Sunday, 28 April 2019

Tropical cyclones and local storms

TROPICAL CYCLONES AND STORMS

TROPICAL CYCLONE
  • Tropical cyclones are generated in tropical areas of the ocean near the equator
  • The winds generated move around a central eye
  • Wind direction is counter-clockwise in the northern hemisphere and clockwise in the southern hemisphere
  • They are low-pressure systems
  • The low pressure calm centre of circulation is called the 'eye'
  • The area around the eye with the fastest, most violent winds is called the 'eye wall'
  • Bands of thunderstorms circulating outward from the eye are part of the evaporation-condensation cycle that feed the storm are called 'Rain Bands'
Stages of development of a tropical cyclone:
  1. Tropical wave is a trough of low-pressure in the trade-wind easterlies
  2. Tropical disturbance is a moving area of thunderstorms in the tropics that maintains its identity for twenty four hours or more
  3. Tropical depression: is a tropical cyclone in which the maximum sustained surface winds is almost sixty kmph
  4. Tropical storm is a tropical cyclone in which the maximum sustained surface wind speed is almost 120 kmph
  5. A tropical cyclone has maximum sustained surface winds of almost 118 knph. It is also called a hurricane or typhoon in different parts of the world 
The three events essential for a cyclone to form are:
  1. A continuing evaporation-condensation cycle of warm, humid ocean air
  2. Patterns of wind characterized by converging winds at the surface and  strong uniform wind speeds at higher altitudes
  3. A pressure gradient between the surface and high altitude
LOCAL STORMS:
  1. Storms are a result of vertical circulation in the atmosphere
  2. Heavier (cold ) air sinks and warm air (lighter) rises
  3. Potential energy is converted to kinetic energy
  4. Strong winds are intense when a thunderstorm is accompanied by heavy rain
  5. Due to precipitation surrounding air cools down and is dragged down
  6. Near ground level, the stream of air veers into a horizontal plane causing rain or hail stones into a sloping trajectory, sometimes at 45 degrees from the vertical
  7. A local storm is produced by a cumulonimbus cloud and accompanied by lightening and thunder, usually with strong gusts wind, heavy rain and sometimes with hail
Destruction by Cyclones
The destruction caused by cyclones depends on its intensity, location and size. The effects of a cyclone can be divided into:
  • Primary Hazards
  • Secondary Hazards and
  • Tertiary Hazards
Examples of primary hazards are:
  1. Strong winds, heavy rains and storms
  2. Abnormal rise in sea level at the coast
  3. Submergence of low lying areas near the coast resulting in drowning  of humans, livestock, habitations, destroying vegetation and soil fertility
  4. Very strong winds damage houses, trees and communication systems resulting in huge loss to life and property
Examples of secondary hazards are:
  1. Floods, fire and freshwater flooding
  2. Floods in rivers causing submergence of nearby inhabited areas
  3. Erosion of valuable fertile agricultural land
  4. Destruction of buildings
  5. Strong winds in forest regions result in forest fires which spread the intensity of cyclonic winds
 Examples of tertiary hazards are:
  1. Tertiary hazards include diseases caused due to stagnant water, water poisoning and increase in prices of goods and resources
 Sometimes all the hazards occur simultaneously because of which relief operations become difficult. . As the water level rises in the streets, transportation, communication, rescue operations and clean-up efforts extremely difficult.
Death toll due to cyclones is very high. Despite their devastating effects, cyclones of low intensity are beneficial because they bring rain to dry areas and move heat from the tropical regions.

Destruction due to local storms
Strong winds due to storms can damage and destroy vehicles, buildings, bridges and other outside objects turning loose objects into deadly flying projectiles.
Local storms damage the power supply to the local region
They also damage communication and hamper rescue and relief efforts
Cloud-to-ground frequently occurs during storms
They also damage vital local infrastructure

Cumulative atmospheric hazards or disasters

CUMULATIVE ATMOSPHERIC HAZARDS OR DISASTERS

The word 'cumulative' refers to increment by successive additions. Atmospheric hazards or disasters refers to oxygen deficiency, dust, chemical vapours, welding fumes, fog or mists that can interfere with the body's ability to transport and utilize Oxygen. Such hazards have negative toxicological effects on the human body. 

Confined spaces can be found in industrial settings,public utilities and the construction industry. The safety hazards associated with confined spaces can cause serious injury and death. These hazards can be called as atmospheric hazards or physical hazards.

Atmospheric hazards include:
  • Oxygen deficiency
  • Oxygen displacement
  • Flammable atmospheres and
  • Toxic gases
Oxygen deficiency: Low levels of oxygen can be caused by consumption of Oxygen during open flame operations such as welding, cutting or brazing. In addition, low levels of Oxygen can be present in manholes that are located near garbage dumps, landfills and swampy areas where fermentation has caused the consumption of oxygen.

Oxygen displacement: Some type of gases will displace oxygen from a confined space. Sometimes Nitrogen is used to purge gases from tanks. If a person enters the tank before Nitrogen was properly removed and vented from the tank, the person could die within a matter of minutes

Flammable atmospheres: Some confined spaces could contain flammables like solvents, fuel oil, gasoline, kerosene, etc that provide fuel for combustion. For the atmosphere to become flammable, it must have the proper mixture of oxygen and fuel. A fire hazard is possible in confined spaces if the right mixture of oxygen, fuel and a spark are present.

Toxic gases: Toxic gases can be present in a confined space because of type of manufacturing processes or toxic substances during production or biological and chemical breakdown of the product being stored in the tank. Common types of toxic gases encountered in confined spaces are:
  1. Hydrogen sulphide: Colourless gas with odour of rotten eggs It inhibits exchange of oxygen at the cellular level and causes asphyxiation. It causes a loss of sense of smell
  2. Carbon monoxide: It is a colourless and odourless gas and inhibits the body's ability to transport Oxygen to all parts of the body
  3. Solvents: Solvents such as kerosene, gasoline, paint strippers, degreasers are flammable and when inhaled at high concentrations causes Central Nervous System (CNS) effects such as dizziness, drowsiness, lack of concentration, confusion, headaches, coma and ultimately death
Two or more of the above listed hazards or disasters occurring together adds-up the effects and this is called 'Cumulative atmospheric hazards or disasters'

Impact of disasters on development projects

IMPACT OF DISASTERS ON DEVELOPMENT PROJECTS

Disasters derail development. According to the United Nations (UN), over the past two decades, disasters from natural hazards have affected more than 4 billion people, claimed more than 1 billion lives, and caused almost U.S. $ 2 trillion in economic losses. Disasters have a devastating effect on development. Apart from loss of human life and economy, the psychological impact of disasters on the mental health of the affected people leads to low attendance at work and retards the economic growth of the region in general. The impact of disasters on specific development projects is discussed below-

IMPACT ON DAMS
The drive for economic growth has exposed populations to increased risk.Destruction has been exacerbated by the development of dams in fragile ecosystems. Hence, disasters reveal boundaries and limits to development.All countries suffer from disasters but their impact is felt to the maximum extent in poor countries.In case of development project involved in construction of dams, the disasters like flash floods, earthquakes and landslides can delay the project and adversely affect the finances allocated to the project as additional expenditure will be required in operations like clearing of debris, redesigning the project to suit the changed landscape, salvaging the usable construction material and disposal of incomplete structure. The ongoing progress of the project is pushed back and the project is delayed considerably.

IMPACT ON EMBANKMENTS
An embankment is a wall of brick or stone built to prevent flooding. The natural disasters that can affect its development are Earthquakes, landslides, floods as all these disasters result in affecting the surface of the Earth. Earthquakes destabilise the foundation of the embankment causing it to collapse. Floods may weaken the bonds between the bricks and stones by dissolving the cement or water may act as a lubricant between stones causing the stones to slide against each other leading to collapse of the structure. Flood water may be absorbed into bricks and swelling of bricks may lead to cracking and ultimately collapse of the structure. Earthquakes cause embankments to collapse as the entire structure is built on land. Landslides cause a section of land to slide over another and this disturbance of land also collapses the embankments.

IMPACT ON CHANGES IN LAND-USE
Land-use refers to a particular purpose for which a parcel of land is used. Change in land-use refers to using a particular area of land for a different purpose than which it was being used. Examples of this are:
  1. Clearing a forest area for residential purpose
  2. Clearing a forest area for agriculture
  3. Clearing a residential area for industries
  4. Clearing agricultural land for industries etc
Disasters will have a profound impact on any change in land-use. This happens primarily because the local community will have experienced the area and will have the knowledge regarding the do's and don'ts in specific areas as a result of previous experience. When ever there is a change in land-use pattern as listed above takes place activities of the new community might not be in synchronicity with the ecological cycle of resource withdrawal. This might result in disasters.Change in land-use has been the most common factor in recent natural disasters.Few examples are listed below:
  • Mangroves in coastal areas act as natural barriers to strong winds and storm surge associated with land falling tropical cyclones. Cutting these mangroves for agriculture removes the natural barrier and thereby increases the intensity of land falling cyclones.
  • Mangrove ecosystems along the mithi river and mahim creek in Mumbai were destroyed and replaced with haphazard construction. Sewage and garbage dump also destroyed the mangroves. The Mumbai floods of July 26, 2005 is a classic example of modifying land-use contributing to a major disaster where more than 1000 lives were lost.
  • Chennai floods of 2015 and floods in Bengaluru and Hyderabad have demonstrated that haphazard change in land-use has become a major source of disasters caused by natural hazards
  • Major floods in Uttarakhand in 2014 and Kashmir have shown that land-use change and unplanned development have been the real cause of large-scale disasters.

Friday, 26 April 2019

Cyclones and floods

Cyclones
The word 'cyclone' is derived from a Greek word meaning 'coil of snake'. In meteorological terms, cyclone is a low pressure from all sides. A cyclone may be elliptical, circular or 'V' shaped. Cyclones can be classified as tropical or temperate based on the location where they occur. The various impacts of cyclone  are listed below:
  1. Storm surge causes
    1. Flooding in coastal areas
    2. Erosion of beach
    3. Loss of soil fertility and
    4. Damage to structures
  2. Winds
    1. Damage to structures
    2. Loss of power and communication
    3. Loss of life
    4. Agricultural loss and livestock losses
      3.Torrential rains
    1.  Flooding in inland areas
    2. Land subsidence
    3. Contamination of water supply system
    4. Destruction of  crops and livestock
It is difficult to measure the magnitude and intensity of a cyclone. Cyclones are usually accompanied with heavy rains and wind storms. Cyclones paralyse entire public services including communication and transportation. Damages caused by cyclones  to sanitation infrastructure causes a heightened risk of communicable disease outbreak like diarrhea and cholera.

In order to mitigate the effects of cyclones, a rehabilitation plan with geographical focus and prioritization of intervention should be prepared. The plan should contain measurable indicators like infrastructure, livelihood and habitat.

Floods
Floods are a common feature in India occurring in many areas. Floods are a natural phenomena.
Flood is a water related disaster. A flood occurs when the geomorphic equilibrium in the river system is disturbed due to intrinsic or extrinsic factors. or when the system crosses the geomorphic threshold.
  1. Flooding in the river bed due to aggradation of river bed (intrinsic threshold)
  2. Flooding in the river due to heavy rainfall (extrinsic threshold)
Floods in major cities especially in major cities during rainy season are disastrous not only to the environment but also has serious implications for human life and property
The different types of flood are:
  1. Flash floods
  2. River floods
  3. Coastal flood and
  4. Urban flood
According to the duration, floods can be classified as:
  1. Slow-onset floods 
  2. Rapid-onset floods and
  3. Flash floods
Floods can also be classified as:
  1. Natural
    1. Storm surge
    2. Tsunami
    3. Glacial melt
    4. Landslides
    5. Riverine, Estuarine and Marine floods
    6. Examples are bursting of landslide and blockades in the catchment areas of rivers
  2. Man-made
    1. Breach of dam / barrage / embankment
    2. Release from reservoir
    3. Urban flood
    4. Examples are breach of almatti and narayanpur dams in karnataka
Causes of floods
  1. Silting of river bed
  2. Inadequate capacity within the banks
  3. River bank erosion
  4. Flow obstruction and change in river course
  5. Common floods in the main and tributary rivers
  6. Poor natural drainage
  7. Cyclones
  8. Retardation of flow and backwater flow
  9.  Heavy rainfall
Factors influencing floods:
  1. Vegetation cover
  2. Climate
  3. Slopes
  4. Rainfall intensity and duration
  5. Land use
  6. Rock type
  7. Lakes and reservoirs
  8. Soil depth and type
Impact of floods
  1. Human loss
  2. Property loss
  3. Affects the major roads
  4. Disrupts transportation services
  5.  Spread of water-borne communicable services
  6. Disruption in electricity and communication services
  7. Social and economic disruption
  8. Pollution of air and water
Flood forecasting - Anticipating floods before they occur helps to take precautions and warn people in order to prepare people in advance for flood conditions.
In order to predict floods accurately, a long-time series of historical data that relates stream flows to measured past rainfall events is required.
Radar estimates of rainfall and general weather forecasting techniques are important components of good flood dorecasting.

Cold waves

COLD WAVES

A cold wave is a weather phenomenon that is distinguished by a cooling of the air. A cold wave is a rapid fall in temperature within a 24-hour period requiring substantially increased protection to agriculture, industry, commerce, and social activities. The precise criterion for a cold wave is determined by the rate at which the temperature falls, and the minimum to which it falls.

Cold wave can also be caused by invasion of very cold air over a large area. It is a prolonged period of excessively cold weather that may be accompanied by winds that cause excessive wind chills causing weather to appear colder than it actually is.Cold waves can be preceeded or accompanied by winter weather events like blizzards or ice storms.

Effects of cold waves:
  • Sudden cold waves can cause frostbites, hypothermia and other serious medical conditions
  • Grazing animals may die of starvation
  • Water pipelines may freeze and burst
  • Cold waves also invite excess electricity bills due to the energy spent in heating rooms at work or residence
Cold waves cannot be forecasted but can be managed by implementing proper disaster plans


Thursday, 25 April 2019

Causes of floods and tropical cyclones

CAUSES OF FLOODS

Floods are experienced all over the world for a variety of reasons both natural and man made or human-induced. Some of the reasons are natural while many others are human induced or man-made. Some of the reasons are listed below:

  1. Heavy rains - The simplest explanation for floods is heavy rains. Human beings designed infrastructure and systems designed to move rainwater into appropriate basins and reservoirs. However, incessant and heavy rains cause these systems to be overwhelmed causing rainwater to back-up and causes the water level to rise and flood residential and commercial buildings. This normally happens due to heavy rainfall over a short period of time.                                                 
  2. Overflowing rivers - When rivers experience heavy rains, it could cause an overflow in the river and it may overflow the banks. Therefore overflowing rivers may also cause floods.                   
  3. Broken dams - Due to heavy rains, old dams may fail, and unleash torrents of water on households. Levees may fail aggravating the effects of a flood. Dams may fail structurally releasing the water behind as a flood                                                                                                           
  4. Urban drainage basins - Urban areas are primarily made of concrete and other impermeable material. This prevents water from being absorbed into the soil. This causes the drainage basins to fill-up quickly resulting in flooding of low lying areas                                                                             
  5. Storm surges and tsunamis - Storm surges related to hurricanes and other storms can result in  flooding like tsunamis caused due to underwater earthquakes.Sometimes storm surges and tsunamis give little warning before coming ashore                                                                                    
  6. Channels with steep sides - Flooding often occurs when there is fast run-off into lakes, rivers and other reservoirs. This occurs mainly where channels have steep sides.                                              
  7. Lack of vegetation - Vegetation can help slow run-off and prevent flooding. Where there is sparse to no vegetation, there is no obstruction to the flow of water and this is aggravated by drought like conditions. Lack of vegetation after a drought can cause flash flooding. This can happen if heavy rains are followed by long periods of drought                                                          
  8. Melting snow and ice - Heavy snow and precipitation in winter can cause flooding. This can aggravate flood like conditions in low-lying areas around the mountains. 

CAUSES OF TROPICAL CYCLONE

  1. A tropical cyclone is a rapidly rotating storm system characterized by a low-pressure center, a closed low-level atmospheric circulation, strong winds, and a spiral arrangement of thunderstorms that produce heavy rain.
  2. "Tropical" refers to the geographical origin of these systems, which form almost exclusively over tropical seas. "Cyclone" refers to their winds moving in a circle
  3. Winds in a cyclonic cyclone blow counterclockwise in the Northern Hemisphere and clockwise in the Southern Hemisphere.
  4. Tropical cyclones typically form over large bodies of relatively warm water
  5. They derive their energy through the evaporation of water from the ocean surface, which ultimately recondenses into clouds and rain when moist air rises and cools to saturation
  6. Coastal regions are particularly vulnerable to the impact of a tropical cyclone
  7. The primary energy source for these storms is warm ocean waters
  8. Though their effects on human populations are often devastating, tropical cyclones can relieve drought conditions
  9. They also carry heat energy away from the tropics and transport it toward temperate latitudes, which may play an important role in modulating regional and global climate

Wednesday, 24 April 2019

Other Policies related to disaster management


OTHER POLICIES RELATED TO DISASTER MANAGEMENT

Aside from the National Disaster Management Policy (NDMP), disaster management through public policy is an effort to inquire into the process of a hazard turning into a disaster, identify its causes and rectify the same to prevent future occurrences. Public policies on disaster management is concerned with minimizing and preventing the damaging impact of a natural or man-made hazard.

Some of the policies that need to be addressed with regard to disaster management are:

  1. Poor and weak or overcrowded buildings in an earthquake prone area
  2. Poor land-use planning in flood prone areas
  3. Inadequate and faulty laws regulating various processes and facilities
The Yokohoma strategy for disaster management at the world conference on disaster reduction held at Hyogo laid emphasis on disaster management policy framework, risk identification and early warning, knowledge management, reducing risk factors and preparedness for effective response and recovery.

The Hyogo conference adopted the framework for action (HFA) 2005-2015 called, "Building the resilience of National and Communities to Disaster."

In India, the central government lays down policies and provides technical, logistical and financial support while the district administration carries out most of the operations in collaboration with central and state level agencies.

The National Disaster Management Authority (NDMA) under the chairmanship of the prime minister is the apex body for laying down policies, plans and guidelines for disaster management and for coordinating their enforcement and implementation throughout the country.

The National Institute for Disaster Management (NIDM) is responsible for providing assistance to formulate national policy on disaster management.

At the state level, the State Disaster Management Authority (SDMA) headed by the state chief minister lays down policies and plans for disaster management in the state and policies related to disaster management at the district level are implemented by the District Magistrate (DM).

Policy of Emergency Operation Centres (PEO) at national, state and district level should be effectively implemented.

Appropriate knowledge and local resources


APPROPRIATE KNOWLEDGE AND LOCAL RESOURCES IN DISASTER MANAGEMENT


Appropriate Knowledge in disaster management
The word 'appropriate' refers to apt or  suitable. and therefore, the phrase 'appropriate knowledge' refers to knowledge that is regarding any particular subject. In the context of disaster management, 'appropriate knowledge' refers to knowledge of importance that will help in understanding the causes of the event, techniques to prevent recurrence of such disastrous events and most importantly knowledge to save lives of the people needing help. Appropriate knowledge in the context of disaster management encompasses  knowledge regarding the local conditions, history of disastrous events in the past and the techniques employed to survive them. Appropriate knowledge can vary depending on the disaster. In case of earthquakes, volcanoes, tsunamis and landslides the expertise of a geologist will prove invaluable.The knowledge of a meteorologist is extermly valuable to predict storms and cyclones. Knowledge of a hydrologist, agricultural scientist and a meteorologist can help predict the occurrence of a drought or famine. Hence, different types of disasters require the expertise of different specialists. For a field as broad and unpredictable as disaster management, there might be a requirement of an expert from any field. This emphasizes the need for appropriate knowledge in order to tackle any disaster

Local resources in disaster management
Disasters always occur at the local level. The local government maintains control over all assets used in response and recovery efforts.
  • People from the local community for the local resources when a disaster strikes
  • Local people from the community act as the first primary provider of emergency response service
  • Local people activate the Emergency Operations Center (EOC) and comprehensive emergency management plan
  • Local resources coordinate the response with public and private organizations and agencies
  • The local resources notify the state emergency management agency of the situation by regularly submitting situation reports
  • The local resources activate necessary local governments and organizations that are signatories to mutual aid contracts
  • The local resources can request the state to provide assistance

Disaster management act and policy


DISASTER MANAGEMENT ACT & POLICY

Disaster management act
  • The  Disaster Management act came into effect on 23rd December 2005 and it applies to the whole of India.
  • For the purpose of disaster management, the centre shall set-up a body called the National Disaster Management Authority (NDMA) with the Prime Minister of India holding the position of chairperson, exofficio
  • The Chairperson shall nominate a maximum of nine members to the NDMA and designate one of the nine members as the vice-chairperson
  • The members shall meet as necessary as deemed by the chairperson of the NDMA
  • The NDMA is responsible for laying down policies, plans and guidelines for disaster management to ensure timely and effective response to a disaster
  • The NDMA can recommend provision of funds for disaster mitigation
  • SDMA at the state level is headed by the chief minister
  • State Executive Committee (SEC) headed by the chief secretary coordinates and monitors implementation of National Policy, National Plan and State Plan
  • District Disaster Management Authority (DDMA) is headed by the District Majistrate
  • National Disaster Response Force (NDRF) and National Institute of Disaster Management (NIDM) are supporting institutions for disaster management efforts
  • The disaster management act represents a paradigm shift from a response centric approach to a holistic and integrated approach towards disaster management
  • The DM act is backed by institutional framework and legal authority
  • It has the power to create response fund and mitigation fund at national, state and district levels
  • The Disaster Management act lays down policies and guidelines
  • It coordinates enforcement and implementation of disaster policy and plans
  • The DM act lays down broad guidelines and policies for functioning of the NIDM
  • The DM act exercises general superintendence, direction and control of National Disaster Response Force (NDRF)
  • The vision of the DM act is to build a safe and disaster resilient India by developing a holistic, proactive, multi-disaster and technology driven strategy through a culture of prevention, mitigation, preparedness and efficient response
Disaster management policy


The objectives of the disaster management policy are:
  • Promoting a culture of prevention, preparedness and mitigation
  • Establishing institutional and techno-legal frameworks
  • Mainstreaming disaster management into the developmental planning process
  • Developing contemporary forecasting and early warning systems
  • Ensuring sufficient response and relief through dedicated decision support system
  • Undertaking reconstruction to build resilient communities

Plans, programs and legislation for DM

PLANS, PROGRAMS AND LEGISLATION RELATED TO DISASTER MANAGEMENT

Plans related to disaster management: The National Disaster Management Plan (NDMP) has been formulated with the aim to make India disaster resilient and reduce the loss of lives and assets. The plan is based on priority themes of the Sendai framework. They are:
    1. Understanding disaster risk
    2. Improving disaster risk governance
    3. Investing in disaster reduction (through structural and non-structural measures) and disaster preparedness
    4. Disaster preparedness and rebuilding a resilient community in the aftermath of a disaster
The NDMP covers all phases of disaster management i.e, prevention, mitigation, response and recovery. For each hazard, the NDMP incorporates four priorities listed in the Sendai framework for disaster risk reduction under the five thematic areas for action:
  1. Understanding risk
  2. Inter-Agency coordination
  3. Investing in structural measures for Disaster Risk Reduction (DRR)
  4.  Investing in non-structural measures for Disaster Risk Reduction (DRR) and
  5.  Capacity development
The response part has eighteen activities as listed below:
  1. Early warning, maps, satellite inputs and information dissemination
  2. Evacuation of people and animals
  3. Search and rescue of people and animals
  4. Medical care
  5. Drinking water, Dewatering pumps, Sanitation facilities, Public health
  6. Food and essential supplies
  7. Communication
  8. Housing and temporary shelters
  9. Power
  10. Fuel
  11. Transportation
  12. Relief logistics and supply chain management
  13. Disposal of animal caracasses
  14. Fodder for live stock in scarcity hit areas
  15. Rehabilitation and ensuring safety of live-stock and other animals, veterinary care
  16. Data collection and management
  17. Relief management
  18. Media relations
The plan consists of a chapter on strengthening disaster risk governance. The six thematic areas in which the central and state governments have to take action in this context are:
  1. Mainstream and integrate Disaster Risk Reduction (DRR) and institutional strengthening
  2. Capacity development
  3. Promote participatory approach
  4. Work with elected representatives
  5. Grievance Redress Mechanism
  6. Promote quality standards, certifications and awards for Disaster Risk Management
  • The NDMP incorporates horizontal and vertical integration among all the agencies and departments of the  Government. The plan also specifies the roles and responsibilities of all levels of government up to panchayat and urban local body level. The plan has a regional approach that is beneficial not only for disaster management but also for development planning
  • The plan is designed in such a way that it can be implemented in a scalable manner in all phases of disaster management.
  • Major activities such as early warning, information dissemination, medical care, fuel, transportation, search and rescue, evacuation, etc are allotted to disaster managers in the form of a check-list
  • The NDMP provides a general framework for recovery and offers flexibility to assess a situation and act accordingly
  • The NDMP prepares communities to cope with disasters emphasizing the need for  information, education and communication activities
Programs related to disaster management
The National Disaster Management Authority (NDMA) hosts several programs for mitigation and responsiveness for specific situations. A few of the programs include:
  1. National Cyclone Risk Management Project
  2. School Safety Project
  3. Decision Support System
  4. Scheme for training of community volunteers for disaster response in thirty most flood prone districts in India
  5. Sustainable reduction in disaster risk in ten multi-hazard prone districts in five states of India
  6. Capacity building on disaster management for IAS and central service officers at Lal Bahadur Shastri National Academy of Administration (LBSNAA), Mussoorie
Legislation for disaster management
Laws and regulations serve as a foundation for building community resilience. The Hyogo Framework for Action (HFA) highlighted the importance of good legislation for effective disaster management. The Sendai framework adopted in 2015 insists for a renewed focus on reviewing and strengthening legal frameworks.International organizations have conducted a research and comparative study on disaster management in various countries.

Tuesday, 23 April 2019

Relevance of indigenous knowledge

RELEVANCE OF INDIGENOUS KNOWLEDGE

According to the United Nations Educational, Scientific and Cultural Organization (UNESCO), indigenous knowledge refers to the understandings, skills and philosophies developed by societies with long histories of interaction with their natural surroundings. This knowledge (indigenous), influences the decision-making of day-to-day life for the local people.

Indigenous knowledge is essentially a complex mixture of:
-language 
-systems of classification 
-resource use practices
-interactions rituals and 
-spirituality

Indigenous knowledge is a unique way of gaining information about important facets of world's cultural diversity and is an important source of locally-appropriate sustainable development.

Indigenous knowledge has proved to be of significance in reducing risk from disasters caused by natural phenomena like earthquake, cyclone, droughts, landslide, tsunami etc. Indigenous knowledge is culture specific and represents people's lifestyle.

Local communities use indigenous knowledge to reduce risk, cope and survive natural disasters. Indigenous knowledge refers to methods and practices developed by a group of people who have an advanced knowledge of the local environment that has accumulated from several generations of habitations. The important characteristics of this type of knowledge that distinguish it from other types of knowledge is that it originates within the community, has as non-formal means of dissemination, is collectively owned, is developed over several generations and is subjected to adaptation. It is embedded in the community's way of life as a means of survival.

A few examples of the use of indigenous knowledge to manage or mitigate the effects of disasters are listed below:
  • Indigenous construction practices for earthquake safe housing in Kashmir known as "Taq" and "Dhajji Dewari" have earthquake resistant qualities
  • Bamboo plantation along canal bunds by villagers in Assam has protected embankments, bridges and roads from damage during heavy rains
  • The rich collection of indigenous knowledge uses local resources is cost efficient in the case of locals of Philippines who use it to master the damages by seasonal typhoons
  • The traditional and indigenous knowledge of the people of Sri Lanka helped the people build a village tank cascade system for drought mitigation and rural-well being in the drought-prone Purana villages of Sri Lanka
  • Indigenous knowledge (Mokken knowledge) helped several people survive the killer Tsunami of 2007 in Thailand
  • Indigenous knowledge for weather forecasting is extensively used in the drought prone areas of Vietnam. In this case, farmers use moon observations and observe the habits of insects to cultivate crops. This indigenous knowledge is passed on through thousands of years from generation to generation by the community
  • The 'Karez' technology is used in China to combat droughts. This is an indigenous knowledge in Xinjiang area of China that makes use of underground water efficiently. It takes advantage of topography for gravity irrigation and is still in use. This indigenous technology can be used in the face of a severe drought disaster.

Hailstorms

 Hailstorms When the water droplets that were about to fall as rain pass through very cold layers of the atmosphere. This will freeze the wa...