Hydrometeorological Hazards PDF

Summary

This document provides an overview of hydrometeorological hazards, with a particular focus on coastal processes and typhoons. It discusses the different categories of typhoons, their effects, and mitigation strategies, along with details on other weather events and their impact.

Full Transcript

Hydrometeorological and
Coastal Processes and
Hazards
BIG IDEA:
Hydrometeorological phenomena cause hazards and may
accelerate coastal processes. The hazards may be mitigated
through government and private or personal initiative.
 Coastal Processes and
Hazards

The Philippines has a total
of 7,641 islands and has one
of the longest coastlines in
the world, approximately
36,289 km.
 Coastal Processes
1. Erosion
2. Submersion
3. Salt intrusion
TYPHOON
 WHAT IS TYPHOON?
Tropical Cyclones that develops in the
north-western part of the Pacific
Ocean.
In the Philippines, tropical cyclones
(typhoons) are called bagyo.
The term bagyo, a Filipino word
meaning typhoon arose after a 1911
storm in the city of Baguio had a
record rainfall of 46 inches within a
24-hour period.
 WHAT IS TYPHOON, HURRICANE
AND TROPICAL CYCLONE?
The terms "hurricane" and "typhoon"
are regionally specific names for a
strong "tropical cyclone".
A tropical cyclone is the generic term
for a non-frontal synoptic scale
low-pressure system over tropical or
sub-tropical waters with organized
convection (i.e. thunderstorm
activity) and definite cyclonic surface
wind circulation
 WHAT IS TYPHOON, HURRICANE
AND TROPICAL CYCLONE?
If winds reach 33 m/s (64 km, 74 mph), then they are called:
"hurricane" (the North Atlantic Ocean, the Northeast Pacific
Ocean east of the dateline, or the South Pacific Ocean east of
160E)
"typhoon" (the Northwest Pacific Ocean west of the dateline)
"severe tropical cyclone" or "Category 3 cyclone" and
above (the Southwest Pacific Ocean west of 160°E or
Southeast Indian Ocean east of 90°E)
"very severe cyclonic storm" (the North Indian Ocean)
"tropical cyclone" (the Southwest Indian Ocean)
CATEGORIES OF TYPHOON
 CATEGORIES OF TYPHOON

CATEGORY 1
TROPICAL DEPRESSION
SUSTAINS WINDS BETWEEN
119 AND 153 KM/HOUR
(KM/H). IT IS THE FIRST
NOTABLE STAGE IN THE
FORMATION OF A TYPHOON.
 CATEGORIES OF TYPHOON
CATEGORY 2
TROPICAL STORM (TS)
HAS WINDS BETWEEN 154
AND 177 KM/H. -A TROPICAL
STORM IS A SYSTEM OF
INTENSE THUNDERSTORMS
THAT PROGRESSIVELY
INTENSIFIES.
 CATEGORIES OF TYPHOON
CATEGORY 3
STRONG TYPHOON
A STRONG TYPHOON IS A
SYSTEM OF LOW PRESSURE
AND INTENSE WINDS
(BETWEEN 178 AND 209
KM/H).
(MAEMI-SOUTH KOREA)
 CATEGORIES OF TYPHOON
CATEGORY 4
INTENSE TYPHOON
AN INTENSE TYPHOON
SUSTAINS HIGH WINDS OF
210 TO 249 KM/H AND IS
CLASSIFIED AS A
CATEGORY-5 STORM, WHICH
CARRIES THE HIGHEST
ELEMENT OF RISK.
 CATEGORIES OF TYPHOON

CATEGORY 5
VIOLENT TYPHOON
A VIOLENT TYPHOON
IS CHARACTERIZED BY
WINDS EXCEEDING
249 KM/H.
(TYPHOON HAIYAN)
 7300

1901
1593
1359 1410 1268

30+
LIST OF PHILIPPINE HISTORICAL TYPHOON (1970-2011)
NAMES OF TYPHOONS MARKED
THE PHILIPPINE HISTORY
Milenyo (Xangsane) - 2006
Frank (Fengshen) - 2008
Ondoy (Ketsana) - 2009
Juan (Megi) - 2010
Bebeng (Aere) - 2011
Ambo (Mawar) - 2012
Yolanda (Haiyan) - 2013
Glenda (Rammasun) - 2014
Lando (Koppu) - 2015
Ompong (Mangkhut) - 2018
MONSOONS
 NORTHEAST
MONSOON (AMIHAN)
It is characterized by moderate temperatures,
little or no rainfall in the central and western
part of Luzon and Visayas, and a prevailing
wind from the east. On the east coast of
Luzon it brings drizzling rainfall and squalls.
The effect on Mindanao relatively less than in
the northern part of the country.
As a rule of thumb, the Philippines' amihan
weather pattern begins sometime in
November or December and ends sometime in
May or June. There may, however, be wide
variations from year to year.
 SOUTHWEST
MONSOON (HABAGAT)
The Philippines' habagat weather pattern
begins sometime in June or July and ends
sometime in September or October.
The Philippines experiences the west or
southwest wind; south west monsoon. The
habagat season is characterized by hot and
humid weather, frequent heavy rainfall, and a
prevailing wind from the western parts.
STAGES OF TYPHOON
FOUR STAGES
OF TYPHOON
FORMATIVE STAGE
IMMATURE STAGE
MATURE STAGE
DECAYING STAGE
 FORMATIVE STAGE

The incipient stage when
the tropical cyclone form
in waves and in shear
lines of pre-existing
disturbances and winds
usually remain below the
typhoon force.
 IMMATURE STAGE
The deepening stage of the
cyclone during which it
continues to deepen until the
lowest central pressure and the
maximum wind intensity are
reached. However,
intensification does not usually
take place since some have
been known to die down even
though the winds has attained
typhoon force.
 MATURE STAGE
The stage of maturity of
the tropical cyclones where
the areas of circulation
expands while the surface
pressure no longer falls and
no increase in maximum
winds speed can be
observed which may last
for a week.
 DECAYING STAGE
The dissipating stage of the
tropical cyclone where the
surface pressure rises and the
area affected by the cyclones
diminishes in size as it recurves
or dissipate due to friction and
lack of moisture over continents
or when colder and drier air
enters through when they go
poleward.
STRUCTURE OF TYPHOON
 THE EYE
The hurricane's center is a
relatively calm, generally clear
area of sinking air and light
winds that usually do not
exceed 15 mph (24 km/h) and
is typically 20-40 miles (32-64
km) across. An eye will usually
develop when the maximum
sustained wind speeds go above
74 mph (119 km/h) and is the
calmest part of the storm
 THE EYEWALL
Where the strong wind gets as
close as it can is the eyewall. The
eyewall consists of a ring of tall
thunderstorms that produce
heavy rains and usually the
strongest winds. Changes in the
structure of the eye and eyewall
can cause changes in the wind
speed, which is an indicator of the
storm intensity. The eye can grow
or shrink in size, and double
(concentric) eyewalls can form.
 RAINBANDS
Curved bands of clouds and
thunderstorms that trail away
from the eye wall in a spiral
fashion. These bands are
capable of producing heavy
bursts of rain and wind, as
well as tornadoes. There are
sometimes gaps in between
spiral rainbands where no rain
or wind is found.
EFFECTS OF TYPHOONS

Strong wind
Tornadoes
Rainfall
Flood
Possible Storm surge
TYPHOON MITIGATION
 TYPHOON MITIGATION
ACTIONS BEFORE: Increase Knowledge, Determine Risk, Safeguard, Plan
General All-Hazard Actions:
Determine the disaster risks in your locale and the hazards that
accompany them.
Increase your knowledge about the emergency warning signals and
alert notifications used in your community.
Instruct family members how to shut off water, gas and electricity to
your house.
Make the necessary property preparations to reduce the damage from
the hazard.
Acquire a backup generator in case of a prolonged power failure.
Check into insurance (property, health, life, and hazard type).
Make the necessary financial arrangements in case of a sudden
evacuation and power outage that shuts down local ATMs and banks.
 TYPHOON MITIGATION
Organize important documents and records and store them in a portable
lock box or safe-deposit box.
Perform home inventory videotaping and store tape in a portable lock
box or safe-deposit box.
Develop an Emergency Communication Plan with evacuation plan and
ask an out-of-state person to serve as the "family contact".
Assemble a shelter-in-place Emergency Supplies Kit.
Assemble a mobile Emergency Supplies Kit that can serve as a “grab and
go” bag.
Get a family member trained in first aid and CPR.
Make the necessary preparations and arrangements for pets, seniors,
and the disabled.
Familiarize yourself with the emergency plans of your family member's
employment building, school, day care center, or nursing home.
 TYPHOON MITIGATION
Hazard Specific Actions:
Know the duration of the hurricane season. It starts on
June 1 and runs through November 30.
Check flashlights and radios. Make sure you have
batteries.
Check trees and shrubbery, and remove limbs that
could damage your house or utility lines.
Plan an evacuation route and learn safe routes inland.
Make arrangements for family pets because some
emergency shelters may not allow pets.
 TYPHOON MITIGATION
ACTIONS DURING: Safety Basics, Evacuation, Shelter in Place
Hurricane Watch (conditions within 24-36 hours):
Listen to battery-operated radio for progress reports; check
emergency supplies.
Fuel car.
Bring in outdoor objects.
Secure buildings by closing and boarding up windows.
Remove outside antennas.
Turn refrigerator and freezer to coldest settings.
Store drinking water in clean bathtubs, jugs, and bottles.
Moor boat securely or move to a designated safe place;
anchor trailer to ground.
Review evacuation plan.
 TYPHOON MITIGATION
Hurricane Warning (conditions expected in 24 hours or less):
Listen to radio for instructions.
Tie down mobile home and evacuate immediately.
Store valuables in waterproof container
Avoid elevators.
If at home:
Stay inside, away from anything glass.
Keep a supply of batteries and flashlights.
Avoid open flames as a source of light.
If power is lost, turn off major appliances to reduce power surge.
If evacuation is necessary: leave ASAP, avoiding flooded roads and
washed-out bridges.
Secure home by unplugging appliances and turning off electricity and the
main water valve.
If time permits, elevate furniture to protect it from flooding.
Bring pre-assembled emergency supplies and warm clothing.
Take blankets and sleeping bags to a shelter and leave immediately.
 TYPHOON MITIGATION
ACTIONS AFTER: Get Disaster Relief, Clean-up, Salvage
Stay tuned to radio for information, returning home only when
authorities advise it is safe to do so.
Help injured or trapped persons and give first aid where
appropriate.
Avoid loose or dangling power lines and report them to the power
company or fire department.
Beware of snakes, insects, and animals driven to higher ground
by flood water.
Open windows and doors to ventilate and dry your home.
Check refrigerated foods for spoilage.
Take pictures of the damage for insurance claims.
Drive only if necessary and avoid flooded roads and washed-out
bridges.
Use telephones only for emergency calls.
DESTRUCTIVE
WAVES
DESTRUCTIVE WAVES

TSUNAMI
TIDAL WAVES
STORM SURGE
TSUNAMI
 TSUNAMI
These awe-inspiring waves
are typically caused by large,
undersea earthquakes at
tectonic plate boundaries.
When the ocean floor at a
plate boundary rises or falls
suddenly, it displaces the
water above it and launches
the rolling waves that will
become a tsunami.
 TSUNAMI
Most tsunamis
–about 80
percent–happen
within the Pacific
Ocean’s “Ring of
Fire,” a
geologically
active area
where tectonic
shifts make
volcanoes and
earthquakes
common.
SIGNS OF TSUNAMI
 SIGNS OF TSUNAMI
Severe ground shaking from
local earthquakes may cause
tsunamis.
As a tsunami approaches
shoreline, water may recede
from the coast, exposing the
ocean floor, reefs and fish.
Abnormal ocean activity, a
wall of water, and an
approaching tsunami create a
loud "roaring" sound similar
to that of a train or jet
aircraft.
 WARNING SIGNS OF TSUNAMI
An earthquake is a natural tsunami warning. If you feel a
strong quake do not stay in a place where you are exposed to
a tsunami. If you hear of an earthquake be aware of the
possibility of a tsunami and listen to the radio or television for
additional information. Remember that an earthquake can
trigger killer waves thousands of miles across the ocean
many hours after the event generated a tsunami.
Witnesses have reported that an approaching tsunami is
sometimes preceded by a noticeable fall or rise in the water
level. If you see the ocean receding unusually rapidly or far
it's a good sign that a big wave is on its way. Go to high
ground immediately.
 WARNING SIGNS OF TSUNAMI
Many people were killed by the Indian Ocean tsunami
because they went down to the beach to view the retreating
ocean exposing the seafloor. Experts believe that a receding
ocean may give people as much as five minutes' warning to
evacuate the area.
Remember that a tsunami is a series of waves and that the
first wave may not be the most dangerous. The danger from
a tsunami can last for several hours after the arrival of the
first wave. A tsunami wave train may come as a series of
surges that are five minutes to an hour apart. The cycle may
be marked by a repeated retreat and advance of the ocean.
Stay out of danger until you hear it is safe.
TIDAL WAVE
 TIDAL WAVE

A tidal wave is a shallow
water wave caused by the
gravitational interactions
between the Sun, Moon,
and Earth on the ocean
STORM SURGE
 STORM SURGE
Storm surge is the abnormal
rise in seawater level during a
storm, measured as the height of
the water above the normal
predicted astronomical tide. The
surge is caused primarily by a
storm’s winds pushing water
onshore. The amplitude of the
storm surge at any given location
depends on the orientation of the
coast line with the storm track;
the intensity, size, and speed of
the storm; and the local
bathymetry.
CAUSES OF STORM SURGE
 CAUSES OF STORM SURGE
The wind circulation around the eye of a hurricane
The hurricane reaches shallow waters near the
coast, the vertical circulation in the ocean
becomes disrupted by the ocean bottom.
Storm surge occurs where winds are blowing
onshore. The highest surge tends to occur near
the “radius of maximum winds,” or where the
strongest winds of the hurricane occur.
WATER COMPOSITION OF TOTAL
WATER LEVEL
WATER COMPOSITION OF TOTAL
WATER LEVEL
Tides - When the tide is combined with the storm
surge, it is called the storm tide.
Waves - Breaking waves contribute to the water
level rise through wave runup and wave setup.
Wave runup occurs when a wave breaks and the
water is propelled onto the beach.
Freshwater - Input Heavy rainfall ahead of a
hurricane can cause river levels to rise well inland
from the coast. Once all this water flows downriver
and reaches the coast, local water levels especially
near deltas and in bays will rise.
 TOTAL WATER LEVEL
= STORM SURGE + TIDES + WAVES + FRESHWATER
STORM SURGE MITIGATION
 STORM SURGE MITIGATION
Tide Station - measure the variation in water level along the coast.
Since tidal cycles are predictable, storm surge can be calculated by
subtracting what the water level would have been in the absence of
the storm from the measured water level.
Pros:
Available in real time
Generally located in areas sheltered from waves and are able to measure “still
water”
Traditionally the most reliable way of measuring surge

Cons:
Limited number of stations along the coast, so there is often no real-time
validation of storm surge in the most vulnerable areas
Often fail at the height of an event due to loss of electrical power or damage
STORM SURGE MITIGATION
 STORM SURGE MITIGATION
High water marks - are lines found on trees and structures marking the
highest elevation of the water surface for a flood event, created by foam,
seeds, or other debris. Survey crews are deployed after a storm to locate
and record reliable high-water marks, usually through GPS methods.
Pros:
Traditionally the best method for capturing the highest surge from an event

Cons:
Are not available in real time
Are perishable, so surveys need to be conducted as soon as possible after a storm
Can be subjective
Generally, include the effects of wave runup and setup, and only a small
percentage represent “still water”
STORM SURGE MITIGATION
 STORM SURGE MITIGATION
Pressure sensors - from the Geological Survey are temporary
barometric pressure sensors that provide information about storm
surge duration, times of arrival and retreat, and maximum depths. The
sensors are installed around posts and other structures before the
arrival of a hurricane.
Pros:
Are able to provide timing information that cannot be obtained from high water
marks
Can be deployed ahead of a storm at the locations of the highest expected surge
Cons:
Information from the sensors is not available in real time
Can include the effects of waves, which will provide an overestimation of the
storm surge height
May be difficult to recover the instruments after a storm
STORM SURGE MITIGATION
FLOOD
 FLOOD
Flooding is an overflowing of water onto land that is
normally dry. Floods can happen during heavy rains, when
ocean waves come on shore, when snow melts too fast, or
when dams or levees break.
Flooding may happen with only a few inches of water, or it
may cover a house to the rooftop.
They can occur quickly or over a long period and may last
days, weeks, or longer.
Floods are the most common and widespread of all
weather-related natural disasters.
 FLASH FLOOD
Flash floods are the most dangerous kind of floods,
because they combine the destructive power of a
flood with incredible speed and unpredictability.

Flash floods occur when excessive water fills
normally dry creeks or river beds along with
currently flowing creeks and rivers, causing rapid
rises of water in a short amount of time. They can
happen with little or no warning.
 ALERT IN IDENTIFYING FLOOD
FLOOD WATCH: Flash flooding or flooding is possible
within the designated watch area - be alert.
FLASH FLOOD or FLOOD WARNING: Flash flooding or
flooding has been reported or is imminent - take
necessary precautions at once! Get to higher ground!
URBAN and SMALL STREAM ADVISORY: Flooding of
small streams, streets and low-lying areas, such as
railroad underpasses and urban storm drains is occurring.
FLASH FLOOD or FLOOD STATEMENT: Follow-up
information regarding a flash flood/flood event.
 TYPES OF FLOOD
RIVER FLOOD - occurs
when water levels rise
over the top of river banks
due to excessive rain from
tropical systems making
landfall, persistent
thunderstorms over the
same area for extended
periods of time, combined
rainfall and snowmelt, or
an ice jam.
 TYPES OF FLOOD

COASTAL FLOOD - the
inundation of land areas
along the coast, is caused
by higher than average
high tide and worsened by
heavy rainfall and onshore
winds (i.e., wind blowing
landward from the ocean).
 TYPES OF FLOOD

INLAND FLOODING -
occurs when moderate
precipitation accumulates
over several days, intense
precipitation falls over a
short period, or a river
overflows because of an
ice or debris jam or dam
or levee failure.
 TYPES OF FLOOD
FLASH FLOOD - is caused
by heavy or excessive
rainfall in a short period of
time, generally less than six
hours. Flash floods are
usually characterized by
raging torrents after heavy
rains that rip through river
beds, urban streets, or
mountain canyons sweeping
everything before them.
FLOOD MITIGATION
 FLOOD MITIGATION
There are steps that you can take to prepare yourself and
mitigate against damages.
1. The first thing you can do is know your risk, and we have
information on risk.
2. Next, you should create an emergency communications plan
and build an emergency kit to ensure you and your family are
prepared for a flood.
3. As part of having a plan, we also encourage you to consider
your coverage. A flood insurance policy can protect your
home, property, or business from the financial damages of
flooding. Most homeowner’s insurance does not cover damage
from flooding.
 FLOOD MITIGATION
In addition to these steps, there are also small flood proofing
measures that you can take to help prevent, or minimize the
impact of flooding to your home and its contents. A few examples
include:
Elevate your furnace, water heater and electric panel in your
home, if you live in a high flood risk area.
Install "check valves" to prevent flood water from backing up
into the drains of your home.
When practical, homeowners can construct barriers (such as
sandbagging) to stop flood water from entering your home.
Seal walls in your basement with waterproofing compounds.
TORNADO
 TORNADO / TWISTER
Tornadoes are vertical funnels of rapidly spinning
air. Their winds may top 250 miles (400 kilometers)
an hour and can clear a pathway a mile (1.6
kilometers) wide and 50 miles (80 kilometers) long.

Twisters are born in thunderstorms and are often
accompanied by hail. Giant, persistent thunderstorms
called supercells spawn the most destructive
tornadoes.
 TORNADO FACTS
A tornado forms when changes in wind speed and direction
create a horizontal spinning effect within a storm cell. This
effect is then tipped vertical by rising air moving up through
the thunderclouds.
The meteorological factors that drive tornadoes make them
more likely at some times than at others. They occur more
often in late afternoon, when thunderstorms are common, and
are more prevalent in spring and summer. However, tornadoes
can and do form at any time of the day and year.
Tornadoes' distinctive funnel clouds are actually transparent.
They become visible when water droplets pulled from a storm's
moist air condense or when dust and debris are taken up.
 CAUSE OF TORNADO
The most violent tornadoes come from
supercells, large thunderstorms that have
winds already in rotation. About one in a
thousand storms becomes a supercell,
and one in five or six supercells spawns
off a tornado.
Supercells are storms usually, but not
necessarily, thunderstorms that contain
updrafts that rotate about a vertical axis.
This rotation is derived from shear in the
environmental wind field (that is, a
change in wind direction and / or speed
with height) surrounding the storm as it
begins to grow.
CLASSIFICATION OF TORNADO
 CLASSIFICATION OF TORNADO
Multivortex (multiple-vortex)
tornadoes contain two or more
small, intense subvortices orbiting
the center of the larger tornado
circulation. These vortices may
form and die within a few seconds,
sometimes appearing to train
through the same part of the
tornado one after another. They
can happen in all sorts of tornado
sizes, from huge "wedge"
tornadoes to narrow "rope"
tornadoes.
 CLASSIFICATION OF TORNADO
Waterspout is a tornado over
water--usually meaning non-supercell
tornadoes over water.
Although waterspouts are always
tornadoes by definition; they don't
officially count in tornado records unless
they hit land. They are smaller and
weaker than the most intense Great
Plains tornadoes, but still can be quite
dangerous. Waterspouts can overturn
boats, damage larger ships, do significant
damage when hitting land, and kill
people.
 CLASSIFICATION OF TORNADO
Landspout is storm-chaser slang
for a non-supercell tornado.
So-called "landspouts" resemble
waterspouts in that way, and also
in their typically small size and
weakness compared to the most
intense tornadoes. But "landspouts"
are tornadoes by definition; and
they are capable of doing
significant damage and killing
people.
 CLASSIFICATION OF TORNADO
Gustnado is a small and usually weak
whirlwind which forms as an eddy in
thunderstorm outflows. They do not
connect with any cloud-base rotation
and are not tornadoes. But because
gustnadoes often have a spinning dust
cloud at ground level, they are
sometimes wrongly reported as
tornadoes. Gustnadoes can do minor
damage (e.g., break windows and tree
limbs, overturn trash cans and toss
lawn furniture), and should be avoided.
 CLASSIFICATION OF TORNADO
Dust devil is a small,
rapidly rotating wind
that is made visible by
the dust, dirt or debris
it picks up. Also called
a whirlwind, it
develops best on clear,
dry, hot afternoons.
TORNADO MITIGATION
 TORNADO MITIGATION
IF YOU ARE UNDER A TORNADO WARNING, FIND SAFE
SHELTER RIGHT AWAY
If you can safely get to a sturdy building, then do so
immediately.
Go to a safe room, basement, or storm cellar.
If you are in a building with no basement, then get to a
small interior room on the lowest level.
Stay away from windows, doors, and outside walls.
Do not get under an overpass or bridge. You’re safer in a
low, flat location.
Watch out for flying debris that can cause injury or death.
Use your arms to protect your head and neck.
 TORNADO MITIGATION
HOW TO STAY SAFE WHEN A TORNADO THREATENS
Prepare NOW
○ Know the signs of a tornado, including a rotating,
funnel-shaped cloud; an approaching cloud of debris;
or a loud roar—similar to a freight train.
○ Pay attention to weather reports. Meteorologists can
predict when conditions might be right for a tornado.
○ Identify and practice going to a safe shelter in the
event of high winds, such as a safe room built. The
next best protection is a small, interior, windowless
room on the lowest level of a sturdy building.
 TORNADO MITIGATION
Survive DURING
○ Immediately go to a safe location that you identified.
○ Take additional cover by shielding your head and neck
with your arms and putting materials such as furniture
and blankets around you.
○ Listen to Weather Radio, or local alerting systems for
current emergency information and instructions.
○ Do not try to outrun a tornado in a vehicle.
○ If you are in a car or outdoors and cannot get to a
building, cover your head and neck with your arms
and cover your body with a coat or blanket, if
possible.
 TORNADO MITIGATION
Be Safe AFTER
○ Keep listening to Weather Radio, and local authorities for
updated information.
○ If you are trapped, cover your mouth with a cloth or mask to
avoid breathing dust. Try to send a text, bang on a pipe or
wall, or use a whistle instead of shouting.
○ Stay clear of fallen power lines or broken utility lines.
○ Do not enter damaged buildings until you are told that they are
safe.
○ Save your phone calls for emergencies. Phone systems are
often down or busy after a disaster. Use text messaging or
social media to communicate with family and friends.
○ Be careful during clean-up. Wear thick-soled shoes, long pants,
and work gloves.
EL NIÑO & LA NIÑA
 EL NIÑO AND LA NIÑA

El Niño and La Niña are opposite phases of what is
known as the El Niño-Southern Oscillation (ENSO) cycle.

The ENSO cycle is a scientific term that describes the
fluctuations in temperature between the ocean and
atmosphere in the east-central Equatorial Pacific
(approximately between the International Date Line and
120 degrees West).
 EL NIÑO AND LA NIÑA
La Niña is sometimes referred to as the cold phase of ENSO
and El Niño as the warm phase of ENSO. These deviations
from normal surface temperatures can have large-scale
impacts not only on ocean processes, but also on global
weather and climate.

El Niño and La Niña episodes typically last nine to 12
months, but some prolonged events may last for years.
While their frequency can be quite irregular, El Niño and La
Niña events occur on average every two to seven years.
Typically, El Niño occurs more frequently than La Niña.
EFFECTS OF LA NIÑA
 EFFECTS OF LA NIÑA

Increased Rainfall
Catastrophic Floods
Drier Than Normal Conditions
Increased Commercial Fishing
Affects the Climate Patterns
Affects Weather Cycles
Economic Problems Around the Globe
EFFECTS OF LA NIÑA
EFFECTS OF EL NIÑO
EFFECTS OF EL NIÑO
EFFECTS OF EL NIÑO
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