powerpoint presentation on natural hazards and disaster,types,mitigation and management....

2. Natural Hazards

3. Introduction to Natural Hazards
• What is a “Geohazard”?
– Earth processes (involving the lithosphere,
hydrosphere & atmosphere) that, upon interaction
with human activity, cause loss of life and property
Hazardous
geo- human
process
condition
process
or result
– It is important to understand the human element
• without it, there would be no hazard
• because of it, the science of geohazards becomes more
important every year
– mitigation: reduction/prevention

4. Why is the human element so
critical?
• The Earth’s population is increasing
• more people living in hazard-prone areas
• populations are becoming hyper-concentrated
• consumption of resources
• examples:
– today there are 6 billion people on Earth ( ~ 50% live in cities)
– by 2025, there will be ~8 billion people (~ 66% in cities)
– of these cities, 40% are coastal
» prone to severe storm and tsunami damage
– and a large majority lie in areas subject to other geohazards
(for example volcanoes and earthquakes)

6. •CANNOT stop the geologic processes
•CANNOT stop the population growth/expansion
•Therefore, we must try to reduce (mitigate)
the hazards through:
•scientific study
•population education
•changes in engineering/building practices
•management plans and hazard response scenarios

7. Types of Natural Hazards
• Volcanoes, floods,
earthquakes, tornadoes,
tsunamis, etc.
– can act adversely on human
processes
– can occur:
• without warning (e.g. earthquakes)
• with warnings (precursors) (e.g.
satellite monitoring of cyclone tracks,
or the presence of ground
deformation at a volcano before an
eruption)

8. • To help mitigate the hazard we need to know:
• Frequency vs. Magnitude
– F: how often a given event occurs in a certain
region
– M: how powerful (amount of energy released) an
event is
• for example, high M hazards happen with low F, but are
much more destructive
• Scope
– S: area affected by a given hazard
• local: landslides, floods, earthquakes, fire …
• regional: tsunamis, volcanoes, larger earthquakes,
cyclones …
• global: large volcanoes, global warming, meteorite
impacts …

9. Practical Exercise 1.
Impact of Environmental
Disasters

10. Earthquakes
and Tsunamis

11. What is an Earthquake?
• Ground movement caused by the sudden
release of seismic energy due to tectonic forces.
The focus of an
earthquake is the actual
location of the energy
released inside the
Earth’s crust.
The epicentre is the
point on the Earth’s
surface directly above the
focus.

12. Why do earthquakes occur?
• Seismic energy is usually caused by the brittle
failure (fracturing) of rocks under stress.
Figure showing
the distribution of
earthquakes
around the globe
• This commonly occurs due to movement along
tectonic plate boundaries

13. Earthquake Magnitude
Magnitude Earthquake Effects Approx. number
each year
< 2.5 Usually not felt, but recorded 900,000
2.5-5.4 Often felt, only minor damage 30,000
5.5-6.0 Slight damage to buildings and 500
other structures
6.1-6.9 May cause a lot of damage in very 100
populated areas
7.0-7.9 Major earthquake. Serious 20
damage.
> 8.0 Great earthquake. Can be totally 1 every 5-10 years
destructive near the epicentre.

14. San Francisco - Great Earthquake
• Magnitude 7.7 - 8.3

15. Earthquake Hazards
• These are important hazards to understand:
– the natural hazard that on average kills the highest
number of people per year (> 1 million during the
past century)
– commonly strikes without warning
– no time for evacuation
– not a predictable trend to earthquake numbers,
magnitude or location
• 1000's of large earthquakes every year
• ~ 20 are > M7.0 and these account for 90% of the energy
released and 80% of all the fatalities

17. How do we mitigate the
hazard from earthquakes?
• Reinforce buildings
• Education
• Disaster plan

18. Earthquakes and Tsunami’s
• An earthquake under the ocean has the
potential to form a tsunami.
• The earthquake must vertically displace
overlying water (extensional or
compressional faults - not transform)
Extension Compression
Transform

19. How does an earthquake form
a tsunami?

20. 2004 South Asian
Boxing Day event
• Biggest earthquake
in 40 years!
• Magnitude 9.2
• 150 km off the west
of Northern
Sumatra
• Generated a
disastrous tsunami
in 12 countries

21. Second largest recorded earthquake
• The earthquake occurred at a convergent
tectonic plate boundary (subduction zone)
• An estimated 1,600 km (994 miles) of faultline
slipped about 15 m (50 ft)!
• The earthquake released 20 x 1017 Joules of
energy
– Equivalent to:
• 475,000,000 kg of TNT
• 23,000 Hiroshima atomic bombs!

22. Tsunami
Animations of
the Boxing
Day tsunami
showing how
the tsunami
radiated from
the entire
Above: Countries most effected by length of the
the tsunami 1,600 km (994
miles) rupture.

23. A village
near the
coast of
Sumatra
lays in ruin
after the
tsunami.

24. How do we mitigate the
hazard from tsunamis?
• Monitoring
– process is very technology-
intensive
• high costs for many poorer
countries
– often no technology available to
monitor local tsunamis
• for example,
• Papua New Guinea has no
monitoring stations
– reliant on the Pacific Tsunami
Warning Center
• tsunami in 1998 was not detected

25. How do we mitigate the
hazard from tsunamis?
• Building restrictions in
hazard prone areas
– In Hawaii, Hilo harbor and
downtown was destroyed
by the tsunamis of 1946
and 1960
– The town is now rebuilt on
higher ground and the
devastated area is a park

26. How do we mitigate the
hazard from tsunamis?
• Seawall construction
– cause early wave breaking
– prevent wave run up into urban areas

27. How do we mitigate the
hazard from tsunamis?
• Education
– warning systems
– evacuation plans
– general understanding
of the hazards involved
Punishment Natural event
From God 35%
45%
Bomb 20%
Population reaction:
Papua New Guinea (1998)

28. Practical Exercise 2.
Locating Earthquake
Epicentres

29. Tropical Storms

30. Same Storm - Different Name

31. Tropical Cyclones
• Background:
– Can be deadly!
• For example, in 1991 a large
cyclone in Bangladesh killed
>138,000 people in just two
days!

32. Tropical Cyclones
• Most widespread
destructive weather hazard
– For example: Hurricane
Floyd (1999)
• only a moderate level
hurricane
• caused US$5.6 billion in
damage in the Bahamas
and North Carolina (USA)
and 57 fatalities
(Left) Three different cyclones spinning over
the western Pacific Ocean on August 7, 2006.

33. How do cyclones form?
The above figure shows how cyclones form. The green arrows show
where warm air is rising. The red arrows indicate where cool air is sinking.

34. Cyclone Categories
Category Wind Speed Damage at Storm Surge
(mph) Landfall (feet)
1 74-95 Minimal 4-5
2 96-110 Moderate 6-8
3 111-130 Extensive 9-12
4 131-155 Extreme 13-18
5 > 155 Catastrophic 19+
The Saffir-Simpson Hurricane Scale

35. Hurricane Katrina
• Hurricane Katrina
was the most costly
and most deadly
hurricane in the
history of the USA.
– Category 5
• At least 1,836
fatalities
• Damage estimated at
US$ 81.2 billion

36. Hurricane Katrina

37. What damage is produced?
• Storm Surge
– water that is pushed toward the shore
by the force of the cyclone winds.

38. What damage is produced?
• Wind
– responsible for the
loss of power and
utilities
– wind damage affects
larger areas than
surge
– flying debris
– tree loss

39. What damage is produced?
• Flying debris
– debris
propelled at
high speeds

40. How do we mitigate the
hazard from a cyclone?
• Monitoring
– early warning systems
• Infrastructure
– cyclone walls
– communal shelters
• Education and
planning

41. Natural Hazards Summary
Graph
showing the
number of
deaths per
year due to
natural hazard
events

42. Damage HAZARD
Potential
Awareness- Effect
on Elements
Society
Quicker
Recovery
Elements at Risk
Action
Plans Huge Losses/
Communities
Damages More
Resilient
Reduced
More Stable Society
Losses

43. Damage HAZARD
Potential
Elements at Risk
Natural Features Societal Elements
River/Stream Banks People & Live-stock
Low-lying Areas Huts & Semi-permanent Houses
Sea & Sea-coast Weak Buildings
Slopes of hills Agri. & Horticultural crops
Livelihood tools / Equipment
Unsecured personal assets
Public Infrastructure

44. CYCLONE
Damage
Potential
Poorer than
Society before
Elements at Risk
Disruption of
Normal life &
Huge Losses/ Development
Damages Suffers

45. Types of disasters
Major natural disasters: Minor natural disasters:
• Cold wave
• Flood
• Thunderstorms
• Cyclone • Heat waves
• Drought • Mud slides
• Earthquake • Storm
Major manmade disaster: Minor manmade disaster:
1. Setting of fires • Road / train accidents, riots
2. Epidemic • Food poisoning
3. Deforestation • Industrial disaster/ crisis
4. Pollution due to prawn • Environmental pollution
cultivation
5. Chemical pollution.
6. Wars

46. Scale of Disaster
Is Dependent on :
• Lead Time Available.
• Intensity of Hazard.
• Duration.
• Spatial Extent.
• Density of Population & Assets.
• Time of Occurrence.
• Vulnerabilities existing in the
Elements at Risk.
• Hazard X Vulnerability =
Disaster

47. ELEMENTS AT RISK
• People
• Livestock
• Rural Housing Stock
• Houses Vulnerable
• Crops, Trees,Telephone, Electric
poles
• Boats, Looms, Working Implements
• Personal Property
• Electricity, Water and Food Supplies
• Infrastructure Support

48. AIMS OF DISASTER MANAGEMENT
• Reduce (Avoid, if possible) the
potential losses from hazards.
• Assure prompt and appropriate
assistance to victims when
necessary.
• Achieve rapid and durable
recovery.

49. PRE-DISASTER DURING DISASTER
POST-
DISASTER
DISASTER MANAGEMENT CYCLE

50. Stages of Disaster
Cyclone
BEFORE DURING AFTER
Jan - Apr MAY June- Oct
Well Before
Weeks-Months
Just Before Actual Time
- Hours Period
Rescue Relief Rehabilitation Reconstruction

51. Role Players in Disasters
• People : Individuals, House -Holds,
Volunteers
• Gram Panchayat : Sarpanch, Panchayati
Secretary, Panchayati Members
• Village Elders : Caste/Community/Religious
Leaders, Teachers, Doctors, Engineers,
Retired Army & Police Personnel
• Govt. Deptl. Officers : Agriculture, Medical,
Engineers (Housing, Roads & Buildings,
Irrigation) Revenue Department, Public
Health, Police etc. NGOs

52. DEFINITIONS OF “VULNERABILITY”
• “The extent to which a community,
structure, service or geographic
area is likely to be damaged or
disrupted by the impact of particular
disaster hazard…”
• “Vulnerability is the propensity of
things to be damaged by a hazard”.

53. DISASTER PREPAREDNESS
• Disaster preparedness aims at
minimizing the adverse effects of a hazard -
• Through effective precautionary actions
• Ensure timely, appropriate and efficient
organisation and delivery of emergency
response following the impact of a disaster.

54. PREPAREDNESS
• Vulnerability Analysis and Mapping to include
Resources.
• Assess strengthening requirements and execute.
• Funding for preparedness must be arranged.
• Peoples’ cooperation through Political leaders,
elders, Volunteers and NGOs
• Create lead time by interpreting Warnings
• Plan to include movement of resources with time
frame.
• Aim to reduce the destructive potential of
cyclones, timely & appropriate relief to victims
and quick & durable recovery

55. Disaster Preparedness
Framework
COMPONENTS OF PREPAREDNESS
Vulnerability Planning Institutional
Assessment Framework
Information Resource Warning
System Base Systems
Response Public Rehearsals
Mechanisms Education
and Training

56. Disaster Response Activities
• Warning
• Evacuation/Mitigation
• Search and Rescue
• Assessment
• Emergency Relief
• Logistics and Supply
• Communication and information Management
• Survivor Response and coping
• Security
• EOC & coordination
• Expedite rehabilitation and reconstruction.

57. Floods and Water Hazards
Elements at Risk Main Mitigation
• Everything in the Strategies.
flood plain. • Land use control
• Earthen or soluble • Engineering of
structures strictures
• Buried services • Elevation of structures
and utilities • Flood control
structures
• Food stores
• Reforestation projects
• Crops and (watershed
livestock management)

58. Strong Winds
Main Mitigation
Elements at Risk
Strategies.
• Lightweight structures.
• Elevated utilities • Structural
(Power and engineering
communication lines) measures.
• Fishing boats and • Planting of
other maritime
industries.
windbreaks.