Notes on living with tectonic hazards 0 levels

1. NOTES ON LIVING WITH TECTONICHAZARDS (O levels)
1. What are tectonic hazards?
Tectonic hazards are caused by movements in the Earth’s crust e.g. Earthquakes, Volcanic
eruptions, Tsunamis.
2. What is the internal structure of the Earth?
The crust is the outer layer of the earth and it varies in thickness from 5 to 70 km.
Mantle is the second layer of the earth's structure which is 2900 km thick. It is divided into
upper mantle and lower mantle. The upper mantle is a layer of solid rock and asthenosphere.
Below the uppermost mantle, rocks are close to melting point and easily deformed as the
temperature is between 800⁰C and 3,000⁰C.Convection currents carry heat from the hot
inner mantle to the cooler outer mantle.
The outer core is about 2100 km made up of molten iron-nickel (liquid) and the inner
core is about 1200km consists of solid iron nickel and is very hot and under great pressure.
3. What is the difference between the tectonic plates?
The crust is cracked into pieces called tectonic plates which float on the mantle. The tectonic
plates are part of the lithosphere, which includes the crust and the uppermost mantle. There
are two types tectonic plates:
Continental crust – found beneath the earth’s continental land masses and under shallow
seas close to continents, it is thicker between 30 and 60km but is made of lighter rocks
including granite.
Oceanic crust – found beneath deep oceans, it is thinner between 5 and 8km but it is
heavier and denser as it consist mainly of basalt
4. How do the tectonic plates move?
Movement of crustal plates is driven by convection currents and slab-pull force.
Convection currents occur when materials in the mantle is heated by the core, causing the
mantle material to expand, rise and spread out beneath the plates. This causes plates to be
dragged along and to move away from each other. Then the hot mantle material cools and
sinks, pulling the plates along. The sinking mantle materials heats up again as it nears the
core and the whole process repeats.
Slab-pull force occurs when the denser oceanic plate is force beneath the less dense
continental plate resulting in subuction. As the plate subducts, it pulls the rest of the plates
along. The subducting plate drives the downward moving portion of convection currents. The
mantle material, which is found away from where the plate subduct, drives the rising portion
of convection currents.

2. 5. What are the types of plate boundaries?
Types of plate boundaries and examples:
· Divergent: where plates move away from each other - oceanic-oceanic e.g. Mid-
Atlantic Ridge, continental-continental e.g. Great Rift Valley of East Africa
· Convergent:where plates move towards each other - oceanic-oceanic e.g. Mariana
Trench, continental-continental e.g. Himalayas, oceanic-continental e.g. Andes
· Transform: where plates move past each other e.g. San Andreas Faultbetween the
Pacific plate and the North American Plate.
6. Describe the characteristics of landforms associated with plate movements.
Oceanic-oceanic plate divergence: Mid-oceanic ridge and Volcanic islands
E.g. The Mid-Atlantic Ridge
Eg: The Azores (Chain of volcanic islands)
 As the plates move apart due to convection currents inside the Earth. magma rises
from the mantle to fill the gap between the plates as they diverge.
 New sea floor is formed when the magma cools and solidifies. This process is called
sea-floor spreading.
 Magma rises at the zone of divergence/spreading zone to form a ridge of new ocean
floor called mid-oceanic ridge.
 The newly formed (youngest) rocks are closest to the middle of the ridge/plate
boundaries.
 At various points along the ridge, magma builds up above the ocean to form volcanic
islands.
Continental–continental plate divergence:Rift valleys and block mountains
E.g. East African Rift Valley
 When two continental plates diverge, they are stretched, causing fractures to form at
the plate boundary.

3.  The land in between the two continental plates sink, forming a linear depression
known as a rift valley.
 A number of active volcanoes and earthquake fractures can also be found along the
East African Rift Valley.
Oceanic–oceanic plate convergence:Trench and islands, volcanoes
E.g. Mariana Trench, Mariana Islands
 When two oceanic plates converge, one subducts under the other.
 A subduction zone forms, creating a deep oceanic trench.
 The subduction of the oceanic plate causes the solid mantle material to melt and
magma is formed.
 The magma rises through the mantle and ocean floor to emerge as volcanoes.
 Eventually a chain or arc of islands called island arc is formed.
 Earthquakes may also occur.
Continental-continental plate convergence: Fold mountains
E.g. Himalayas
 Plates made largely of continental crust may collide with other plates made largely of
continental crust.
 However, both plates have similar densities and hence, resist subduction.
 Instead, the plates break, slide along fractures in the crust and fold, forming fold
mountains.
Oceanic-continental plate convergence:Oceanic trench, Fold mountains and
Volcanoes
E.g. Sunda Trench, Barisan Mountains
 When an oceanic plate meets a continental plate, the denser oceanic plate subducts
under the less dense continental plate.
 A subduction zone forms, creating a deep oceanic trench along the plate boundary.
 The subduction of the continental plate causes the soild mantle material to melt and
magma is formed.
 The magma rises through the mantle and crust to emerge as volcanoes on land.
 The edge of thick continental plate buckles to form fold mountains.
 Earthquakes may also occur.
Transform plate boundaries
E.g. San Andreas Fault, United States of America - In 1906, an earthquake occurred in
San Francisco, southern California between the Pacific Plate and the North American
Plate. This caused several hundred km of North American Plate to move an average of
2.5 m, and at one point almost 7 m all in less than 1 minute
 Plates slide past each other.
 As they do so, tremendous stress builds up.
 This stress is eventually released, often as a violent earthquake.

4. 7. How is a fold mountain formed?
E.g. The Himalayas, the Rocky Mountains and the Andes
 Fold mountains are formed along convergent plate boundaries.
 The compressional force causes the layers of rocks to buckle and fold.
 This process is known as folding.
 When there is increasing compressional force on one limb of a fold, the rocks may
buckle until a fracture forms.
1. Describe the formation of Rift valleys and block mountains.
E.g. East African Rift Valley
 Rift valleys and block mountains are formed at divergent plate boundaries where
plates are pulled apart giving rise to faults.
 The tensional forces from these movements result in parts of the crust being
fractured.
 A block mountain is a block of land with steep sides. It is formed when sections of
the crust extend along fault lines and rock masses surrounding a central block sink
due to tensional forces.
 A rift valleyis a valley with steep sides formed along fault lines.
2. Describe the formation of volcano.
 A volcano is a landform formed by magma ejected from the mantle onto the earth’s
surface. Magma is molten rock found below the earth’s surface. Magma that is
ejected onto the surface is known as lava. The lava cools and solidifies in layers and
form a cone-shaped mountain called a volcano.

5. Volcanoes vary in shapes and sizes due to the characteristics of lava. Low silica lava has
low viscosity (stickiness) while high-silica has high viscosity.
3. Differentiate between the shield volcano and the stratovolcano.
 Shield volcano have gently sloping sides and a broad summit. It is made up of fluid
lava with low silica content. It is more mobile and spreads away from the vent before
it solidifies forming gentle concave slopes.
 E.g. Mauna Loa (Hawaii), Mount Washington, United States of America
 Stratovolcano is steeper at the top and gentler at the base. There are periodic
violent eruptions with alternate layers of lava and ash accumulated.
 E.g. Mt Fujiyama in Japan, Mt Pinatubo in Philippines, Mount Mayon, Philippines
4. Explain what is an active, dormant or extinct volcano?
Active volcanoes – volcanoes which are currently erupting or are expected to erupt in the
future
Dormant volcanoes – volcanoes which are currently inactive but may erupt in near future
Extinct volcanoes – volcanoes without current seismic activity with no geological evidence
of eruptions for the past thousands of years.
12. Describe the distribution of volcanoes.
 Mainly along the Pacific Ring of Fire which is the boundaries of several converging
plates – Pacific Plate, Nazca Plate, the Philippines Plate and the Eurasian Plate.
 Also found where plates are diverging e.g. Atlantic Ocean and East Africa
13. Explain the cause of earthquake.
Earthquakes occur when there is plate movement along plate boundaries. The plate
movements cause the slow build-up of stress on the rocks found on either side of the fault.
When the rocks can no longer withstand the increasing stress, they can suddenly slip many
metres, causing an earthquake.
The release of tension in the form of seismic waves made the ground vibrate. After an
earthquake, a series of smaller earthquakes called aftershocks occur along the fault line.
A seismograph is used for recording earthquake. The intensity of earthquake is measured
on the Richter scale graded from 1 to 9. The higher the number on the Richter scale the
greater the intensity of the earthquake.

6. 14. Explain why some earthquakes are more damaging than others.
Some earthquake causes more damage because the intensity of the earthquake differs.
Places located near to the epicentre will experience higher intensity of the earthquake and
thus suffer the greatest amount of damage.
The damage also depends on the depth of its origin – a deep-focus earthquake ( 70-
700km below earth surface) has a smaller impact on the land compared to a shallow-focus
earthquake (upper 70km of earth crust) as seismic waves take a longer time to reach the
surface and would have lost most of their energy by then,
The extent of damage also depends on the amount of development in the areas where
earthquake takes place. An earthquake which struck a desert is less damaging than in a city.
The foundations of the buildings and bridges are also important because if the
foundation is good, it will withstand the vibration. Developed areas suffer more damages as
water and gas pipes broke. Urban areas are heavily built up with dense population densities
and heavy traffic movements. As residents in big urban areas usually live in high rise
buildings because land is scarce in the cities, damage to properties and loss of lives can be
phenomenal as the high rise building collapse when earthquakes occur. As building collapse,
other related hazards usually occur such as fire from damaged power lines. Destruction to
highways, streets, flyover and bridges leads to widespread traffic congestion and commuters
may be killed and hurt. Telephone line and power supply will be disrupted, and this will affect
communication with outside world which in turn will hamper rescue work.
The strength of the earthquake also depends on the the geology of the epicentre.
e.g. Mexico, built on layers of mud and sand, vibrates like jelly in the 1985 earthquake which
killed 7000.
In Christchurch, many houses and buildings had to be abandoned because of liquefaction
where the ground becomes unstable and saturated soil flows like a liquid after the
earthquake in 2011.
The damage also depends on the level of preparedness and time of occurrence.
Preparations such as having evacuation plans, trained rescue workers and other action
plans can make the damage of an earthquake more manageable if the people are more
prepared. If the earthquake occurs when most people are sleeping, there is a higher chance
that more deaths will occur as they are trapped in their houses. E.g. more than 2400 people
died when an earthquake occurred after midnight in the Sun Moon Lake Region in Taiwan in
1999.
15. Explain the impacts and hazards associated with earthquakes.
 Disruption of services - An earthquake can disrupt services such as the supply of
electricity, gas and water. The earthquake in Kobe, Japan, in 1995 disrupted
electricity, gas and water supplies to about a million of Kobe city’s 1.4 million
residents.
 Fires are started due to rupture gas pipes which provide fuel to start fires as well as
exposing electrical cables which ignite flammable items. The earthquake
in Kobe, Japan in 1995 caused extensive fires that raged on an off for 2 days and it
spread quickly due to strong winds. The firemen were unable to control the fires as
there was no water supply due to ruptured water pipes.

7.  Landslides caused by earthquakes which weaken the slopes of hills and mountains
due to the shaking of the ground. In 1970, an earthquake off the coast
of Peru triggered a massive landslide on the slopes of Mount Huascaranand
destroyed the town of Ranrahirca killing 18000 people within seconds.
 Destruction of properties – the earthquake in Tohoku, Japan in 2011, caused a
tsunami which travelled up to 10km inland, causing extensive structural damage
resulting in hundreds of thousands of people forced from their homes. There was a
severe shortage of housing and long-term consequence on the health of people.
 Destruction of infrastructure –earthquakes cause cracks to form in infrastructure
such as roads and bridges. Transportation can be disrupted as it is unsafe to use the
damaged roads.
 Loss of lives and threat of tsunami
 Aftershocks -there could still be aftershocks of lower magnitudes as there are
adjustments to the repositioning of the fault. As many buildings are already
weakened by the main shock, the aftershocks will cause more collapse and there will
be more casualties. Dead animals and corpse will start to rot and if not disposed
quickly, there might be an outbreak of epidemic such as Malaria.
16. Explain the cause of tsunamis.
Tsunamis may be formed by:
 Movement of the sea floor during a large earthquake at the subduction zones
 An explosive underwater volcanic eruption
 An underwater landslide;
 A landslide triggered by earthquake or volcanic eruption which causes materials to
plunge into the water.
17. Describe the benefits and risks of living in volcanic areas.
Benefits of living in volcanic areas
 Volcanic regions are often rich in sulphur deposits which can be mined for industrial
use. E.g. In East Java, Indonesia, the sulphur collected is used to make matches and
fertilizers, and refine sugar.
 Basic lava often produces fertile soil after weathering which is suitable for cultivation.
e.g. fertile volcanic soils in Java and Deccan Plateau in India
 Geothermal power may be utilised for making steam to drive turbines and generate
electricity e.g. over 70% of homes in Iceland are heated by volcanic steam
 Volcanic areas offer spectacularly beautiful attractions for tourists. e.g Mt Fuji
inJapan. Volcanic areas can be rich in history e.g. ruins of Pompeii in Italy where Mt
Vesuvius erupted in 79 CE and buried the town. Every year, almost 3 million people
visit the unearthed archaeological site which revealed buildings, pottery and mosaics
left intact.
 Volcanic ash can be used to surface roads and manufacture bricks

8.  In some parts of the world, valuable materials such as gold, iron and diamonds have
been formed by volcanic activity, and large mining centres have developed. The old
volcanic rocks at Kimberly in South Africa are one of the world’s richest sources of
diamond.
Risks of living in volcanic areas
 Volcanic eruptions claim many lives and destroy buildings and property. The lava,
with high temperatures of between 500ºC and 1400 ºC burns the area it flows
through. Volcanic bombs of heated rocks destroy property around the volcano e.g.
eruption of Kilauea in Hawaii destroyed many homes and highway.
 Poisonous gases such as compounds of sulphur, carbon monoxide and carbon
dioxide are produced. Inhaling the hot ash and gases can result in serious injury or
death.
 Landslide can occur due to collapse of a volcanic cone. Landslides can obstruct the
flow of rivers causing floods, block roads, and bury villages and farmlands. The
eruption of Nevado del Ruiz in the Andes mountain of South America in 1985 caused
lahars which killed more than 20000 people in the town of Armero.
 Ash and volcanic dust ejected by volcanoes may be blown away to pollute the air and
disrupt human activities over a large area from the volcano. It can block sunlight,
suffocate crops and cause severe respiratory problems for people and animals. The
eruption of Eyjafjallajökull in Iceland in 2010 resulted in the closure of air space over
much of Europe as the volcanic particles pose a serious danger to aircraft engines
and structures. Connecting flights worldwide were cancelled and delays to 1.2 million
passengers daily cost the airline industry a total of US$1.8 billion.
 When snow-capped volcanoes erupt, a sudden flash flood will also result from the
melting of snow and ice. Mudflow may also be produced.
 Sulphur dioxide released from volcanic eruption may react with water vapour and
other chemicals in the atmosphere to form sulphur-based participles which can
reflect the sun’ energy back into the atmosphere and temporarily cool the earth. The
1815 eruption of Mount Tambora in Indonesia cause the global temperatures to drop
by as much as 1.7ºC.
18. Discuss the responses of people to earthquakes and tsunamis.
People may respond to natural hazards in several ways:
 Fatalistic approach – people who accept earthquakes as unavoidable events and
may resist evacuation in the face of the threat of an earthquake. Common for
communities in less developed countries with limited access to other places.
 Acceptance approach – people who accept the risk of living in earth-quake prone
areas because the benefits of living in those areas outweigh the costs of moving
away. Common in developed countries.
 Adaptation approach – people can successfully live in earthquake prone areas
when they are well prepared with measures such as earthquake monitoring devices,
risk assessments, planning structures and technology as well as support by well-
equipped rescue teams. Most effective approach to saving lives and property.

9. 19. Assess the effectiveness of strategies in mitigating the effects of earthquakes and
tsunamis.
Land use regulation
 Restrict developments in certain areas which are at risk of earthquake or liquefaction.
 Prohibit construction of new buildings on low-lying land vulnerable to tsunamis
Success:
 In California, USA, all new buildings are not built across fault lines or areas at risk of
liquefaction.
 Development on low lying areas prohibited except for areas with protective barriers
such as seawalls along the coasts of Japan and North America where the Pacific
Ring of Fire is located.
Limitations;
 Some areas may already be built-up or are privately owned. In some cases,
government authorities would buy land from private owners and compensate those
who have to move.
 These strategies are costly and some private owners may be reluctant to move as
they often believe that another hazard would not happen.
Effective Building design
 Steel and reinforced concrete
 Buildings constructed with wide and heavy bases
 Damping devices as shock absorbers and counter-weights which move in the
opposite direction to the earthquake.
 Base isolation bearings made of rubber or cushions placed between the ground and
buildings
Success:
 Reduce the collapse of buildings and minimize the damage caused by an
earthquake. e.g.Taipei 101 reinforced with heavy metal bars
 Damping devices prevent a building from swaying too much and collapsing.
 Base isolation bearings absorb the force of the earthquake and reduce the
movement of the building. e.g. lead rubber bearings used at
the Sabiha Gökcen Airport in Istanbul.
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Limitations
 Higher cost of construction and maintenance of buildings.
 Expensive to convert existing buildings to include earthquake resistance features.
 If conversion is too expensive, buildings have to be demolished and rebuilt e.g. A
policy adopted by the local government of Beijing,China in 2011.

10. Infrastructure development
 Roads, bridges and dams built to resist the shaking of the ground so that they do not
collapse or can be easily repaired if they collapse.
 Homes, office buildings and factories fitted with trip switches that ensure all electrical
points are switched off in the event of an earthquake.
 Large underground water tanks provide emergency reservoirs for possible fire fighting
after an earthquake.
 Adherence to strict building codes for minimum acceptable level of safety for
infrastructure such as houses.
Success:
 Although reinforced infra-structure remains untested until earthquake occurs, past
earthquakes in Chile, Japan and California showed benefits of reinforced infrastructure
such as fewer lives lost, faster rescue and evacuations, and less money spent on
recovery for the affected areas.
 In Japan, machines in many factories automatically shut down when they sense
earthquake vibrations which helps to prevent fire outbreaks.
 Underground water tanks are found in Tokyo, Kyoto and Kobe in Japan.
Limitation:
Developing infrastructure to resist earthquake is costly.
Emergency drills
 People take part in emergency drills by moving to safe locations, listening to
instructions given by trained personnel and practicing first aid.
 They may also become members of local response teams that assist people during a
disaster.
Success:
 Japan conducts emergency drills on 1 Sept to commemorate Disaster Prevention Day
which prepares the people mentally on how to create to a disaster. Main roads are
blocked and emergency vehicles have to seek alternative routes to reach affected
areas.
Limitation
 As emergency drills are designed based on the most serious earthquake ever recorded
in the area in the past, the emergency frills and evacuation plans might not prepare
them adequately to prevent the devastation of the areas such as the 2011 earthquake
in Tohoku, Japan.
 There might be insufficient time for evacuation as earthquakes are difficult to predict.

11. Use of technology
 Earthquake and tsunami monitoring and warning systems
Success:
 Installations of earthquake sensors in earthquake prone zone help monitor the frequency
of vibrations and detect possible developments of an earthquake. E.g. earthquake
motion data is gathered from observation stations installed on bridges and roads
in Japan which enables an earthquake to be predicted.
 The sensors also help to quickly estimate damage to bridges, railways or other
infrastructure.
Limitations;
 Earthquake sensors are expensive to obtain, install and use.
 Warnings may not provide sufficient time for an evacuation.
 Noise, lightning or device failure may interfere with seismograph and result in false
warnings given.
 Difficult to give accurate warnings when multiple earthquakes occur close to each other.
20. What are the short term and long term responses to earthquakes?
Short term responses are important in saving lives however long-term responses need to be
put in place to save more life if an earthquake strikes again.
People trapped under collapsed buildings must be quickly located and freed. Some survivors
are found after being trapped for a couple of weeks without food. This will help to save life
for e.g. after the earthquake in Tohoku, Japan, in 2011, sniffer dogs and heat sensors were
deployed and successfully rescued man who are trapped.
Another short-term response is providing medical aid, food and clean drinking water
provided to survivors to prevent dehydration and spread of disease. Provision of immediate
aid helps survivors continue with their lives. e.g. after the earthquake in Afyon in 2002, the
Turkish Red Crescent Society responded by delivering 20000 tents, 50000 blankets and
3000 heaters to the region.
Long term responses must be put in place as it helps to save lives from another earthquake
which may strike again.
Infrastructure and amenities are rebuilt and improved upon after a disaster. Authorities
develop stricter building codes to ensure infrastructure is restored at a higher safety level
than before. e.g. after the earthquake in Kobe, Japan in 1995, Japan spent billions
developing technology to build more earthquake-resistant buildings. This will help to reduce
the collapse of building which will lead to more deaths if the earthquakes strike again.
Compensation is also given out through insurance or direct payments to people who have
lost their land and property. However, compensations are often insufficient and may not
cover the cost of damage.