Grade 11 Geography Textbook - Ethiopia PDF

Summary

This textbook covers various aspects of geography, including the formation of continents, climate classification, natural resources, and population dynamics. It is targeted at Grade 11 students in Ethiopia. The authors are experts in various geography topics.

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Ermias Debie(PhD)
Mehretie Belay(PhD)
Professor Aklilu Dalelo
Fekede Menuta (PhD)
Abera Husen (PhD)
Mesfin Anteneh (PhD)
Andargachew Abeje (MSc)

Evaluators: Teferi Makonnen (PhD)
Abebe Yibeltie (MA)
Hussien Seid (MA)
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First Published by the Federal Democratic Republic of Ethiopia, Ministry of Education, under
the General Education Quality Improvement Program for Equity (GEQIP-E) supported by the
World Bank, UK’s Department for International Development/DFID-now merged with the For-
eign, Common wealth and Development Office/FCDO, Finland Ministry for Foreign Affairs, the
Royal Norwegian Embassy, United Nations Children’s Fund/UNICEF), the Global Partnership
for Education (GPE), and Danish Ministry of Foreign Affairs, through a Multi Donor Trust Fund.

© 2023 by the Federal Democratic Republic of Ethiopia, Ministry of Education. All rights
reserved. The moral rights of the author have been asserted. No part of this textbook repro-
duced, copied in a retrieval system or transmitted in any form or by any means including elec-
tronic, mechanical, magnetic, photocopying, recording or otherwise, without the prior written
permission of the Ministry of Education or licensing in accordance with the Federal Democratic
Republic of Ethiopia as expressed in the Federal Negarit Gazeta, Proclamation No. 410/2004

Copyright and Neighboring Rights Protection.
The Ministry of Education wishes to thank the many individuals, groups and other bodies
involved – directly or indirectly – in publishing this Textbook. Special thanks are due to Ha-
wassa University for their huge contribution in the development of this textbook in collabora-
tion with Addis Ababa University, Bahir Dar University and Jimma University.

Copyrighted materials used by permission of their owners. If you are the owner of copyrighted
material not cited or improperly cited, please contact the Ministry of Education, Head Office,
Arat Kilo, (P.O.Box 1367), Addis Ababa Ethiopia.
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TABLE OF CONTENTS

UNIT ONE
FORMATION OF
THE CONTINENTS
Formation of the Continents..........................................................................................................................................1
1.1. Formation of the continents and oceans...............................................................................................................2
1.2. Geological timescale.............................................................................................................................................................7
1.3. Distribution of the continents and oceans..........................................................................................................16
1.4. Changing position of the continents and oceans..........................................................................................21
Unit Summary......................................................................................................................................................24
Review Exercise.....................................................................................................................................................25

UNIT TWO

Climate Classification and Climate Regions of Our World.......................................................27
2.1. Criteria for climate classification...............................................................................................................................28
2.2. K ppen’s climate classification..........................................................................................................................................30
2.3. World climatic regions................................................................................................................................................................39
2.4. Factors influencing the world climatic regions.....................................................................................................45
2.5. Local/indigenous climate classification of Ethiopia.........................................................................................52
Unit Summary.................................................................................................................................................................55
Review Exercise..............................................................................................................................................................56
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TABLE OF CONTENTS

UNIT THREE
NATURAL RESOURCES AND
CONFLICTS OVER RESOURCES
Natural Resources and Conflicts Over Resources..................................................................................58
3.1. The functions and management of land....................................................................................................................59
3.2. Resources under pressure........................................................................................................................................................63
3.3. Land resource depletion and degradation...............................................................................................................69
3.4. Transboundary rivers.....................................................................................................................................................................74
3.5. Regional cooperation for sustainable use of transboundary rivers.....................................................79
3.6. Potential and actual use of water in Ethiopia, Sudan and Egypt...........................................................82
3.7. Conflicts over resources............................................................................................................................................................86
Unit Summary.................................................................................................................................................................9
Review Exercise.............................................................................................................................................................

UNIT FOUR
GLOBAL POPULATION
DYNAMICS AND CHALLENGES
Global Population Dynamics and Challenges.............................................................................................9
4.1. The growth of world population............................................................................................................................
4.2. Factors responsible for accelerated population growth........................................................................10
4.3. International migrations.............................................................................................................................................11
4.4. Population policies....................................................................................................................................................................1
Unit Summary............................................................................................................................................................12
Review Exercise...........................................................................................................................................................12
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UNIT FIVE

GEOGRAPHY AND ECONOMIC
DEVELOPMENT
Geography and Economic Development......................................................................................................12
5.1. Effects of geographic location on development...............................................................................................
5.2. Climate extremes and poverty..................................................................................................................................
5.3. Disadvantages of landlocked countries.............................................................................................................
5.4. Intraregional trade in Africa.......................................................................................................................................
Unit Summary............................................................................................................................................................................ 6
Review Exercise............................................................................................................................................................................1

UNIT SIX
MAJOR GLOBAL
ENVIRONMENTAL CHANGES
Major Global Environmental Changes..............................................................................................................1
6.1. Persistent environmental problems..........................................................................................................................16
6.2. Poverty–environment nexus.........................................................................................................................................1
6.3. Environmental degradation and sustainable development...................................................................1
Unit Summary............................................................................................................................................................1
Review Exercise.........................................................................................................................................................1
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UNIT SEVEN
GEOGRAPHIC ISSUES AND
PUBLIC CONCERNS
Geographic Issues and Public Concerns.......................................................................................................1
7.1. Population related concerns of our contemporary world............................................................1
7.2. Land degradation and desertification.........................................................................................................................
7.3. Recurrent drought and famine.....................................................................................................................2
7.4. Deforestation.......................................................................................................................................................2
7.5. Worldwide Digital Divide................................................................................................................................2
Unit Summary......................................................................................................................................................21
Review Exercise.................................................................................................................................................21

UNIT EIGHT
GEO-SPATIAL INFORMATION
AND DATA PROCESSING
Geo-spatial Information and Data Processing..........................................................................................21
8.1. Representations of relief features on topographic maps......................................................................................2
8.2. Basic concepts of Geographical Information System (GIS)............................................................................2
8.3. Arcmap and main tools..........................................................................................................................................................................23
Unit Summary.............................................................................................................................................................................24
Review Exercise..........................................................................................................................................................................24
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UNIT ONE
At the end of this unit, you will be able to:

recognize the Earth’s geological history;
describe the formation of the Earth’s Continents;
explain the relative distribution of Continents and Oceans
overthe Globe; and
appreciate the changing positions of the Earth’s Continents and
Oceans over geological times.

Main Contents :
1.1. Formation of the continents and oceans
1.2. Geological timescale
1.3. Distribution of the continents and cceans
1.4. Changing positions of the continents and oceans

Introduction
Students, do you remember the lessons on ‘Geological History of Ethiopia’ and ‘Landforms
of Africa’ in your Grade Nine and Ten Geography, respectively? If yes, can you tell us what
geological history is and how the landforms of Africa have been developing? In unit one of
Grade 11 Geography you are going to learn about the timescale of the Earth’s geological
processes; the development stages of the earth’s continents; and the relative position
(distribution) of the Earth’s oceans and continental landmasses. With these basic contents
you are; therefore, expected to be aware of and appreciate the Earth’s geologic timescales,
formation of the continents, and relative position/distribution of the Earth’s oceans and
continental landmasses.
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UNITUNIT TWO
ONE

1.1. FORMATION OF CONTINENTS
This section presents how the Earth and continents evolved. The topic takes you to the wider
scientific wisdom of the origin of the Earth and its Continents.

At the end of this section, you will be able to:
examine how the Earth was created; and
describe how the Earth’s continents evolved.

Keywords:
Big bang Pangaea
Continents Rodinia
Continental drift Sea-floor spreading
mid-oceanic Solar system

Brainstorming Activity 1.1

Please attempt the following questions first individually
and then in groups:

1. Do you know how the Earth was formed or
created?
2. What do you imagine about the formation of the
Earth and Continents?

The Earth, together with other planets and their moons, form the planetary system. The Sun and
the planets together again form the Solar System (Sun System; see Figure 1.1). The formation
of the Earth is thus attributed similar to the creation of other companion planets and the
entire development of the Solar System. Therefore, it is necessary to comprehend the origin of
the Solar System to understand the foundation of the Earth.

As can be learned from Earth Science literature, there are different views and theories on
the formation of the Earth and that of the Solar System. However, most of the theories
depend on speculation and ambiguous assumptions. None of them are capable of acceptably
demonstrating all the ultimate features of the Earth and the Solar System.
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Among the various assumptions and theories proposed about the formation of the Universe
and Earth, the “Big Bang” is most widely supported by scientists. According to this theory,
the Universe originated sometime 10–20 billion years ago by an abrupt cosmic explosion
initiated by the expansion of a small volume of matter at an exceedingly high density and
temperature. This space explosion was then followed by the formation of numerous space
objects like the Sun, planets (Figure 1.1), stars, meteors, asteroids, and comets through material
collision, cooling, and gravitational attraction. Our Earth was thus created from the mixture of
gas and dust particles moving in space around the Sun about 4.5 billion years ago.

Figure 1.1 The Solar System (Sun & Planets) [Wicander & Monroe, 2010]

Brainstorming Activity 1.2

Discuss the questions below with your classmates and
teacher:
1. How were the continents formed/created?
2. How did the present-day continents come into being?
3. How were they separated from the Pangaea?
4. What is continental drift? How does it happen?

The first cosmic rocks solidified and created the first Earth at about 4600 to 3900 Ma. Fol-
lowing that, initial land masses gathered to form the early continent called ‘Rodinia’ (Figure
1.2).
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UNITUNIT TWO
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Figure 1.2 Neoproterozoic Supercontinent; Rodinia at about 750 Ma
(Wicander & Monroe, 2010)

During the late Cambrian period (514 Ma) the Gondwana Supercontinent had evolved around
the South Pole. Next to this four major continents (Gondwana, Baltica, Siberia & Laurasia)
came into being during 458 Ma (in the mid-Ordovician Period). Then the Laurasia continent
collided with the Baltica and closed the Iapetus Sea during the mid-Silurian (425 Ma).

The continual collision had then produced the pre-Pangaea continent during the early
Devonian period, at about 390 Ma. At about 306 Ma (in the late Carboniferous period)
the North American continent started to develop from the assemblage of rocks. By then, the
Supercontinent (Pangaea) had come into being at about 255 -210 Ma. From 210 -180 Ma
(in the Triassic period) this Supercontinent started to break apart. The break-up had continued
until the late Cretaceous. In the meantime, North America had moved away from the African
continent. During the late Cretaceous, the breaking-apart of Pangaea widened and bigger
water masses (Oceans) were created along the continental cracks. Finally, continental break-up
progressively continued during the Tertiary period; the Earth’s continents have then retained
their present position during the Quaternary (Figure 1.3).
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Figure 1.3 Continents at different Geological times (Gabler et al., 2007)
Tip: An additional information is available online for you at:
https://www.youtube.com/watch?v=6-vHe4599NE

From the preceding section, it is possible to note that the present-day continents were joined
together by forming Pangaea until about 200 Ma. At about 160 Ma, Pangaea divided into
two bigger landmasses called Gondwanaland and Laurasia by the process of continental drift.
The landmass that developed into sub-continent India moved northwards and separated from
the Gondwana continent at about 140 Ma. This occasion caused the collision of the Indian
sub-continent with Eurasia and initiated the formation of the Himalayas ranges. Some 100
Ma, Australia had separated from Antarctica and this has pronounced the break-up of the
Gondwana continent. The two giant continents (Gondwanaland & Laurasia), then moved-
apart east and west thereby resulting in the opening of the Atlantic Ocean.
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UNITUNIT TWO
ONE

NOTE

Continental drift refers to the moving apart of conti-
nents initiated by Sea-floor Spreading at mid-Ocean-
ridge locations. The event makes the Pacific Ocean
narrower, the Atlantic Ocean wider, the Mediterra-
nean Sea narrower, and the Himalayan Mountains
higher. The drift makes Australia reach the equator in
60 million years.

Please answer the following questions:

1. Explain how the Earth’s continents
were created?
2. Name the two Supercontinents that
evolved at about 200 Ma.
3. What is Pangaea?
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This topic focuses on the geological history of the Earth as condensed in the geological time-
cale, mainly on the major Earth forming processes, resultant landforms, and the successions
of interrelated life-forms.
At the end of this unit, you will be able to:
use the geological timescale for the explanation of the geological processes, re-
sultant features, and associated life-forms;
describe the difference between relative and absolute ages of the Earth’s rocks;
examine the geological eras of the earth.
Examine the Geological Eras of the Earth.

Keywords:
Absolute age Half-life
Epoch Period
Geological era Radioactive
Geological timescale decay
Isotope Relative age

Brainstorming Activity 1.3

Please organize yourself into groups and attempt the following ques-
tions:
1. Have you ever heard about the geological history of the Earth?
2. What is the geological timescale?
3. How was the age of the Earth established?
4. How do scientists determine the age of the Earth and its products?

1.2.1 Meaning of Geologic Timescale
Geological timescale is the time-frame (timetable) showing the possible age of the Earth and
its associated life-forms. It provides a review of Earth’s history and the major changes that
occurred over time. It is developed by Earth scientists through the study of Earth’s rocks.
Through
the study of rocks, scientists determine the Relative and Absolute ages of rocks.
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UNITUNIT TWO
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1.2.2. Relative and Absolute Age of Rocks

Relative age mainly depends on the analysis of the sequence of geological occurrences without
giving due regard to the exact time of origin. It focuses only on determining the sequence of
formation of events (whether the event had occurred before or later than the other related
one). This method principally depends on the study of sedimentary rocks and often applies
to local conditions interpretations. Geologists employ three basic principles (rules) during the
study of the relative age of rocks:

The principle of original horizontality indicates that layers of sediments are originally placed
horizontally under the action of gravity. This means that except for the disturbed sequences,
sedimentary rocks are always deposited in nearly horizontal beds. In the hypothetical Figure
1.4a,
the rock-layers A, B & C must have been developed in horizontal beds because they have the
same orientation. If the beds are no longer horizontal, they must have undergone deformation
after formation. The principle of superposition asserts that in an undisturbed sequence of
sedimentary rock layers (beds) or lava flows, the overlying bed is younger than the underlying
rock. For instance, in Figure 1.4b, the rock layers are placed from earliest (1) to latest (4).

Source: www.kean.
A) Original Horizontality B) Superposition C) Cross-Cutting
Figure 1.4: Sample sedimentary rock-layers

The principle of cross-cutting relationships indicates that a rock-layer that cross-cuts another
rock-layer is said to be younger than the rocks it cross-cuts. This is a condition where older
rocks are cut by younger geologic features or igneous intrusions. In Figure 1.4c, layer 3 is an
igneous intrusion created after the formation of the sedimentary layers 1 and 2.
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Absolute age refers to the actual age of rocks given in numerical values through the analysis
of the spontaneous decay of radioactive isotopes. The term isotope refers to the presence of
an element in different forms.

Radioactive decay stands for the conversion of unstable (Parent) elements into daughter (Stable)
elements through the gaining or losing of particles in their nucleus. For instance, Potassium-40
(40K) decays into Argon-40 (40Ar). Similarly, Carbon-14 (14C) changes to Nitrogen
(14N). Rubidium-87 (87Rb) converts also to Strontium-87 (87St). Likewise, Uranium-235 (235U)
change to and Lead-207(207Pb) (Table1.1).

Table 1.1 Parent and Daughter isotopes and time-taken (half-life) for conversion

No Parent isotope Daughter isotope Half-life
1 Uranium - 238 (238U) Lead – 206 (206Pb) 4.5 billion years
2 Rubidium – 87 ( Rb) 87
Strontium – 87 48.8 billion years
(87Sr)
3 Potassium-40 (40K) Argon – 40 (40Ar) 1.25 billion years
4 Uranium - 235 (235U) Lead – 207 (207Pb) 704 million years
5 Carbon-14 ( C)
14
Nitrogen – 14 ( N) 5,730 years
14

The time taken to convert from parent element to Daughter element is commonly measured in
half-lives. The half-life of an isotope is the time taken for half of the parent isotope to change
to its product atoms. The relative proportions of the Parent and Daughter isotopes are used
to determine the number of half-lives. Before conversion, 100% of the Parent prevails and no
daughter product is formed. After one half-life, 50% of the Parent remains while 50% of the
atoms are changed to Daughter atoms. After two half-lives, the number of Parent isotopes is
again halved (25%) whilst the number of Daughter atoms increases by the same amount (to
75%). For more clarity please see Table 1.2.

Table 1.2 Proportion of Parent and Daughter isotopes during radioactive decay
No No of half-lives Proportion (% of total isotopes)
Parent isotope Daughter isotope
1 0 100 0
2 1 50 50
3 2 25 75
4 3 12.5 87.5
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Radioactive decay occurs when elements recombine to form
new minerals during the processes of metamorphism or
when magma cools. Radioactive elements found in igneous
and metamorphic rocks are commonly used in rock-dating
studies. For instance, see some of the rocks used for dating
purposes in Figures 1.5 & 1.6.

As mentioned earlier, the geological timescale forms a division of geological processes and
life-forms based on standard time units through the study of fossil remains imprinted in rock
layers. The scale divides the age of the Earth into Eons, Eras, Periods, and Epochs (Table 1.3).

When the geological timescale was initially developed, the earliest fossils were found not
exceeding 600 million years (Ma) from the present (the Cambrian Period) in age. Based on
that, the part of the geological history of the earth before the Cambrian Period (the time
from 600-4500 Ma) is classified as Precambrian. Precambrian, thus, means the time before
Cambrian.

Uraninite Zircon Hornblende Glauconite
a) Sample rocks used in radiometric

Trilobite fossil Ammonite fossil Crinoid fossil
(Cambrian) (Jurassic) (Carboniferous)
b) Some index fossils used in geological
Figure 1.5 Sample rocks and index fossils used for
geological dating purposes (a,b)

Figure 1.6 Radiocarbon
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Table 1.3 Geological timescale

EON PERIOD EPOCH AGE MAJOR
(Ma)* EVENTS
C QUATERNARY Holocene Present – Modern Humans
E 0.01
N Pleisto- 0.01 – 1.6 Ice Age
O cene
Z
P O T NEOGENE Pliocene 1.6 – 5.3 Early Whominids
I E
Miocene 5.3 – 23.7
H C R
T PALEOGENE Oligo- 23.7 –
I cene 36.6
A A Eocene 36.6 – Extinction of
R 57.8 Dinosaurs
N Y
Paleo- 57.8 – 70
cene
E
M CRETACEOUS 70 - 144 First birds
R E
JURASSIC 144 - 208
S
O TRIASSIC 208 - 250 Start of Pangaea
O Z break-up; First
O mammals; First
Z I Dinosaurs
C
O P PERMIAN 250 - 286
A
PENNSYLVA- 286 - 320 Coal deposits,
I L
NIAN First Reptiles
E
O MISSISSIPPIAN 320 -360
C Z
DEVONIAN 360 - 408 First Amphibians
O
I SILURIAN 408 - 438 First land animals;
C First land plants;
ORDOVICIAN 438 - 505
First Fish

CAMBRIAN 505 - 600 First shelled
animals
PROTERO- P 600 - Formation of the
ZOIC R 2500 oldest known
E rocks and solid-
C ification of the
A earth
ARCHEAN M 2500 -
B 3900
R
HADEAN I 3900 -
A 4500
N
*Ma: Million years Crawford (1998); Wicander & Monroe (2010); www.kean.edu
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UNITUNIT TWO
ONE
Based on the geological timescale, the history of the formation of the Earth is classified into
four longer geological periods named Eons. Hadean, Archean, Proterozoic, and Phanerozoic
are four major sub-divisions of the known Eons. The Hadean, Archean and Proterozoic Eons
are often called Precambrian by scientists to refer to the geological time before the emergence
of life on Earth. The Phanerozoic is the most recent Eon. It is further sub-broken into three
Geological Eras named Paleozoic, Mesozoic, and Cenozoic (see Table 1.3).

1.2. 3.Geologic Eras

As can be learned from Table 1.3, four known Geological eras are identified in the history of
the Earth. They are the Precambrian, Paleozoic, Mesozoic, and Cenozoic. The Precambrian is
the oldest of all the geological eras. It covers the time from 600 million to 4.5 billion years
(about 85% of the geological time of the Earth). It was the time of solidification of the Earth
and the formation of the oldest rocks. Rocks created during that time are rich in base metallic
minerals and are often called crystalline basement complex rocks. Figure 1.7 indcate that they
are often found along with the continental Shields or Cratons (landscapes resisted long period
of erosion) The Hadean Eon of the Precambrian covers the time 4600 – 3900 Ma and not
much is known about it. Archean is the other Eon covering some 1400 (3900 – 2500 Ma).
The latest of the three Eons is the Proterozoic lasting from 2500–570 Ma.

Figure 1.7 Distribution of Precambrian rocks (shields) [Wicander & Mon-
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Figure1.8: Life forms evolved during the different geological eras (Crawford, 1998)
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UNITUNIT TWO
ONE
The Paleozoic era covered the time from 600 to 250 Ma from the present. It is believed that
it marked the beginning of life and is commonly referred to as the age of ancient life. Trilobites
and shelled animals (see Figure 1.8) were the common species of the time. The Devonian,
the fourth period of the Paleozoic, was rich in fish species and referred to as the age of fish.
By the end of the Paleozoic, all continents of the Earth had joined together and created the
Supercontinent named Pangaea (Figure 1.9). The creation of Pangaea led to extreme seasonal
weather changes that caused the great extinction of Earth species. Due to that, around 75% of
the Amphibian species have perished.

Figure 1.9 The Supercontinent (Pangaea) (Gabler et al., 2007)

The Mesozoic era marked the time from 250-70 Ma. It is often referred to as the era of middle
life and the age of Dinosaurs owing to their relative dominance. Turtles, snakes, crocodiles,
and lizards were among the life forms of the time. Low-lying areas were occasionally flooded
by shallow marine transgressions followed by depositions of red sandstones and mudstones.
Tropical areas were dominated by extensive swamps which later became rich coal deposits. The
mid-Mesozoic era was experiencing the splitting of Pangaea into Laurasia and Gondwanaland
(Figure 1.9). Igneous activities had initiated also the development of volcanic mountain ranges
in western North America. The end of the Mesozoic era saw the emergence of land mammals
but marked the mass extinction of Dinosaurs (see Figure 1.8).

The Cenozoic era is the recent one covering the time since 70 Ma. As it forms the recent
geologic time, it is well known compared to the other Geological eras. Birds, mammals, and
flowering plants dominante succeeded on Earth. It is commonly named an era of recent life
and the age of mammals.
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During the beginning of the Cenozoic era the the rifting of Pangaea has been fully achieved
and the continents retained their present form. Great volcanism and orogenic folding caused
the formation of numerous volcanic, fault-block, and fold mountains in the different parts of
the Earth’s continents. Glaciations were experienced in some high-latitude areas while heavy
rainfall occurred in other localities. Extinction of some mammals happened in some localities.

Orogenic is the formation of mountains, espe-
cially through the folding of the earth’s crust

Please organize yourself into groups and
answer the following questions:

1. How is the geological timescale es-
tablished?
2. What are geological eras?
3. Could you please name some of the
life forms that evolved in the differ-
ent geological eras?
4. Prepare a geologic timescale chart
using graph paper.
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UNITUNIT TWO
ONE

This topic of unit one is about the relative size and distribution of the Continental landmasses
and Oceanic basins over the Globe.
At the end of this section, you will be able to:
compare the sizes of landmasses and oceanic basins over the globe; and
locate the current positions of Continents and Oceanic basins.

Brainstorming Activity 1.4

1. How do you explain the distribution of Con-
tinents and Oceans over the Globe?
2. Show the location of the world’s Continents
and Oceans using sketch maps? Please study
the maps from your textbook and tell the an-
swer to your teacher.

The surface area of the Earth is estimated to be 510,072,000 km2 and the area of the Oceans
is about 363, 000,000 km2. All water (hydrosphere) in total covers greater than 71% of Earth’s
surface. The largest of these are the Oceans, which account for over 97% of all the water on
Earth. Glaciers and polar ice caps contain just greater than 2% of the Earth’s water in the
form of solid ice. Only about 0.6% is found under the surface as groundwater. Nevertheless,
groundwater is 36 times more plentiful than water found in lakes, inland Seas, rivers, and in
the atmosphere as water vapor.

The distribution of Ocean basins and Continents is unevenly arranged over the Earth’s surface
(see Figure 1.10). In the Northern Hemisphere, the ratio of land to ocean is about 1:1.5.
But it is 1:4 in the Southern Hemisphere. The greater abundance of water in the Southern
Hemisphere has some interesting effects on the environment of that area. For example, the
climate tends to be more moderate in the Southern Hemisphere because of the ocean’s ability
to release large amounts of stored heat energy.

The Continents
A continent is a huge area of land mostly separate by a water body. There are seven known
continents on the earth today. They are: Africa, Antarctica, Asia, Australia, Europe, North
America, and South America. A brief description of the continents is presented as follows:
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Africa
Africa is the second largest continent in the world next to Asia. The equator divides Africa
into two parts. But the largest part of the continent is found north of the equator. Africa is the
only continent in the world crossed by the equator, Tropic of Cancer, and Tropic of Capricorn.
The world’s largest hot desert (Sahara), and the world’s longest river (River Nile),are found in
Africa. Africa has 54 countries.

Antarctica
Antarctica is a permanently ice covered continent located around the South-Pole. The climate
is very cold and there are no permanent human settlements in Antarctica. But, many countries
have research stations in Antarctica. It is the third smallest continent on the earth.

Asia
Asia is the largest continent in the world. It lies in the eastern hemisphere covering one-third
of the total land area of the earth. It is crossed by the Tropic of Cancer and separated by the
Ural Mountains from Europe. It is part of the Eurasia and crossed by the Arctic Circle at its
northern margin. It is bounded by water bodies on three sides and by the Pacific Ocean in
the east and southern part. Asia has 48 countries and accommodates two-third of the world
population. It has the highest mountains (Himalayas), the deepest depressions (Dead Sea),
the driest desert (Lut desert), highest precipitation (Assam) and long tradition of civilization
(Mesopotamia).

Australia
Australia is the smallest continent in the world. It is surrounded by water in all of its sides and
often called an Island continent or Oceania; and has the largest area of ocean jurisdiction of
any country on Earth. It is the driest inhabited continent in the world with 70 percent of it
either arid or semi-arid. The vast majority of its population is concentrated along the eastern
and south-eastern coasts. Australia entirely lies in the southern hemisphere.

Europe
Europe is the second smallest continent in the world, and home of the industrial revolution.
It has 44 countries. It lies to the west of Asia and north of Africa. Europe is crossed by the
Arctic Circle. It is bounded by the Atlantic and Arctic oceans and by the Mediterranean Sea
in the south.
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North America
North America is located to the west of the Atlantic Ocean and linked to South America by
the narrow strip of land called the Isthmus of Panama. It is the third largest continent of the
earth. It lies north of the equator in the western hemisphere and surrounded by the Atlantic,
Pacific and Arctic Oceans. The main countries are three (USA, Canada & Mexico).

South America
South America is also located in the western hemisphere, but most of its area lies south of
the equator. It is bounded in the east by the Atlantic Ocean and in the west by the Pacific
Ocean. The world’s largest River (Amazon River), largest and most bio-diverse rainforest, tallest
uninterrupted waterfall (Angel Falls) and the north-south extending longest mountain (Andes
Mt.) are found in South America. South America has 12 countries.

The Arctic Ocean is the world’s smallest Ocean with an area of 14,056,000 km2. It lies in
the area between Europe, Asia, and North America. Most of its waters are north of the Arctic
Circle. Its average depth is 1,205 m. The deepest point lies at the Nansen Basin or Central
Basin and it is –4,665 m deep. Throughout most of the year, much of the Arctic Ocean is
covered by a drifting polar icepack that is an average of 3 m thick. However, as the Earth’s
climate changes, the Polar Regions are warming and much of the icepack melts during the
summer months. The Northwest Passage and the Northern Sea route have historically been
important areas of trade and exploration.

The Atlantic Ocean is the world’s second-largest Ocean with an area of 76,762,000 km2.
It is located between Africa, Europe, and the Southern Ocean in the Western Hemisphere. It
contains the majority of the Earth’s shallow Seas, but relatively few islands.
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The shallow Seas found in the Atlantic Ocean basin are the: Baltic Sea, Black Sea, Caribbean
Sea, Gulf of Mexico, North Sea, and the Mediterranean Sea. The average depth of the Atlantic
Ocean is 3,926 m. Its deepest point is the Puerto Rico Trench which is some 8,605 m
deep (Figure 1.11).
Many streams and rivers discharge their water into the Atlantic Ocean. This basin also drains
some of the world’s largest rivers including the Amazon, Mississippi, St. Lawrence, and Congo.
It receives more freshwater from continental runoff than any other Ocean basin. The Atlantic
Ocean is important to the world’s weather (as are all oceans) because strong Atlantic hurricanes
often develop off the coast of Cape Verde, Africa, and move toward the Caribbean Sea from
August to November.

Figure 1.10 Continents and Oceans of the World

The Indian Ocean is the world’s third-largest ocean and it has an area of 68,566,000 Km2.
It is located in the area between Africa, the Southern Ocean, Asia, and Australia. The Indian
Ocean has an average depth of 3,963 m. Its deepest point is at the Java Trench or Sunda
Double Trench (Figure 1.11). The maximum depth reaches some 7,258 m. The waters of the
Indian Ocean also include parts of the adjacent water bodies such as the Andaman, Arabian,
Flores, Java, and the Red Sea as well as the Bay of Bengal, Great Australian Bight, Gulf of Aden,
Gulf of Oman, Mozambique Channel and the Persian Gulf.

The Indian Ocean is known for causing the monsoon weather patterns that dominate much
of Southeast Asia and for having waters that have been historical checkpoints (narrow
international waterways). Because of its proximity to the equator, this basin has the warmest
surface Ocean temperatures.
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Figure 1.11: Trenches (deepest parts of the Oceans)
Source: www.trenchesandtrenches.weebly.com

The Pacific Ocean is by far the world’s largest ocean basin with about 155,557,000 km2.
It covers 28% of the Earth and is equal in size to nearly all of the land area on the Earth
combined. It is located between the Southern Ocean, Asia, and Australia in the Western
Hemisphere. It has an average depth of 4,028 meters, but its deepest point is the Challenger
Deep within the Mariana Trench (Figure 1.11), about 10,924 m deep. This area is also the
deepest point in the world. The Pacific Ocean has few marginal Seas but many islands. It is an
important Ocean basin from the geographers’ perspective not only because of its size but also
because it has been a major historical route of exploration and migration.

The Southern Ocean is the world’s newest and fourth-largest Ocean. In the spring of 2000,
the International Hydrographic Organization decided to delimit it as the fifth Ocean.

In doing so, boundaries were taken from the Pacific, Atlantic, and Indian Oceans. The Southern
Ocean extends from the coast of Antarctica to 60 degrees south latitude. It has a total area
of 20,327,000 km2 and an average depth ranging from 4,000 to 5,000 m. The deepest point
in the Southern Ocean is unnamed, but it is in the south end of the South Sandwich Trench
(Figure 1.11) and has a depth of 7,235m.
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Please answer the following question:

1. Locate the present-day Oceans and
Continents on a sketch map and
then show it to your teacher?

1.4. CHANGING POSITION OF CONTINENTS AND
OCEANS OVER GEOLOGICAL TIMES
This specific section acquaints you with the changing positions of Continents and the Ocean
basins over the geologic times.
At the end of this section, you will be able to:

appreciate the changing positions of the Continents and Oceanic basins over the
geologic time; and
produce sketch maps showing the changing location of the Oceans and Conti-
nents

Keywords
Continental drift
Continents
Oceans
Plate tectonics
Rodinia

Brainstorming Activity 1.5

What do you know about the changing positions of
Continents and Ocean basins? Please think individu-
ally and then discuss with your classmates.
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As can be observed from Figure 1.3 (on page 5), the location of the continents and oceans
was not fixed. Due to plate movement (tectonics) the position of continents and oceans has
been changing several times. For instance, during the Triassic period of the Mesozoic era ( 210
Ma), the earth’s continents were joined together forming one big continent called Pangaea
(meaning the whole of the earth). Pangaea during this time was surrounded by on big water
body named Panthalasu. During this time, Laurasia was located around the equator whereas
Gondawana was located around the South-Pole.

During the second stage, in the late Triassic period ( 180Ma), Pangaea started cracking because
of continental drift. Following the rifting of Pangaea, Laurasia moved to the north. Africa,
South America, India and Arabia started moving to the north too. Antarctica and Australia
positioned around the South-Pole. Following the cracking of Pangaea, the oceans flooded the
rifted area between the continents (see Figure 1.3).

During the late cretaceous (65 Ma), the separation between Eurasia and North America
increased. These two big continents positioned almost north of the tropic of cancer. Africa,
South America, Arabia and India separated and positioned around the equator. Antarctica still
placed at the South-Pole. Since the cracks between the separating continents widened, all the
free areas were occupied by the Pacific, Atlantic, Arctic and southern oceans.

After the separation of the Pangaea (see Figures 1.9 &1.12), North America and Eurasia are
positioned in the northern hemisphere while India and Arabia joined Eurasia. Africa, South-
America, and Australia are positioned around the equator; but Antarctica is still placed at
the South-Pole. The Atlantic Ocean covered the area between Africa, Eurasia and the two
America’s. The Pacific Ocean occupied the area between the America’s, Eurasia and Australia.
The Arctic Ocean covers areas north of the Arctic Circle and areas between North America,
Europe and Asia.

The Indian Ocean covers the area between Africa, the Southern Ocean, Asia, and Australia.
The Southern Ocean covered areas south of the Pacific, Atlantic and Indian Oceans and the
coastal lands of Antarctica (see Figure 1.10).
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Figure 1.12: Location of continents and Oceans during the late Cretaceous

Today, seven continents and five Oceans makes-up the Earth. Most Continents occupy areas
north of the equator while oceans dominate the southern hemisphere. The Pacific Ocean is
located between Eurasia and the Americas while the Atlantic divides Africa and Eurasia from
the Americas. The Indian Ocean also covered the area between Africa, Asia and Australia. The
Arctic and Southern Oceans are centered at the North and South-Poles, respectively.

Please answer the following question:

1. Describe how Continents and Oce-
anic basins had been changing their
positions over the geological times?
2. Please support your descriptions
with sketch maps?
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UNIT SUMMARY
The geological timescale is the timeframe showing the estimated age of the Earth and its
associated life-forms. It is established by Earth scientists through observation and analysis of
rock layers. Two types of rock dating methods (Relative and Absolute dating) are used during
rock dating activities. In relative dating, three principles (Original horizontality, Superposition,
and Cross-cutting relationships) are in use. Radiometric isotopic dating methods are used for
determining the absolute ages of rocks.

The Earth is estimated to be 4.5 billion years old. The earliest life-forms assessed from fossilized
bacteria are detected to be only about 3.5 billion years old. Scientists guess that early Earth
was very hot and hostile to life. Its history is classified into Eons, Eras, Periods, and Epochs.
Eons cover longer time units (billions of years) in the geological timescale. They are the
Hadean, Archean, Proterozoic and Phanerozoic. The Phanerozoic Eon is the latest and divided
into four Eras. Eras cover larger time units (hundreds of Ma). They include the Precambrian,
Paleozoic, Mesozoic, and Cenozoic eras. The eras are further classified into periods that cover
millions of years. They are 13 in number and each divided into relatively shorter periods
named epochs. Of the eras, the longest and oldest is the Precambrian. It is the time when the
earliest rocks solidified and were created. The Paleozoic is known to be the age of ancient life.
The Mesozoic marks the age of middle life in the geological history of the Earth. The Cenozoic
is the latest and is an era of developed mammals, birds, and modern humans.

The formation of the Earth is attributed similar to the creation of other companion planets
and the entire Solar System. The present-day continents are assumed to be developed by
continental drift. At the beginning (during the Paleozoic and Mesozoic eras) all current
continents were joined together forming a big landmass (Pangaea) embraced by a big water
body named Panthalasu. In the mid of the Mesozoic, Pangaea started to break apart to form
two major continents named Gondwanaland and Laurasia. These two supercontinents later
split into several smaller landmasses.

Due to continental drift, the Earth and its continents as well as the ocean basins have been
continuously changing their shape, size, and position since the time of their creation. Their
distribution has also been changing since time immemorial. For instance, the Supercontinent
Pangaea was situated around the South Pole during the late Permian. Eurasia was also centered
around the equator during that time. The present-day Oceans were not known by then. Today
a large part of the continental landmass is located north of the equator. On the other hand,
Oceanic environments are much more in the southern hemisphere. The proportion of land
and water is not also equal over the planet Earth. Large areas (>71% of the Earth) are covered by
water. Generally, the Earth’s continents and Oceans are not permanent and static. Their shapes,
sizes, and locations are continuously changing with changes in time and earth processes.
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REVIEW EXERCISES

Instruction: Attempt the following questions accordingly.
I) True/False: For questions 1-5, write ‘True’ if the statement is correct and ‘False’ if wrong.
1. Radioactive dating methods are applied to place rock layers in their relative ages.
2. The Cenozoic era is well known and divided into a number of periods and epochs.
3. The initial creation of the Earth is inseparable from the creation of the entire Solar System.
4. The Earth’s continents are immovable and static.
5. In continental formation, Pangaea evolved ahead of Rodinia.

II) Matching: Match items listed in Column ‘A’ with the geological eras under Column ‘B’

Column ‘A’ Column ‘B’
1. Modern humans A) Precambrian era
2. Not accurately known B) Paleozoic era
3. Formation of continental shields C) Mesozoic era
4. Rifting of Pangaea D) Cenozoic era
5. Trilobites
6. Ice age
7. Formation of Pangaea
8. Age of Dinosaurs

III) Multiple choice: For questions, 1-5 choose the best answer from the given alternatives.
1. Which relative dating principle applies for conditions where younger rocks cut across older
rocks?
A) Original horizontality C) Radioactive decay
B) Cross-cutting relationship D) Superposition
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2. How were the present-day Continents and Oceans created?
A) By the will of God C) By the art of cartographers
B) Through space explosion D) Through continental drift
3. One of the following is correct about the formation of the Earth’s continents
A. The current continents and oceans have been shaped by the process of plate
tectonics
B. The present-day continents evolved 4.6 billion years ago
C. Earth’s continents were formed by rapid chemical precipitation from the world’s
oceans
D. All of the Earth’s surface features had evolved in less than 6,000 years

4. Mariana trench (challenger deep) forms the lowest part of the Earth in the:
A) Atlantic Ocean B) Arctic Ocean C) Pacific Ocean D) the Indian Ocean
5. Which is correct about the distribution of Continents and Ocean basins?
A) Continents and Oceans account for equal size on Earth
B) Continents occupy more area in the southern hemisphere
C) There is wider Ocean coverage in the northern hemisphere
D) More continental coverage north of the equator compared to the south

IV) Short answer writing:
Give short answers to questions provided below.
1. How do scientists assign absolute ages to Earth’s rocks and ancient fossils?
2. What is the difference between relative and absolute ages of geological events?
3. Study the sketch (figure 1.13) below and then determine the age estimates (in Ma) for the
sedimentary beds 1-5; 9 and 10?
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UNIT TWO
Learning Outcomes:

At the end of this unit, you will be able to:
list the criteria commonly used to classify climates of an area;
classify climates of an area based on Köppen’s classification
methods;
identify the factors influencing world climatic regions;
describe climate zones in Ethiopia;
compare and contrast the local and Köppen’s methods of
climate classification; and
locate world climatic regions on a map.

MAIN CONTENTS
2.1. Criteria for climate classification
2.2. Köppen’s climate classification
2.3. World climatic regions
2.4. Factors influencing the world climatic regions
2.5. Local/Indigenous climate classification of Ethiopia
Unit Summary
Review Exercise

INTRODUCTION

This section will guide you about the climatic classification methods and global climatic
areas. The unit also includes approaches, climatic region classification criteria, and elements
that influence global climatic regions. As a result, you should make an effort to understand
the offered contents both independently and jointly. Climate is a multifaceted and abstract
notion that contains data on all aspects of the global environment. The climate in two or more
locations on our planet may not be the same. Climates vary within a narrow range throughout
a limited area of the planet, yet there is some uniformity in the patterns of climatic elements
within the climatic zone. Understanding Earth’s climates require climate classification to
recognize, clarify, and simplify climatic similarities and variations between geographic regions.
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Climate classification is useful for determining expected weather patterns for a certain region,
comparing exceptional and regular daily meteorological variables, and indicating climate vari-
ability and change through time. Different environmental elements and criteria are used in the
classification schemes. Many climate factors have only been collected for brief periods and are
not available for significant portions of the globe. Data on soil, vegetation, temperature, and
precipitation is widely available and has been collected over long periods. Most classification
schemes (such as Köppen’s and Trewartha’s) are intended for global or continental scale use
and identify climatic zones based on the criteria.

At the end of this section, you will be able to:
identify the criteria used to classify the climates in different classification schemes;
differentiate between the criteria used to classify climates in different classification
schemes

Keywords
Climate classification
Criteria

Brainstorming Activity 2.1

Note the following questions and try to think independently and
share them with your classmate in a group of 5.
1. How do you understand climate from your courses in
grades 9 and 10?
2. What exactly do you mean when you say “climate classifi-
cation criteria”?
3. How did the ancient Greeks categorize the world’s cli-
mates?
4. How do you distinguish between genetic and empirical
classification methods?

There are criteria used for different types of climate classification, including ancient Greeks,
genetic, and empirical (including Köppen’s and Trewartha’s). The ancient Greeks divided the
earth into latitudinal zones based on their perceptions of habitability in particular zones, such
as the Frigid Zone, Temperate Zone, and Torrid Zone. They did so by considering temperature
and the distribution of sunlight around the earth. The planet’s Polar Regions, including the
Arctic and Antarctic circles, are represented by the Frigid Zone, which has extremely frigid
temperatures. The Temperate Zone, which lies between the Torrid and Frigid Zones, is thought
to offer the best climate and habitat.
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The tropics, or warmer areas south of the Mediterranean Sea, are represented by the Torrid Zone.
The Earth-Sun relationship served as the foundation for ancient Greek climate classification.
According to the data utilized for classification, climate classification methods can be divided
into two types: genetic and empiric. Climates are classified using a genetic classification method
based only on the major forcing processes that shape climate. Climate is classified using the
genetic method based on the activity and features of air masses, circulation systems, fronts,
jet streams, solar radiation, topographic effects, and other factors that contribute to the spatial
and temporal patterns of climatic data. Genetic systems, while more scientifically desirable,
are more complex to implement and less successful overall since they do not rely on simple
observation. The most widely utilized genetic systems are air mass ideas.

The empirical classification system is a classification system that uses data input to calculate
the climatic type based on specified class boundaries. Köppen and Trewartha’s systems,
for example, have the advantage of being simple to deploy in regions with high-quality
and abundant climatic data. They also make certain that two places with similar climatic
characteristics for the variables in question are grouped.

The classical period of climatic analysis began in 1970 with the mathematics and distribution
of natural vegetation based on the botanist Vladimir Köppen’s climatic classification system.
For world climate classification, the Köppen method typically includes yearly and monthly
temperature and precipitation, as well as the seasonality of those variables. Winds, temperature
extremes, precipitation intensity, sunshine quantity, cloud cover, and net radiation are not
considered in Köppen’s climatic classification system.

Trewartha’s classification incorporates the fundamentals of both empirical and genetic
classification schemes. The classification structure is based on the most important and basic
weather parameters, such as temperature and precipitation. The impacts of water surfaces on
a region’s climate are also taken into account.

Please answer the following question:

1. Compare and contrast the Köppen and Tre-
wartha’s climatic classification systems’ cri-
teria.
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2.2. KÖPPEN’S CLIMATE CLASSIFICATION

At the end of this section, students will be able to:

Keywords:
Climate classification
Modified Köppen
Simplified Köppen

Brainstorming Activity 2.2

1. Why Köppen climatic classification method is commonly
used?
2. Using Figure 2.1, identify the climate types of Ethiopia using
the simplified Köppen’s climate classification?
3. Which climate types are determined by temperature, and
which are determined by precipitation? In a group of 3-5
people, discuss and share your thoughts on these topics.

Because of its simplicity and strong alignment with climatic areas, natural vegetation, and soil
types, the Köppen climate classification system is commonly used for classifying world climate.
The Köppen method recognizes that most vegetation types respond immediately to climate in-
puts, particularly temperature and moisture fluctuations, and is based on dominant vegetation
types. Köppen observed and mapped the ecotone (the zone where two biomes meet), then
utilized temperature and precipitation data to construct equations that defined the climatic
boundary between the two biomes. Köppen published his initial climate classification scheme
in 1900 and revised it in 1940.

Based on the aforementioned criteria, the Köppen system distinguishes between five major
terrestrial climatic types:
1. Tropical climate (A): All months have an average temperature above 18o C (64oF). There
is no real winter season because every month of the year remains warm.
2. Dry Climate (B): It has deficient precipitation most of the year.

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3. Meso-thermal or Mid-latitude Mild (C): Average temperature of the coldest month is
below 180C (640 F) and above -30C (270F).
4. Micro-thermal or Mid-latitude Cold (D): The average temperature of the warmest month
exceeds 100C (500F), and the coldest monthly average drops below -30C (270F).
5. Polar Climate (E): It has extremely cold winters and summers. The average temperature
of the warmest month is below 100 C (500F). Given that all months are cold, there is no real
summer season.

Copyright 2019 Cengage Learning.
Figure 2.1:A simplified overview of the major climate types, according to Köppen
The climates A, C, and D stimulate tree growth, whereas the climates B and E are too dry and
too cold, respectively, generally do not. The four primary climatic kinds, A, C, D, and E, are
characterized by temperature, although type “B” denotes a climate in which dryness, rather
than coldness, is the governing element of vegetation. A new group, highlands (H), was later
created to account for the significant climate changes in mountainous areas over short dis-
tances.

Brainstorming Activity 2.3

1. How can you tell the difference between a basic Köp-
pen system and one that has been modified?
2. Which climate types are found in Ethiopia, according
to modified Köppen’s climatic classification schemes?
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Figure-2.2. Improved Köppen-Geiger classifications of our world:
Part (a) shows the present-day map (1980–2016) and (b) the future map (2071–2100).
Source - Present and future Köppen-Geiger climate classification maps at 1-km resolution
@www.gloh20rg/ Köppen

Using air temperature (0C) and precipitation (mm y-1) criteria from high-resolution climatic
datasets, the present Köppen-Geiger map (Figure 2.2a) was developed. The current Köp-
pen-Geiger classification didn’t consider the rising levels of greenhouse gases in the at-
mosphere, which may alter how vegetation relates to various climate classes. Consider the
future Köppen-Geiger classification (Figure 2.2b) as providing information on possible spatial
changes in regional climatic zones under climate change, which caused by the rising levels of
greenhouse gases in the atmosphere.
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Source: Beck et al.: Present and future Köppen-Geiger
climate classification maps (2018)

"Figure 2.3. Köppen-Geiger climate classification map for Ethiopia (1980-2016)"
Rudolf Geiger, a climatologist, altered the Köppen classification system in 1961 to improve
the alignment of climate zones and biomes. By merging appropriate first, second, and third-or-
der subdivisions, modified Köppen–Geiger climatic types are produced. To classify regional
climates more precisely, those primary (first) climatic types were subsequently classified into
second and third-order subdivisions.

The average monthly and total annual precipitation for A, C, and D climates is denoted by the
second-order subdivision (with “f” denoting a climate that is wet all year, “m” denoting tropical
monsoon conditions, “s” denoting dry summer climates, “w” denoting dry winter climates and
“m” representing tropical monsoon conditions).
The second-order subdivision in the case of B climate is “W” if the dry climate is a true desert,
and “S” if the dry climate is only semi-arid. Second-order subdivisions for “E” climate include
“T” for Tundra climate, a milder arctic sub-type, and “F” (frozen) for Ice Cap climate.

The third order subdivisions in the Mesothermal and Microthermal climates specify the
features of summer temperatures, with “a” indicating hot summers, “b” indicating warm sum-
mers, “c” indicating mild summers, and the rare “d” indicating cool summers. The third-order
subdivision of arid climates is “h” for hot and “k” for cold.

From the equator to 15o to 25o north and south latitudes, the tropical wet climate (A) exists.
The average temperature in all monthly records exceeds 18o C (64.4oF). More than 60 inches
(>1500mm)of rain falls each year.
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The climate in this category is divided into three minor Köppen climatic types, each of which
is named after the seasonal distribution of rainfall.

1.Tropical wet or equatorial rainforest climate (Af):
Af refers to a tropical environment with year-round precipitation. In this environment, monthly
temperature differences are fewer than 3oC. Cumulus and cumulonimbus clouds occur prac-
tically every day early in the afternoon due to severe surface heating and high humidity. The
average daily high temperature is 32oC, while the average nighttime temperature is 22oC. This
climate is found in areas such as Amazon rain forest and Congo basin.

2.Tropical monsoon climate (Am)
Am denotes a climate with yearly rainfall similar to or greater than Af, but with the majority
of precipitation falling during the 7 to 9 hottest months to support the rainforest. There is
extremely little rain throughout the dry season. This type of climate found in regions such as
parts of India and South east Asia.

3.Tropical wet and dry or savanna (Aw)
The third group, tropical wet and dry or savanna (Aw), is characterized by a prolonged dry
season in the winter. During the rainy or summer season, precipitation is frequently less than
40 inches. examples inculed the african savanna and the tropical regions of south america.The
difference between Aw and Am climates is determined by annual precipitation and the driest
month’s precipitation, using the formula below:

a=3.94-r/25 , where a= precipitation of driest month, and r = annual precipitation. If the
precipitation of the driest month of a place is less than the value of “a”, it will be Aw climate,
whereas if it is more than the value of “a”, it will be Am climate.

If the average annual precipitation of a place is 80 inches, then Am/
Aw boundary would be = 3.94-80/25=3.94-3.2=0.74 inches. If
the precipitation of the driest month of that place is 2 inches, the
climate type would be Am. On the contrary, it would be considered
Aw climate if the area’s driest month had precipitation of less than
0.74 inches.

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Dry climate (B)
Dry climates are generated by their location:
In trade wind belts,
On the leeward side of high mountains, and
In the interior of continents along cool ocean currents.
During most months, mean evapotranspiration tends to exceed mean precipitation in a dry
environment. Type B climates are characterized by a lack of precipitation for the majority of the
year, which limits vegetation growth and spread. Aridity is defined by the interaction between
precipitation input to the soil where plants grow and evaporative losses. Aridity is defined
by Köppen in terms of the temperature-precipitation index, with evaporation thought to be
controlled by temperature. The horn of the Africa is an exception to the rule that aridity is
typically linked to subsidence. For instance, Somali’s extreme driness can be attributed to the
contininet of Africa’s orientation concerning atmospheric circulation. Based on yearly tem-
perature and the wettest month of the year, the dry climate is classified into two minor classes.

NOTE:

Evapotranspiration is the term for the combination of two
distinict processes of water loss, one by evaporation from
the soil surface and onother by transpiration form a plant.

Desert (BW): A true arid climate dominated by xerophytes vegetation that covers 12% of the
earth’s land surface. It is found between 15 and 300 North and South, where warm, dry air
sinks because of subtropical highzones. Vast deserts such as the Sahara or Gobi are included.

Dry Semiarid or Steppe (BS): A grassland climate that encompasses 14% of the planet’s land
area. The climate gets more precipitation than the BW from the inter-tropical convergence zone
or mid-latitude cyclones. The boundary between BW and BS is established using the formula:
r=0.44t-8.5/2, where r represents annual precipitation (inches) and t represents temperature
(00 F). If the annual precipitation of a certain location exceeds the value of “r,” the climate is
BS, but if it is less than “r,” the climate is BW. In the United States, the great plains, portions of
the Southern California cost and the great basin are semi-arid deserts.

If the temperature of a place is 90oF, the annual value of
precipitation for dividing boundary between BS and BW
climates will be: r=0.44x90-8.5/2=15.5 inches
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Dry (B) climates are further classified based on annual temperature. The climate is represent-
ed by the letter “h” when the mean annual temperature is greater than 180C (64.40F) and by
the letter “k when the mean annual temperature is less than 180C (64.40F). Desert climates
are further divided into hot/tropical/desert (BWh) climates, which have an average annual
temperature greater than 180C (64.40F), and middle latitude cold desert climates (BWk), which
have an average annual temperature less than 180C. Hot dry semiarid or tropical steppe (BSh)
climate, with a mean annual temperature above 180C, and cold dry semiarid or middle-lati-
tude latitude cold steppe climate (BSk), with mean annual temperature below 180C, are two
third-order divisions of steppe climates. The BWh climate is found in areas such as the sahara
desert while BWk climate is found in colder desert regions, such as the Gobi desert.

Cloud cover is unusual in most low-latitude deserts (fewer than 30 days per year have clouds
in some areas). Although the unreliability of precipitation is more relevant than the modest
totals, precipitation quantities are generally in the range of 0–10 inches. These places, on the
other hand, have high temperatures, with monthly averages in the range of 21–320C (70–90
0
F). Furthermore, daily temperature swings are considerable.

Mid-latitude Mild or Mesothermal (C)
Warm and humid summers alternate with mild winters in this region, which is located between
25 and 400 latitudes, primarily on the eastern and western borders of most continents. It is
frequently dominated by convective thunderstorms during the summer months. During the
winter season, the dominant meteorological feature is the mid-latitude cyclone. The seasonal
distribution of precipitation further divides mid-latitude climate into four distinct climatic
subgroups.
(I) Cf climate: This climate is characterized by precipitation throughout the year, with more
than 1.2 inches of precipitation in the driest month of the summer season. This is the most
common climate in Western Europe. There are two third-order sub-divisions within this cli-
matic type:
A. Humid subtropical (Cfa), Is found along east costs of continents are charac-
terized by warm humid summers with frequent thunderstorms; and precipitation
coming from mid-latitude cyclones during the mild winter season); and
B. Marine west coast (Cfb), is found in the western sides of continents are char-
acterized by humidity, short dry summer, and persistent mid-latitude cyclones
(causing heavy precipitation during mild winters).
(II) Cw Climate: Characterized by dry winters, and has 10 times more prcipitation in the
wettest month of summer season than the driest month of winter season. It is the dominant
climatic type in China.

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Classification and Regions of the World

(III) Cs (Mediterranean): The primary rainfalls from mid-latitude cyclones during the winter
season. Extreme summer aridity is caused by the sinking airs of the subtropical highs. The wet-
test winter month receives at least three times the amount of rain as the driest summer month.

Mid-latitude Cold or Microthermal (D) Climate
This climate type also called continental climate is found on the poleward side of the moder-
ate (C) mid-latitude climate. Warm to cool summers and cold winters are the most prominent
features. Snowstorms, high winds, and brutal cold from polar or arctic air masses characterize
the harsh winters. Df climate (humid cold climate with no dry season), Dw climate (humid cold
climate with dry winters), and DS climate (humid cold climate with wet winters) are the three
sub-classes of this climate type (dry winters and dry summers).

Polar Climate (E)
This climate is characterized by cold temperatures year-round, with the warmest month having
a temperature of about than 100C. Geographically, it is found on the landmasses of Green-
land and Antarctica, as well as the northern coastal portions of North America, Europe, and
Asia. The two minor types of polar climate are polar tundra (ET) and polar ice caps (EF). Polar
tundra (ET) is defined by permafrost, which is soil that is permanently frozen to depths of
hundreds of meters. The warmest month’s average temperature is greater than 00C (320F) but
less than 100C. (500F). Mosses, lichens, dwarf trees, and scattered woody shrubs can be found
scattered throughout the polar tundra. A polar ice cap (EF) is characterized by a land surface
permanently covered with snow and ice. The average temperature of the warmest month is 00
C (320F) or below.

Highland Climate

Due to the effects of height, tundra and polar conditions could be seen in low latitude places.
In high latitudes, climate change experienced while climbing 300 meters (1000 feet) in el-
evation is equivalent to horizontal changes encountered while moving 300 kilometers (186
miles) northward (this distance is equal to about 30 latitude). Over a relatively little vertical
shift in elevation, highland climates often show a tremendous lot of diversity in temperature,
precipitation, and flora. The presence of glaciers in tropical mountains demonstrates that alti-
tude has a cooling impact.
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Figure 2.4: Altitudinal zone of highland climate
The afro-alpine zones on the highest parts of the Ethiopian plateaus, for example, have a
highland climate. The Senate Plateau (Bale Zone), Simien Mountains (north Gonder), Mount
Guna (south Gonder), Amara Saint (South Wollo), and the Choke Mountains (Gojam) are
examples of small isolated high places where it can be found (Figure 2.4).

The Merits and Demerits of Köppen’s System
Despite many critics, the Köppen system is still the most widely used climatic classification
system today. The Köppen system has been criticized by several people, including for reasons.
Extreme events, such as a periodic drought o