Monday, 12 September 2022
TSUNAMI
TSUNAMI
The term ‘Tsunami’ has been coined from the Japanese term Tsu meaning ‘harbour’ and nami meaning ‘waves’. Tsunamis are waves generated by earthquakes, volcanic eruptions, or underwater landslides and can reach 15m or more in height devastating coastal communities. Tsunamis caused by nearby earthquakes may reach the coast within minutes. When the waves enter shallow water, they may rise to several feet or, in rare cases, tens of feet, striking the coast with devastating force. The Tsunami danger period can continue for many hours after a major earthquake.
Tsunamis are nearly always created by movement of the sea floor associated with earthquakes which occur beneath the sea floor or near the ocean. Tsunamis may also be generated by very large earthquakes far away in other areas of the Ocean. Waves caused by these travel at hundreds of kilometers per hour, reaching the coast several hours after the earthquake. Unlike ordinary tides, which are short, frequent and surface level, tsunami, are barely noticeable in their deep-sea formation stage. At this point despite a wavelength up to 100 km, they are shallow in depth and move at hundreds of
Kilometer per hour.
Tsunamis can be very large. In coastal areas their height can be as great as 10m or more (30m in extreme cases), and they can move inland several hundred meters.All low-lying coastal areas can be struck by tsunamis.
landslides
LANDSIDES
Landslides
Landslides are among the major natural disasters or calamities in the world. In hilly terrains of India, including Himalayan mountains landslides have been a major and widely spread natural disasters that strike life and property almost perennially and occupy a position of major concern. These landslides, year after year, bring about untold misery to human settlements apart from causing devastating damages to transportation and communication network. Landslides, debris fall, debris slide, debris flow, rock toppling etc. cause destruction of slope and ground surface, initiating the change of uncontrolled erosion in the mountain terrains.
FACTORS THAT CAUSE LANDSLIDES
Landslides occur because of the interplay of several factors.
Natural factors
★ Intensity of rainfall
★ Steep slopes
★ Stiffness of slopes
★ Highly weathered rock layers
★ Soil layers formed under gravity
★ Seismic activity
★ Poor drainage
Man made factors
★ Deforestation leading to soil erosion
★ Non-engineered excavation
★ Mining and quarrying
★ Non-engineered construction
★ Land use pattern
Vulnerable houses are those which are situated on:
- Existing landslides area.
- Steep natural slopes.
- Areas in or at the mouths of drainages (such as canyons).
- Houses constructed near foothills.
PROTECTION MEASURES FROM DAMAGE TO BUILDINGS
Site Selection
Landslides generally happen where they have occurred in the past, and in identifiable hazard locations. Areas that are typically considered safe from landslides include areas that have not moved in the past; relatively flat areas away from sudden changes in slope; and areas at the top of or along ridges. Houses built at the toe of steep slopes are often vulnerable to slides and debris flows.
Signs and Warnings
A house located on a hill can detect possible slope failure by watching for these signs:
Doors or windows stick or jam for the first time.
New Cracks appear on plaster, tile, brick or foundations.
Outside walls, walks or stairs begin pulling away from the building.
Slowly developing, widening cracks appear on the ground or on paved areas such as streets or driveways.
Underground utility lines break.
Fences, retaining walls, utility poles or trees tilt or move.
Water or bulging ground appears at the base of a slope.
The potential for landslides and destructive erosion can be greatly reduced or prevented with proper development, sound construction techniques, seasonal inspections and regular maintenance of drainage facilities.
Earthquake
EARTHQUAKE
"An earthquake is a sudden motion or trembling of the ground produced by the abrupt displacement of rock masses".
- Most earthquakes result from the movement of one rock mass past another in response to tectonic forces.
- The focus is the point where the earthquake's motion starts.
- The epicenter is the point on the earth's surface that is directly above the focus.
- Earthquake Magnitude is a measure of the strength of an earthquake as calculated from records of the event made on a calibrated seismograph.
- In 1935, Charles Richter first defined local magnitude, and the Richter scale is commonly used today to describe an earthquake's magnitude.
- Earthquake Intensity. is a measure of the effects of an earthquake at a particular place. It is determined from observations of the earthquake's effects on people, structures and the earth's surface.
- Among the many existing scales, the Modified Mercalli Intensity Scale of 12 degrees, symbolized as MM, is frequently used
Earthquake Hazards
Earthquake hazards can be categorized as either direct hazards or indirect hazards.
Direct Hazards
- Ground shaking
- Differential ground settlement
- Soil liquefaction
- Immediate landslides or mud slides, ground lurching and avalanches
- Permanent ground displacement along faults
- Floods from tidal waves, Sea Surges & Tsunamis
Indirect Hazards
- Dam failures
- Pollution from damage to industrial plants
- Delayed landslides.
Most of the damage due to earthquakes is the result of strong ground shaking. For large magnitude events, trembling has been felt over more than 5 million sq. km.
Site Risks
Some common site risks are:
- Slope Risks - Slope instability, triggered by strong shaking may cause landslides. Rocks or boulders can roll considerable distances.
- Natural Dams - Landslides in irregular topographic areas may create natural dams which may collapse when they are filled. This can lead to potentially catastrophic avalanches after strong seismic shaking.
- Volcanic Activity - Earthquakes may be associated with potential volcanic activity and may occasionally be considered as precursory phenomena.
- Explosive eruptions are normally followed by ash falls and/or pyroclastic flows, volcanic lava or mud flows, and volcanic gases.
Tuesday, 12 July 2022
Geological disasters
Geological disasters
Geological disasters are caused by the transition of rock mass from stable equilibrium to the unstable state. This transition is accompanied by release of large amounts of energy. The disasters of this type are classified as:
- Earthquake
- Landslides
- Tsunami
- Mining
- its magnitude
- geological and soil conditions
- location of fault
- construction of major structures and
- prevailing construction practices in the particular areas.
- Rann of Kutch (1819) magnitude 8.0
- Assam (1897) magnitude 8.7
- Kangra (H.P.) (1905) magnitude 8.0
- Bihar-Nepal border (1934) magnitude 8.4
- Andaman Islands (1941) magnitude 8.0 and
- Assam (1950) magnitude 8.6.
- Uttarkashi (1991)
- Latur (1993) and Jabalpur (1997)
- Chamoli (1999)
- Bhuj (2001).
- The affected area had a known history of earthquake occurrence and widespread damage took place due to this earthquake.
- The non-engineered buildings found throughout the rural areas and the old stone buildings in the towns suffered severe damage.
- The engineered buildings faced the earth quake in a very safe manner and suffered no damage, except for minor cracks in the buildings
- There was large scale damage to infrastructural facilities in the earthquake affected area.
- The damage to roads was due to rockfall, landslides and' rock-slides along the road side slopes causing heavy damage
- Services like communication network and power supply system were affected very badly
- The buildings that house health and education facilities suffered damaged the joints in the piped supply lines failed due to ground shaking, resulting in disruption of water supply
- A large number of bridges were located to cross the rivers and deep river valleys throughout the hilly area.
- The Gawana bridge on the road to Gangotri suffered 'slight to medium damages.
- Widespread damage took place due to this earthquake.
- Due to the earthquake most of the houses were destroyed' causing death of people in large numbers as also a wide spread damage to installations and properties
- The entire region had a traditional system of dwelling unit construction which involved heavy stone walls, and a massive roof over the wooden timber sub-structure.
- During the earthquake most of the houses were destroyed' causing death of people in large numbers along with widespread damage to installations and properties
- Army services were pressed into action for the rescue operation. This involved clearing rubble, rescuing the injured, removal and cremation of dead bodies.
- Provisions were made for temporary relief shelters to the survivors of the earthquake. These
- shelters were made up ofG.1. (galvanized iron) sheeted roofs over the bamboo
- or wooden frames. About 30,000 families were provided the temporary
- shelters in the two worst affected districts of Latur and Osmanabad,
- Landslides are simply defined as the mass movement of rock, debris or earth down a slope and have come to include a broad range of motions whereby falling, sliding and flowing under the influence of gravity dislodges earth material.
- They often take place in conjunction with earthquakes, floods and volcanoes. At times, prolonged rainfall causing heavy block the flow or river for quite some time.
- The formation of river blocks can cause havoc to the settlements downstream on it's bursting. In the hilly terrain of India including the Himalayas, landslides have been a major and widely spread natural disaster the often strike life and property and occupy a position of major concern.
- the Himalayas and
- the Western Ghats.
- The term ‘Tsunami’ has been coined from the Japanese term Tsu meaning ‘harbour’ and nami meaning ‘waves’. Tsunamis are waves generated by earthquakes, volcanic eruptions, or underwater landslides and can reach 15m or more in height devastating coastal communities.
- Tsunamis caused by nearby earthquakes may reach the coast within minutes. When the waves enter shallow water, they may rise to several feet or, in rare cases, tens of feet, striking the coast with devastating force. The Tsunami danger period can continue for many hours after a major earthquake.
- Tsunamis are nearly always created by movement of the sea floor associated with earthquakes which occur beneath the sea floor or near the ocean. Tsunamis may also be generated by very large earthquakes far away in other areas of the Ocean. Waves caused by these travel at hundreds of kilometres per hour, reaching the coast several hours after the earthquake.
- Tsunamis can be very large. In coastal areas their height can be as great as 10m or more (30m in extreme cases), and they can move inland several hundred meters. All low-lying coastal areas can be struck by tsunamis.
- A tsunami consists of a series of waves. Often the first wave may not be the largest. The danger from subsequent tsunami waves can last for several hours after the arrival of the first wave.
- Sometimes a tsunami causes the water near the shore to recede, exposing the ocean floor. This is nature’s Tsunami warning.
- The force of some tsunamis is enormous. Large rocks weighing several tons along with boats and other debris can be moved inland several meters by tsunami wave activity. Homes and other buildings are destroyed. All floating material and water move with great force and causing mortality or injuries to people.
- Tsunamis can occur at any time of day or night.
- Tsunamis can travel up rivers and streams that lead to the ocean thereby polluting them.
- Tsunamis may also be generated by very large earthquakes far away in other areas of the Ocean. Waves caused by these travel at hundreds of kilometres per hour, reaching the coast several hours after the earthquake. Unlike ordinary tides, which are short, frequent and surface level, tsunami, are barely noticeable in their deep-sea formation stage. At this point despite a wavelength up to 100 km, they are shallow in depth and move at hundreds of kilometre per hour.
Disaster Management
Disaster Management
Disaster management is a process of effectively preparing for and responding to disasters. It involves
- strategically organizing resources to lessen the caused by disasters.
- a systematic approach to managing the responsibilities of disaster prevention, preparedness, response, and recovery.
Disaster and Development
Disaster and Development
Historically it has been seen there has been an apparent increase in the number of natural disasters resulting in increasing losses due to urbanization and population growth. This is a rigid one-sided outlook of development that recognizes only growth aspect, without an eye on sustainability. In the context of definition of a disaster. we recognize only damage and destruction.
With reference to the tsunami in 2004, Maldives, Sri Lanka, and Thailand suffered from non-ecologically sustainable over-development in coastal areas and India, Sumatra and North East Sri Lanka, suffered because affected pockets were inaccessible due to underdevelopment and impoverishment of the people. Such disastrous events have demonstrated that development has to continue, but with due concern for protection of the environment.
Science and technology should be fruitfully employed to control disasters. Alternatives should be generated by research and development in science and technology with emphasis on science and technology, especially information communication technology (ICT) for better understanding of disasters and better reach of disaster response efforts
Disasters and Development are interrelated, both in positive and negative ways.
- Disasters can set back development by wiping out decades of economic and social development. Disasters can also limit social development. Disasters worsen poverty in communities.
- Disasters can provide development opportunities by development policy in the aftermath period. Disasters can elevate the development potential of a society by becoming a catalyst for change in the form of reconstruction and social development as well as upgrading administrative capability and training of personnel involved. Ex: Reforestation programs after landslides and flash floods to check soil erosion, have spin off effects on other sectors, such as improved air quality, better flora and fauna, health and longevity for people, etc. These in-turn work as development programs in the form of more sources of income for the poor, enhanced employment opportunities, etc. Development opportunities often are compromised because of excessive focus on relief assistance. Disasters can also be a major vehicle for carrying out major development programs.
- Development can increase vulnerability as Social and economic development can increase the vulnerability of the community to disaster risks. It has been shown time and again that economic development increases disaster risk. Rapid urbanisation has increased the vulnerability of the community. Urban development often leads to an influx of relatively low income groups, with large scale settlement of marginal land or in high density, poor quality housing. Marine and coastal zone development leads to population concentrations, exposed to possible storm surge, high wind, flash flood and landslide risks.
- Development can reduce vulnerability as demonstrated in the examples given below:
- Disaster resistant technologies in buildings that are being newly constructed in Malaysia is a good example of development oriented towards risk reduction
- Social development includes awareness/education to reduce human vulnerability and limit losses in a disaster
- A literate and better-educated population, including women and girls, is better able to cope up effectively to any disaster by responding effectively to early warnings
Capacity
Capacity
The International Strategy on Disaster Reduction (ISDR), United Nations (UN), defines Capacity “as a combination of all the strengths and resources available within a community, society or organization that can reduce the level of risk, or the effects of a disaster. This involves managing resources, both in normal times as well as during crisis or adverse conditions. The strengthening of coping capacities usually builds resilience to withstand the effects of natural and induced hazards.”
It is widely believed that vulnerability and capacity should be integrated in all assessments with regard to disaster management. The severity of the impact of a disaster depends on the balance of vulnerability and capacity of a particular community.
As per the FAO directory, "Within the context of disaster management, development is defined as a process that reduces vulnerabilities and increases capacities".
The five categories involving Vulnerability and Capacity Analysis (VCA) are:
- Economic
- Natural
- Physical
- Human, and
- Social
Risk
Risk
“Risk” usually refers to the probability of loss of a ‘valued resource’. In the context of health and environmental risks, the word “risk” integrates two ideas:
- the potential for detrimental consequences and
- the uncertainty associated with the circumstances
Hazard
Hazard
According to the United Nations International Strategy for Disaster Reduction (UNISDR), a hazard is a natural process or phenomenon that may pose negative impacts on the economy, society, and ecology. It includes both natural factors and associated human factors.
A hazard can be defined as a potentially damaging physical event, social and economic disruption or environmental degradation. Hazards can be the creation of man or the environment.
A hazard is always present and it simply acts as a catalyst to bring adverse effects into focus. A hazard is defined as a potential cause which is activated when the right configuration of factors present themselves. A hazard may or may not lead to an event.
A hazard is defines as “a potentially damaging physical event, phenomenon or human activity that may cause the loss of life or injury, property damage, social and economic disruption or environmental degradation.” Hazards could be, natural (geological, hydro-meteorological and biological) or induced by human processes (environmental degradation and technological hazards).
Hazards can be single, sequential or combined in their origin and effects. Hence, Hazard analysis entails the identification, study and monitoring of a hazard to determine its potential, origin and characteristics.
Hazards are generally classified as:
- Sudden onset hazards: geological and climatic hazards such as earthquakes, tsunamis, floods, tropical storms, volcanic eruptions, and landslides.
- Slow onset hazards: (environmental hazards) drought, famine, environmental degradation, desertification, deforestation, and pest infestation.
- Industrial/Technological: system failures/accidents, spillages, explosions, and fires.
- Wars and civil strife: armed aggression, insurgency, terrorism, and other actions leading to displaced persons and refugees.
- Epidemics: water and/or food-born diseases, person-to-person diseases (contact and respiratory spread), vector-born diseases and complications from wounds.
Hazards could also be classified as direct and indirect.
Examples of "Direct Hazards" include:
- Ground shaking
- Differential ground settlement
- Soil liquefaction
- Immediate landslides or mud slides, ground lurching and avalanches
- Permanent ground displacement along faults
- Floods from tidal waves, sea surges & tsunamis
- Dam failures
- Pollution from damage to industrial plants
- Delayed landslides.
- Slope risks
- Natural dams (formed by landslides in irregular topographic areas and are susceptible to collapse when filled leading to catastrophic avalanches after strong seismic shaking)
- Volcanic activity
Saturday, 25 April 2020
QUIZ - 2
- List the important human factors that influence disaster severity
- How are disasters a precursor to scientific advancements leading to development
- List the factors affecting vulnerability to disasters
- List the impact of disasters on dams and embankments
- Define "climate change adaptation" and list a few examples of the same
- Define "indigenous knowledge"
- List a few appropriate technologies used in disaster management
- Define Disaster Risk Management
- List the components of disaster relief
- What is disaster management policy
- List few policies related to disaster management
- List policies related to disaster management other than disaster management act 2005 and disaster management policy
- List the priority themes of the sendai framework
- List the programs related to disaster management
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