers the evolution of Earth, the materials that make up the Earth, and the processes acting on them. The chapter explores the geologic forces, geologic time scale, and age dating techniques used to analyze land-forms, geological time scale and age dating techniques. It also covers specific knowledge and hypotheses on continental drift and provides an outline of the geological processes and resulting landforms related to the geologic history of Ethiopia.

Full Transcript

CHAPTER TWO
THE GEOLOGY OF ETHIOPIA AND THE HORN

2.1. Introduction
Geology is an Earth science that studies the evolution of the earth, the materials of which it is
made of, and the processes acting upon them. Much of Geology is concerned with events that
took place in the remote past when no one was around to witness them and with features which
are far beneath the earth‟s surface where no one can see them. A great deal of geological
understanding must, therefore, be obtained by inference, using clues from what can be seen and
what can be measured. There are many such clues not only the rocks and landforms which can be
observed and studied at the Earth‟s surface, but also those provided by indirect methods such as
geophysics (e.g. studying earthquake waves which can penetrate deep beneath the Earth‟s
surface), geochemistry (analysis of the detailed composition of rocks which can give clues as to
their origin) and geochronology (methods for finding the ages of rocks, usually from the
radioactive elements they contain).

Therefore, this chapter will focus on the geology of Ethiopia and the Horn. In this chapter, you
will study the geologic forces acting up on earth and their resulting land form, geological time
scale and age dating techniques.

Objectives
After completing this chapter, the students will be able to:
 Analyze the geologic processes and the resultant land forms of Ethiopia and the Horn.
 Examine the formation of the Rift Valley.
 Recognize the current status of Ethiopian mineral endowment associated with geologic
processes.

The earth‟s continents were once bunched up together in to a single huge continent called
Pangaea. The large super continent was then split into Gondwanaland where Africa is a part
and Laurasia; and later into smaller fragments over the last million years. These then drifted
apart to form the present arrangement of continents.

Australian Climatologist Alfred Wegener proposed the hypothesis that the continents were
once assembled together as a supercontinent, called the Continental drift Theory.

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Wegener‟s principal observations were:

 Fit of the continents: The opposing coastlines of continents often fit together.
 Match of mountain belts, rock types: If the continents are reassembled as Pangaea,
mountains in West Africa, North America, Greenland, and Western Europe match up.
 Distribution of fossils: The distribution of plants and animal fossils on separate
continents forms definite linked patterns if the continents are reassembled.
 Paleoclimates: rocks formed 200 million years ago in India, Australia, South America,
and southern Africa all exhibited evidence of continental glaciations.

2.2. The Geologic Processes: Endogenic and Exogenic Forces
Geology studies of how Earth's materials, structures, processes and organisms have changed over
time. These processes are divided into two major groups: internal and external processes.

The internal processes (endogenic) include volcanic activity and all the tectonic processes
(folding, faulting, orogenesis (mountain building), and epeirogenesis (slow rising and sinking of
the landmass). These processes result in building of structural and volcanic features like plateaus,
rift valleys, Block Mountains, volcanic mountains, etc.

The external (exogenic) processes are geomorphic processes. They include weathering, mass
transfer, erosion and deposition. They act upon the volcanic and structural landforms by
modifying, roughening and lowering them down.

The landmass of Ethiopia, as elsewhere, is the result of the combined effect of endogenic and
exogenic processes. The brief geological history of Ethiopia and the Horn will be dealt
chronologically starting from the oldest Era of the Earth‟s history to the recent.

2.3. The Geological Time Scale and Age Dating Techniques
The geological history is divided in to Eras. Each Era is divided into periods. The Eras are given
names that indicate the kind of life that existed in them. For instance, the Paleozoic Era (ancient
life) is the age of invertebrates, the Mesozoic Era (the middle life) is the age of reptiles while the
Cenozoic Era (recent life) is the age of mammals. These geological time divisions basically
differ from each other in such characteristics as the relative position of land and sea, the kind of
climate and most important the kind of animal and plant life that developed and existed during
that Era or period. Geological time is difficult to measure precisely.
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The Earth is believed to have been formed approximately 4.5 billion years ago and the earliest
forms of life were thought to have originated approximately 3.5 billion years ago. The first major
boundary is defined by what was believed at the time to be the first appearance of life on earth.
The span of time before life appeared was termed the Precambrian Era. To describe the geology
and history of life on Earth, scientists have developed the geological time scale. The geological
time scale measures time on a scale involving four main units:

1. An epoch is the smallest unit of time on the scale and encompasses a period of millions
of years.
2. Chronologically, epochs are clumped together into larger units called periods.
3. Periods are combined to make subdivisions called Eras.
4. An eon is the largest period of geological time.
The division of time units in the geological time scale is usually based on the occurrence of
significant geological events (e.g. mass extinctions). As such, the geological time categories do
not usually consist of a uniform length of time. The geological time scale, illustrated in Table
2.1, is built largely on the basis of life and evolution.

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Table 2.1: The Geological time scale

Era Period Began (in Million Years) End (my) Major Events (million years ago)

Quaternary 1.6 Present Major glaciers in North America
Cenozoic

and Europe (1.5)
Tertiary 70 1.6 Rocky Mountains (65), individual
continents take shape.
Cretaceous 146 70 Dinosaurs extinct (65), western
interior seaway and marine reptiles
(144 – 65)
Mesozoic

Jurassic 208 146 Pangaea (one land mass) begins to
break up (200)
Triassic 225 208 First mammals and dinosaurs

Permian 290 225 Greatest extinction on Earth (245)
Pennsylvani 322 290 First reptiles
an
Mississippia 362 322 Coal-forming forests
n
Devonian 408 362 First land animals and first forests
Paleozoic

(408)
Silurian 439 408 Life invades land

Ordovician 510 439 First fish appeared

Cambria 600 510 Great diversity of marine
invertebrates
Proterozoic 2,500 600 Marine fossil invertebrates (600)
Precambrian

Archean 4,500 2,500 Earliest fossils recorded (3,500),
earliest rock formation (4,000)

Age Dating Techniques

There are two techniques of knowing the age of rocks: Relative and absolute age dating.

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A. Relative Dating
Relative dating uses geological evidence to assign comparative ages of fossils. Hence, we can
use two ways to know the relative age of a rock: one way is to look at any fossils the rock may
contain. If any of the fossils are unique to one of the geologic time periods, then the rock was
formed during that particular time period. The second way is to use the "What is on top of the
older rocks?" When you find layers of rocks in a cliff or hillside, younger rocks are on top of
older rocks. But these two methods only give the relative age of rocks -which one is younger and
which is older.
B. Absolute Dating
Also known as Radiometric techniques. This technique was developed with discovery of
radioactivity in 1896. The regular rates of decay for unstable, radioactive elements were found to
constitute virtual “clocks” within the earth‟s rocks. Radioactive elements such as uranium (U)
and thorium (Th) decay naturally to form different elements or isotopes of the same element.
Every radioactive element has its own half-life.

At the end of the period constituting one half-life, half of the original quantity of radioactive
element has decayed; after another half-life, half of what was left is halved again, leaving one-
fourth of the original, and so on. Two of the major techniques include:

A. Carbon-14 Technique: Upon the organism‟s death, carbon-14 begins to disintegrate at a
known rate, and no further replacement of carbon from atmospheric carbon dioxide can
take place. Carbon-14 has half-life of 5730 years.

B. Potassium-Argon Technique: The decay is widely used for dating rocks. Geologists are
able to date entire rock samples in this way, because potassium-40 is abundant in micas,
feldspars, and hornblendes. Leakage of argon is a problem if the rock has been exposed
to temperatures above 125° C (257° F), because the age of the rock will then reflect the
last episode of heating rather than the time of original rock formation.

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2.4. Geological Processes and the Resulting Landforms of Ethiopia and the Horn

Activity 2.1

1. Distinguish between endogenic and exogenic processes.
2. What are the major geological processes and the resulting landforms of Ethiopia and the
Horn in each Era?

2.4.1. The Precambrian Era Geologic Processes (4.5 billion - 600 million years ago)

The Precambrian Era covers 5/6th of the Earth‟s history. Due to its remoteness in time and the
absence of well-preserved fossils, our knowledge of the events is limited. Nevertheless, some
general description of the main geologic processes can be made.

The major geologic event of the Precambrian Era was Orogenesis. As a result, the land was
subjected to intense folding. This was accompanied by intrusive igneous activity. The result was
the formation of huge mountain ranges. In between the orogenic periods and after the last
orogenesis, there were long periods of denudation, which finally reduced these mountains to
near-level (peneplained) rock surfaces. This “levelled” surface was later (in the Mesozoic and
Cenozoic Eras) covered by younger rock formations. Therefore, in most parts of Ethiopia rocks
belonging to this Era are found beneath all other rocks, forming the basement rocks. Since, they
had been subjected to pressure and heat from overlying weight, earth movements (folding,
orogenesis) and to intrusive igneous activity; the original rocks (both sedimentary and igneous)
were altered into metamorphic rocks of varying stages of metamorphism. Since these same
processes have allowed mineralization and crystal formation, the rocks are also collectively
described as crystalline rocks.The Precambrian rocks are overlaid by recent rock formations.
However, as surface rocks covering 25% of the land mass of the country; they are found exposed
in the following areas:
In the northern part: Western lowlands, parts of northern and central Tigray.

A. In the western Part: Gambella, Benishangul-Gumuz (Metekel and Asossa), western
Gojjam, western Wellega, Illuababora, and Abay gorge.
B. In the southern Part: Guji, southern Omo, and parts of southern Bale and Borena.
C. In the eastern part: Eastern Hararghe.

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2.4.2. The Paleozoic Era Geologic Processes (600 million - 225 million years ago)
The Paleozoic Era lasted for about 375 million years. The major geological process of this Era
was denudation. The gigantic mountains that were formed by the Precambrian orogeny were
subjected to intense and prolonged denudation. At the end, the once gigantic mountain ranges
were reduced to a “peneplained” surface. Undulating plain with some residual features
(inselbergs) here and there was formed. The sediments were transported southward and eastward
to form continental (in Africa) and marine deposits, respectively. Because of the limited
deposition within Ethiopia, rocks belonging to this Era are rare in the country.

2.4.3. The Mesozoic Era Geologic Processes (225-70 million years ago)

This Mesozoic Era lasted for about 155 million years. It was an Era of alternate slows sinking
and rising (epeirogenesis) of the landmass. This process affected the whole present-day Horn of
Africa and Arabian landmass. At the same time the land was tilted eastward and therefore lower
in the southeast and higher in the northwest.
The subsidence of the land began about 225 million years ago. As the land sank slowly the sea
invaded it starting from Somalia and Ogaden and slowly spreading northwestward. This was in
late Triassic. This phenomenon continued up to Jurassic period. As the shallow sea spread
towards the land, sands were deposited over the peneplained Precambrian rock surface. As the
depth of the sea increased, mud (shale), gypsum and later lime were deposited. The latter is
associated with the flourishing of marine life and decaying and precipitating of their remains, as
the sea stayed long. Hence, Mesozoic rocks are considered to have the greatest potential for oil
and gas deposits.
Through time, compression by the overlying rocks and by cementing minerals, the sands and
lime were compacted to form sandstone and limestone layers respectively. These are known as
the Adigrat sand stone and Hintalo limestone layers. They are named after place names in Tigray
where they might have been first identified.

In the Horn of Africa and Ethiopia, the slow rise of the land and consequently the regression of
the sea began in the Upper Jurassic. It continued throughout the Cretaceous period. With the
retreat of the sea, another process of deposition occurred. In the country sedimentation ended
with the deposition of clay, silt, sand conglomerate brought in from the land as the sea receded
due to uplift of the landmass. Gypsum, shale and at last sands were laid over the Hintalo
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limestone. The uppermost layer is known as the Upper sandstone. By the end of the Mesozoic
Era, when the land emerged out of the sea, three major sedimentary formations were laid and
formed upon the Precambrian rock surface. These were the Adigrat or lower sandstone, Hintalo
limestone and Upper Sandstone. As transitional formations, gypsum and shale were inter-
bedded above and below the Hintalo limestone. The Mesozoic sedimentary rocks cover 25% of
the land mass of the country.
Due to the tilting of the landmass during the transgression and regression of the sea, and due to
the direction of the invading and retreating sea, the age and thickness of the Sandstone layers
vary in a Southeast - Northwest direction. The Adigrat sandstone is older and thicker in the
southeast and progressively decreases in age and thickness northwestward. The Upper sandstone,
on the other hand, is thicker and younger (Upper Cretaceous) in the Southeast, while in the
Northwest it is older and thinner.

The transgressing sea and Mesozoic sediments nearly covered the whole of Ethiopia. The
northwestern limit was as far as central Tigray, and western slopes of Western highlands. In most
parts of Ethiopia, the Mesozoic rocks are overlaid by the Cenozoic rocks. As surface rocks,
these old marine sediments are extensively found in the Southeast lowlands. Other exposures
include central Tigray, and along the gorges of Abay and Wabishebelle rivers

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Figure 2.1. Geological map of Ethiopia Source: CSA Shapefile, 2012
2.4.4. The Cenozoic Era Geologic Processes (70million years ago - Present)
The Cenozoic Era is the most recent of the geologic Eras. The tectonic and volcanic activities
that took place in this Era have an important effect in the making of the present-day landmass of
Ethiopia and the Horn of Africa. The land was subjected to two major geologic events and other
geologic processes of lesser magnitude but still important. These geologic activities are:

a. Uplifting of the Arabo-Ethiopian landmass and outpouring of huge quantity of lava.
b. Formation of the Rift Valley.
c. Quaternary volcanism and deposition.
 Uplifting of the Arabo-Ethiopian landmass and outpouring of lava flood
The uplifting of the whole of the Arabo-Ethiopian landmass is a continuation of the slow rise that
began in the Upper Jurassic and Cretaceous periods. This huge uplift continued to the Paleocene
and Oligocene epoch of the Tertiary period. Where the uplifting was of greater magnitude, the
land was pushed up to a maximum height of 2,000 meters above sea level. This occurred during
the Eocene epoch. This uplifting was of an epeirogenic character. It was unparalleled anywhere
else except in the Alpine orogenic belts of the Andes. The whole of the Arabo-Ethiopian
landmass was pushed up in blocks as one mass. The greatest uplift was in central Ethiopia. This
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immense tectonic force also fractured the crust at many places. Huge quantity of lava came out
through these fractures. The out pouring of this flood of basalt spread widely and extensively
and covered a large part of the Mesozoic sedimentary layer to form the Ethiopian plateau surface
and also the floor of the present-day Rift Valley. At that time the Rift Valley was not yet formed.
The mass of lava was so immense, that it formed a thick layer of volcanic rocks on the plateau,
which mounted to more than 1,000 meters above sea level in the north Central Highlands. Where
the lava comes out through vents, huge volcanic rocks were piled up to form many and huge
Volcanic Mountains‟ towering the flat basaltic plateau. This volcanic material is known as
Trappean lava or Trap Series lava. Where it is not dissected by erosion, the Ethiopian plateau had
flat and nearly horizontal surface. This is an expression of the peneplaned Precambrian surfaces,
the smothering effect of the Mesozoic deposition, and the spreading of the Trap series lava over
the Mesozoic sediments.

 The Formation of the Rift Valley
The formation of the Rift Valley is said to be related with the theory of plate tectonics.
According to the theory, the Rift Valley may be lying on the Earth‟s crust below which lateral
movement of the crust in opposite directions producing tensional forces that caused parallel
fractures or faults on the sides of the up-arched swell. As the tension widened the fractures, the
central part of the landmass collapsed to form an extensive structural depression known as the
Rift Valley (Fig. 2.2).

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Figure 2.2.The Ethiopian and East African Rift Valley systems.
Source: Africa Map Library

The major faulting movement probably began in the late Oligocene and Miocene Epochs of the
Cenozoic Era. This rifted the Red Sea trough, which began to be flooded from the north. But the
major rifting, affecting the whole African Rift System, including that of Ethiopia and the Gulf of
Aden took place in the Miocene Epoch. Rifting and faulting, however, continued all the time
throughout the Pliocene and even the Pleistocene Epochs.

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The Red Sea and the Gulf of Aden were connected as a result of the rifting and faulting of the
land bridge that separated them. At the same period (Pliocene), the Afar depression (including
the Gulf of Zula) was down-faulted allowing the Red Sea water to penetrate far inside. Reversed
tilting and volcanic activity, later (Pleistocene) blocked the connection and isolated the extension
of the sea, allowing much of the water to evaporate. As a result, thick saline materials
accumulated. During the same period, the area between the Danakil Depression and the Red Sea
was uplifted to form the Afar Block Mountains.

The Spatial Extent of the Rift Valley
The Ethiopian Rift Valley is part of the Great East African Rift system that extends from
Palestine-Jordan in the north to Malawi-Mozambique in the south, for a distance of about 7,200
kilometers. Of these, 5,600 kilometers is in Africa, and 1,700 kilometers in Eritrea and Ethiopia.
On land, the widest part of the Rift Valley is the Afar Triangle (200-300 km). The Red Sea, the
Gulf of Aden, and the East African System meet and form the triangular depression of the Afar
where the Kobar Sink lies about 125 meters below sea level. The formation of the Gulf of Aden
and the separation of the Arabian Peninsula from the Horn of Africa also took place during the
Tertiary period. The Rift Valley region of Ethiopian is the most unstable part of the country.
There are numerous hot springs, fumorales, active volcanoes, geysers, and frequent earthquakes.
The formation of the Rift Valley has the following structural (physiographic) effects:

 It divides the Ethiopian Plateau into two.
 It separates the Arabian landmass from African landmass.
 It causes the formation of the Dead Sea, Red Sea and the Gulf of Aden troughs.
 It creates basins and fault depressions on which the Rift Valley lakes are formed.

Faulting and graben formation are not only limited to the Rift Valley. For example, similar
tectonics activities have occurred in the Lake Tana Basin. However, the formation of Lake Tana
had been accentuated by volcanic activity so that lava flow in the southeast had dammed part of
the rim to deepen the basin. Faulting in other places had a structural control along some part of
the river courses.

 Quaternary Volcanic Eruptions and Depositions
They are recent volcanic activities that took place after the formation of the Rift Valley. This
occurred in the Pliocene-Pleistocene Epochs. This is a continuation of the tectonic and volcanic
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processes that earlier affected the Rift Valley formation. It occurred in the form of renewed
rifting/faulting and more volcanism. This activity was generally limited to the floor of the Rift
Valley and the region south of Lake Tana, where the lava covers an area of more than 3,000km2.
Aden volcanics and recent faulting are more extensively developed in the Afar region. The area
is shattered by numerous faults and subjected to extensive scoriaceous basalt eruptions. The
latter phenomenon is also widely manifested in the main Ethiopian Rift, especially in its northern
section. Some of the eruptions have occurred in the last few hundred years. Because of their
recent occurrence, the Aden volcanics have relatively well-preserved and visible morphological
features. The basic volcanic features of the Aden series include the following:

 Numerous and freshly preserved volcanic cones, many of which have explosive craters.
Some of these are active Dubi, Erta Ale, Afrera etc.Of these, Erta Ale is the most active
volcano in Ethiopia.
 Volcanic hills and mountains, some of which are semi-dormant (Fantale, Boseti-Gouda
near Adama, Aletu north of Lake Ziway, Chebbi north of Lake Hawassa etc.).
 Extensive lava fields and lava sheets some of which are very recent.
 Lava ridges.
 Thermal springs, fumaroles etc.
Quaternary Deposition

During the Quaternary period of the Cenozoic Era, the Earth experienced a marked climatic
change, where warmer and dry periods were alternating with cooler and wet periods. This was
the time of the last „‟Ice Age‟‟ in the middle and high latitude areas and the time of the „„Pluvial
Rains‟‟ in Africa. The heavy Pluvial Rains eroded the Ethiopian plateau and the eroded materials
were deposited in the Rift Valley lakes.

The excessive rain resulted in an excessive surface flow; rivers were many and large. They
carried a lot of water and sediments. Lake and marshy areas became numerous and deep. Many
were enlarged and covered much area and even merged together. For example, Ziway-Langano-
Shalla; Hawasa-Shallo; Chamo-Abaya; and Lake Abe and the nearby smaller lakes and marsh
basins formed huge lakes.

After the „„Pluvial Rains‟‟, the Earth‟s climate became warmer and drier. Thus, it increased the
rate of evaporation that diminished the sizes of the lakes. Today, there are lacustrine deposits of

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continental origin around many of the Ethiopian lakes, river valleys and lowlands. According to
the place and manner of deposition and depositing agents these deposits are divided as follow.

a. Lacustrine deposits: Deposits on former lakebeds, and swampy depressions.
b. Fluvial deposits:Deposits on the banks of rivers, flood plains both in plateau, foothills
etc.
c. Glacio-fluvial deposits and erosional features: These are occurred on high mountains,
such as Bale and Kaka Mountains.
d. Aeolian deposits:Are windblown deposits.
e. Coastal and marine deposits: Deposits on sea invaded and sea-covered places.
The quaternary deposits are mainly found in the Rift Valley (Afar and Lakes Region), Baro
lowlands, southern Borena, and parts of northwestern low lands. Generally, the Cenozoic rocks
cover 50% of the land mass of the country. These include Highland Tertiary volcanics (basalts),
Tertiary as well as Quaternary volcanics, and sediments of the rift valley.

2.5. Rock and Mineral Resources of Ethiopia
The occurrence of metallic minerals in Ethiopia is associated with the Precambrian rocks.
Although not in sufficient concentration and extent, a great variety of such minerals occur in the
basement rocks. These rocks contain most of the metallic deposits known at present.

The exploitation and search for mineral deposits in Ethiopia has been taking place for the past
2,000 years or so, and its early cultures were based partially on the mineral wealth of the day.
Such has been the case of gold production and utilization, which has become part of Ethiopia‟s
history, tradition and folklore. The mining and working of iron for the manufacture of tools,
utensils and weapons, and the use of salt and salt-bar all these indicate to a fairly long mining
tradition. However, presently mineral production from Ethiopia has been negligible by World
standards.

2.5.1. Brief Facts and Current State of Main Minerals in Ethiopia

Geological surveys proved that Ethiopia has abundant mineral resources of metals and precious
metals, coal, and industrial minerals.

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Gold
Gold has been mined in Ethiopia for quite long time, mainly from Benishangul-Gumuz
(Metekel) and Adola. Operating mines produce gold from primary sources in such localities as
Dermi-dama, Sakoro and Lega-dembi. Mechanised alluvial working is confined to the state-
operated gold field of Adola. Secondary gold deposits are common in the following localities:
Adola, Murmur Basin, Shakiso, Awata Basin, Dawa Basin, Ghenale Basin, Ujama
Basin,Makanisa (Guba and Wombera), Kaffa. In Gambella and Illuababora (Akobo River), in
Sidama (Wondo), Borena (Negele-Yabelo area) and in Benishangul-Gumuz (Sherkole), west
Wellega, Mengi-Tumat-Shangul areas to the Sudanese border, and the drainage of the Didessa
and Birbir.
Platinum
The Yubdo area in Wellega, is the only active Ethiopian Platinum mine. Platinum occurrences
have been reported from Delatti in Wellega, and the valley of Demi-Denissa and Bone Rivers as
well as Tullu Mountain area in Sidama.
Tantalum
Significant deposit of tantalum and niobium is found in southern Ethiopia. It occurs in Adola
area where Kenticha Tantalum mine with resources of more than 17,000 metric tons of world
class ore reserve is found.
The sedimentary and volcanic rock activities are also resourceful. Extensive lignite deposits in
Ethiopia are found in Nedjo (Wellega), and in small amounts in Chilga (Gonder) are found in the
sedimentary formations laid in between Trapean lava. However, important Lignite, one of the
lowest ranked coal, is known to occur in many localities such as in the Beressa Valley and
Ankober (North Shewa), Sululta (nearAddis Ababa),Muger Valley (West Shewa), Aletu valley
(near Nedjo), Kariso and Selmi Valleys (Debrelibanos), Zega wodem gorge (near Fiche),
Didessa Valley (southwest of Nekemte), Kindo and Challe Valley (Omo confluence),
Adola,Wuchalle (north of Dessie), Chukga area (on Gonder-Metema road), Dessie area (near
Borkena River). These areas are promise to be a good prospect to meet some of the local
industrial and domestic needs.
Gemstones
Gemstones, including amethyst, aquamarine, emerald, garnet, opal, peridot, sapphire, and
tourmaline occur in many parts of Ethiopia, mainly in Amhara and Oromia Regional States.

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Quality Opal was first discovered by local people in Wadla and Dalanta woredas, North Wello in
Amhara Regional State.

Potash
The potash reserve in the Danakil (Dallol Depression) of the Afar region is believed to be
significant.

Gypsum and Anhydrite
A limited amount of gypsum is produced for domestic consumption in Ethiopia, mainly for the
cement industry, but very large deposits are known to occur in sedimentary formations of the
Red Sea coastal area, Danakil Depression, Ogaden, Shewa, Gojjam, Tigray, and Hararghe. Total
reserves are probably enormous because the thickness of the gypsum deposits is many hundreds
of meters and the formation are known to extend laterally for hundreds of kilometers.

Clay

Ethiopia is endowed with industrial clay material. Alluvial clay deposits for bricks and tile,
pottery and pipe industry occur in Adola, Abay gorge, and the Rift Valley lakes region. Ceramic
clay for the production of glasses, plates, bricks is found at Ambo and Adola. Tabor ceramic
industry in Hawassa gets most of its raw materials from local sources.

Marble
Crystalline limestone is widespread in the basement rocks of Ethiopia. Marble has been quarried
in such localities as west of Mekelle and south of Adwa in Tigray. In the east in Galetti, Soka,
Ramis, Rochelle, Kumi and other valleys of Chercher Mountain in West Hararghe. In the
northwestern also in areas built of Precambrian schist in Gonder, and the Dabus River and other
neighboring river basins in Benishangul-Gumuz and Gojjam.

Construction stones
Basalt, granite, limestone and sandstone are important building stones. For the surfacing of roads
and compaction, basalt, scoria and other volcanic rocks are extensively used. Mesozoic
limestone is an important raw material for cement and chalk production. The earlier cement
works at Dire Dawa and the recent ones at Muger Valley, Abay gorge (Dejen), Tigray (Messebo)
are using similar raw materials from these rock formations.

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2.5.2. Mineral Potential Sites of Ethiopia

According to the Ethiopian geological survey, the geologic formations that host most mineral
potentials of Ethiopia includes three major greenstone belts and other formations (Fig. 2.3).
These are:
1. The Western and South-western-greenstone belt: They contain various minerals: primary
gold occurrences (Dul,Tulu-Kape,Oda-Godere, Akobo,Baruda,Bekuji-Motish and
Kalaj);Yubdo Platinum, Base metals of AzaliAkendeyu, Abetselo and Kata;Fakushu
Molybdenite and the iron deposits of Bikilal, Chago, Gordana and Korre, Benshagul-Gumuz-
Marble, Akobo and Asosa placer gold deposits and etc.
2. The Southern greenstone belt:It is known as the Adola belt, which comprises the primary
gold deposits and occurrences of Lega-dembi, Sakaro, Wellena, Kumudu, Megado-Serdo,
Dawa Digati, Moyale and Ababa River;the columbo-tantalite of kenticha and Meleka, andthe
Adola nickel deposit and other industrial minerals.
3. The Northern greenstone belt(Tigray): This belt comprises of the primary gold occurrences
of Terakemti, Adi-Zeresenay, and Nirague.The base metals of Terer, Tsehafiemba and other
parts of Tigray, Placer gold occurrences of Tigray.
Review Questions
Answer the following questions briefly.
1. What were the major geologic processes of the Precambrian and Paleozoic Eras in the
Horn of Africa?
2. Explain the formation of the oldest sedimentary rocks in Ethiopia and the Horn.
3. Discuss the major geologic events of Ethiopia that took place during the Cenozoic Era.
4. Where are the major mineral potential sites of Ethiopia? Discuss each of them with the
help of examples.

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