Hydromet Reviewer (jojo).pdf

Transcript

0.4% water vapor
Reviewer: ABE 137 -jojo - The Argon (Ar): < 1%.
Greenhouse Effect & Global Carbon Dioxide (CO2): 0.036% but
crucial in regulating temperature.
Warming
Other trace gases include methane,
1. Structure of the Atmosphere nitrous oxide, and ozone.Ne, He, Kr,
H, O3
The atmosphere is multi-layered with
little chemical interaction. 3. The Greenhouse Effect
50% of the atmosphere's mass is
The Earth’s surface receives energy
within 6 km of the surface.
from the sun and the atmosphere.
Atmospheric Pressure Decreases
Greenhouse gases (GHGs) allow
With Height
shortwave radiation to pass through
Most of the energy is captured close
but trap longwave radiation, warming
to the surface, That energy drives
the Earth by around 33°C.
climate and weather
Thus the atmosphere stores
Layers of the atmosphere (from
energy
lowest to highest):
Without the greenhouse effect, the
○ Troposphere: Contains most
Earth would be much colder.
clouds and weather

phenomena.
○ Stratosphere: Contains the 4. Greenhouse Gases
ozone layer.
○ Mesosphere: Temperature CO2: Released from fossil fuel
decreases with height. burning and deforestation; increased
○ Thermosphere/Ionosphere: by 30%.
UV rays and cosmic rays Methane (CH4): Released from rice
affect this region. cultivation, livestock, and landfills;
○ Exosphere: The outermost increased by 145%.
layer where atmosphere Nitrous Oxide (N2O): Comes from
transitions into space. agriculture and industry; increased
by 15%.
2. Composition of the Atmosphere
What is the chemical structure of the 5. Global Warming
atmosphere?
Global Warming refers to the rise in
nitrogen by far the most common Earth's surface temperature due to
element the increase in greenhouse gases.
oxygen is second most common Enhanced Greenhouse Effect is
greenhouse gasses are small in the result of increased GHGs which
amount, but important! amplify the natural greenhouse
Nitrogen (N2): 78% of the effect, leading to global warming.
atmosphere.
Oxygen (O2): 20.6%. 6. Possible Causes of Global Warming
 Orbital Changes: Shifts in Earth's ○ Cumulus: Puffy clouds that
orbit can affect climate. resemble cotton or
Atmospheric Composition: cauliflower.
Changes in the concentration of ○ Stratus: Uniform light or dark
GHGs. grey clouds covering most of
Ocean Circulation: Alterations in the sky; fog is a type of
the transfer of heat in the oceans. stratus cloud.
Sunspot Activity: Changes in solar ○ Stratocumulus: Irregular
radiation. rolling or puffy clouds with
Reflectivity (Albedo): Changes in occasional gaps between
Earth's surface reflectivity, especially them.
due to ice and snow cover. ○ Nimbostratus: Dark grey
clouds at low to middle
Reviewer: ABE 137 - Cloud Types altitudes that produce
precipitation. The cloud base
Cloud Classification may be hard to see due to
rain.
Clouds are classified based on their altitude:
Special Cloud Type
1. High Altitude Clouds (Prefix:
"cirro-") Cumulonimbus: Large, towering
○ Cirrocumulus: High clouds clouds with dark bases, often
with a puffy, patchy accompanied by thunderstorms.
appearance, often forming They can have an anvil shape.
wave-like patterns.
○ Cirrostratus: Light grey or Reviewer: ABE 137 - Acid Rain and
white thin clouds covering Eutrophication
most of the sky, with the sun
or moon visible through 1. What is Acid Rain?
them.
○ Cirrus: Thin, wispy, and Acid rain refers to rain that has
feathery clouds made of ice been made acidic by pollutants in
crystals. the air, mainly sulfur dioxide (SO₂)
2. Medium Altitude Clouds (Prefix: and nitrogen oxides (NOₓ).
"alto-") It occurs when gases react with
○ Altocumulus: Puffy, patchy water, oxygen, and other chemicals
clouds with spaces between in the atmosphere to form acidic
them, usually found at compounds.
mid-level altitudes. Acid rain includes both wet
○ Altostratus: Light grey and deposition (rain, snow) and dry
uniform clouds that cover deposition (acid particles/gases
most of the sky. sticking to surfaces without
3. Low Altitude Clouds (Prefix: precipitation).
"strato-")
 Wet deposition 4. Effects of Acid Rain
Wet deposition refers to the process
by which acidic pollutants are Increases acidity of soils, affecting
removed from the atmosphere plant life.
through precipitation (such as rain, Acidifies rivers, lakes, and seas,
snow, fog, or sleet). destroying their chemical balance.
Dry deposition Erodes buildings and monuments
-deposition in the absence of made from limestone.
precipitation.
5. Eutrophication
Responsible for as much as 20 to
60% of total acid deposition. This Eutrophication is the increase in
occurs when particles and gases primary productivity in ecosystems
stick to the ground, plants or other due to an increase in nutrients
surfaces. (mainly nitrogen and phosphorus).
This process can occur on land or in
2. Chemical Reactions Leading to Acid water.
Rain It often leads to excessive plant
growth (e.g., algal blooms) and
hydrolyses decreases water quality.
-favors certain weedy species over
Sulfur dioxide (SO₂) reacts with others
water: Ecological Impacts:
SO₂ + H₂O ⇌ H⁺ + HSO₃⁻ ⇌ H⁺ + ○ Decreased biodiversity.
SO₃²⁻ ○ Changes in species
Nitrogen oxides (NO and NO₂) composition.
react with water to form nitric acid: ○ Toxicity effects and reduced
2 NO₂ + H₂O ⇌ HNO₂ + HNO₃ water quality.
2 NO + H₂O ⇌ 2 HNO₃
Reviewer: ABE 137: Atmospheric
Optical Phenomena
3. Causes of Acid Rain. Introduction to Atmospheric Optics
Human Activity: Burning of fossil
All atmospheric optical phenomena
fuels (oil, gas, coal) releases SO₂
occur when sunlight is obstructed.
and oil and petrol in motor vehicles
Sunlight can be scattered, reflected,
releases NOₓ.
refracted, diffracted, or absorbed,
Natural Causes:
leading to various optical
○ Emissions from volcanoes.
phenomena.
○ Biological processes on land,
Scattered
wetlands, and oceans (e.g.,
when it passes microscopic particles
dimethyl sulfide from
such as aerosol particles or even air
oceans).
molecules
 Reflected from the surface of larger diffraction by tiny water
particles such as raindrops and ice droplets in clouds.
crystals. ○ The smaller the droplets, the
Refracted (bent) gradually as it larger and more colorful the
travels through the atmosphere, or corona.
abruptly as it passes between water ○ Cloud Type and Coronas
and air. -Wave Clouds:produce the
Diffracted into a field of patterned most spectacular
waves as it skirts around tiny cloud coronas.because the
droplets. droplets in wave clouds are
Finally, it can be absorbed by almost uniform in size,
matter and extinguished. allowing the diffraction of
light
2. Key Atmospheric Optical Phenomena:
-Convective Clouds:
1. Rainbows Rarely produce beautiful
○ Occur when sunlight shines coronas ,-the size of water
on water droplets, producing droplets varies significantly,
a spectrum of light. which disrupts the formation
○ Primary rainbows have red of clear and vibrant corona
on the outer edge and violet patterns.
on the inner side.
○ Secondary rainbows are less 4. Glories or Brocken Specter
bright with reversed colors. ○ Circular rings around the
with the dark band observer’s shadow, seen on
(Alexander’s Band) clouds or fog.
between the bows. ○ Caused by diffraction of light
○ Often form when light is in small, uniformly sized
refracted, reflected, and water droplets.
dispersed through water 5. Auroras
droplets. ○ Bright displays in polar
○ Rainbows may also form in regions caused by the
mist, such as that of a interaction of solar particles
waterfall with Earth's magnetic field.
2. Halos ○ Aurora Borealis (Northern
○ Rings of light around the sun Lights)
or moon caused by reflection ○ Aurora Australis (Southern
or refraction of light through Lights).
ice crystals. 6. Mirages
○ Most common is the 22° ○ Optical illusions caused by
halo. the refraction of light in layers
3. Coronas of air with different
○ Small, colored rings around temperatures, creating
the sun or moon due to displaced images of distant
objects.
7. Crepuscular Rays ○ clouds in the winter polar
○ Sunlight rays streaming stratosphere at altitudes of
through gaps in clouds, 15,000–25,000 metres
appearing to radiate from a (50,000–80,000 ft).
single point. ○ Their effects on ozone
8. Green Flash depletion arise because they
○ A rare phenomenon seen support chemical reactions
just after sunset or right that produce active chlorine
before sunrise, caused by which catalyzes ozone
the refraction of sunlight destruction,
through the atmosphere. ○ they remove gaseous nitric
9. St. Elmo's Fire acid, perturbing nitrogen and
○ A bright glow appearing on chlorine cycles which
pointed objects during increases ozone destruction
thunderstorms, caused by 14. Lightning
ionization in the air. ○ Is an atmospheric discharge
10. Will-o’-the wisp or Jack o’ Lantern of electricity, which usually,
or Fool’s Fire but not always, occurs during
○ Refers to the ghostly lights rain storms, and frequently
sometimes seen at night or during volcanic eruptions or
twilight that hover over damp dust storms
ground in still air. It looks like ○ Cloud to cloud lightning
a flickering lamp, and is ○ Rocket lightning
sometimes said to recede if ○ Cloud to ground lightning
approached. ○ Volcanic-triggered lightning
11. Sundogs (Parhelia)/Mock Suns
○ Bright spots appearing on Reviewer: ABE 137: Meteorology
either side of the sun, caused and Climatology
by sunlight being refracted by
ice crystals in the 1. Meteorology and Climatology
atmosphere.
12. Noctilucent Cloud or Polar Meteorology: Study of the Earth's
Mesopheric Clouds atmosphere and atmospheric
○ bright cloudlike atmospheric processes.
phenomena visible in a deep
twilight. Branches of Meteorology
○ "night shining" in Latin -Dynamic Meteorology: study of winds and
○ observed in the summer weather patterns and the forces that
months at latitudes between produce them.
50° and 70° north and south -Physical Meteorology: use of radar and
of the equator satellites 1. and the study of the
13. Nacreous Clouds or Polar phenomeneon precipitations, pollution, etc.
Stratospheric Clouds -Synoptic Meteorology: study of
day-to-day weather ○ Earth's declination, rotation,
and revolution affect
radiation, land temperature,
Climatology: A branch of day length, and tides.
meteorology focusing on the ○ Solstice: Sun is farthest from
long-term atmospheric conditions the Earth.
averaged over time. ○ Equinox: Day and night are
equal as the sun is directly
2. Weather vs. Climate overhead.
2. Land and Water Masses:
Weather: Refers to short-term
○ Land heats and cools faster
atmospheric conditions (hours to
than water.
days), including temperature,
○ Oceans moderate
humidity, wind, and precipitation.
temperature changes due to
Climate: Describes long-term
their higher heat capacity
weather patterns in a region,
and deeper penetration of
generally averaged over decades.
sunlight.
3. Kinds of Climate 3. Surface Features of the Land
(Terrain):
1. Macroclimate: Covers large regions ○ Mountains, valleys, and other
of the Earth's surface (e.g., landforms influence local
continents). weather patterns, cloud
2. Mesoclimate: Refers to localized formation, and precipitation.
areas, such as valleys, basins, or ○ Temperature decreases
urban areas. 100C per 1,000 m increase
3. Microclimate: Pertains to small, in elevation.
localized zones, such as a garden or ○ Formation of clouds and
plant surroundings. precipitation in the windward
side of the mountain ranges.
4. Atmospheric Parameters 4. Wind Systems and Pressure
Belts:
Temperature ○ The global circulation of air,
Pressure influenced by high and
Air density low-pressure belts, drives the
Wind speed and direction development of wind patterns
Humidity and weather disturbances.
PV=nRT
1. Position of the earth

Insolation – incoming sunlight
5. Major Factors Affecting Terrestrial Albedo – fraction of the incident
Climate radiation that is reflected by an
object
1. Position of the Earth:
An average of 1/3 (34%) of the
isolation is reflected back,
 19% absorbed by the atmosphere 2. Land and water masses
and
47% absorbed by the earth’s -Land surfaces are heated or cooled by
surface. changes in radiation to much greater degree
Common albedo values: and more rapidly than ocean
snow = 0.81
clouds = 0.17-0.81 Radiation penetrates water more
forests = 0.03-0.10 than in soil,
dark dry sand = 0 – 0.18 Turbulence mixes heat through
the upper 100 m of the ocean
Water has greater heat capacity
than soil,.
Solstice and Equinox. Almost half the heat falling on
water is used in the evaporation
Solstice – the period when the sun
is farthest from the earth (δ=23.450 ) Monsoon
Equinox – sun’s position makes day
and night equal – arge-scale, seasonal version of the
- sun is directly above the observer diurnal sea/land breeze that occurs
(δ=0) along many coast, especially
Arabian Sea and Indian Ocean

6. Winds and Pressure Systems

Trade Winds (Tropical Easterlies):
Winds blowing from subtropical
highs to the equatorial lows.
Prevailing Westerlies: Winds
flowing from the subtropical highs
Spring Tide toward the poles.
Monsoon Winds: Seasonal winds
Stronger high and low tides
that change direction based on
During new and full moon
pressure gradients.
Moon’s pull is supplemented or
Jet Stream: High-speed air currents
offset by sun’s gravity.
found in the upper atmosphere.
Neap Tide
7. Clouds and Precipitation
Smaller high and low tides
Cumulus Clouds: Fair-weather
Moon is in the 1st and 3 rd quarter
clouds resembling fluffy cotton.
(forms 900with the sun)
-They may change to nimbo-stratus
Moon’s pull is stronger but the sun’s
if wind is blowing from NE to S.
gravity lessens it
 Stratus Clouds: Low, featureless Trade Winds (Tropical Easterlies)
clouds that can create fog when -blow from the horse latitudes
touching the ground. (30°-35° N and S) toward the
Cirrus Clouds: Wispy clouds made doldrums near the equator.
of ice crystals. ‘Mare’s tail’. -Average speed: 10-16 knots
Nimbus Clouds: Rain-producing -strongest over the Atlantic and
clouds, including Pacific Oceans, where they are less
Cumulonimbus, which are affected by continental pressure
responsible for thunderstorms. variations.
Prevailing Westerlies - Wind
Wind system and pressure belts (general system from the subtropical high
circulation of the atmosphere) pressure belt directed poleward,
southwesterly or westerly due to the
Coriolis Effect - additional force or Coriolis Effect.
acceleration acting on the motion of bodies Monsoon Winds - Winds whose
in a rotating system of reference direction reverses with the season,
requiring a reversal of the pressure
Planetary Pressure Belts
gradient.
The Equatorial Calms Jet Stream - Narrow, fast-moving air
(Doldrums)-a belt of low pressure (50-300 mph.)currents in the upper
surrounding the earth in the atmosphere, flowing from west to
equatorial zone (10o N and 10o S) east.
Belts of Subtropical Calms (Horse -Found at altitudes above 10,000
Latitudes) – Characterized by very feet, between 30° to 60° latitude.
light winds or calms but high Subtropical Jet Stream: Located
pressure (also called subtropical around 30° latitude.
highs) (30o ~ 35o N and S) Polar Front Jet Stream: Found
Sub-Polar Low Pressure Belts - around 60° latitude.
Characterized by low pressure, Gulf Stream - A powerful and
stormy, variable winds associated enormous ocean current that flows
with traveling cyclone (50o ~ 55o N up the eastern edge of North
and S) America and branching into two
Polar High Pressure Belts - High separate streams toward
pressure areas over both polar Scandinavia and Southern Europe.
regions with intensities and location It develops when the sun heats the
of centers known to shift nod rarely earth unevenly, giving more warmth
on the center of the geographic at the equator than at the poles. As
poles. the warmer wind moves toward the
poles, it creates prevailing winds that
Intertropical Convergence Zone (ITCZ) - can affect ocean movement.
Low pressure area around equator where
prevailing winds are calm. 8. Fronts and Cyclones

Planetary Wind Systems:
Fronts - are air-mass boundaries that lie november to april wet during the
along line of low pressure rest of the year
Type IV - rainfall Is more or less
Cold Front: Cold air advances, evenly distributed through the
causing warm air to retreat. year
Warm Front: Warm air advances,
pushing cold air away. Cyclone/Typhoon/Hurricane - storm in a
Occluded Front: A mix of warm and region of low surface pressures
cold fronts.
Stationary Front- temporarily fixed Development of Tropical Cyclone:
boundary between polar and tropical
air masses Tropical Disturbance
Tropical Cyclones (Typhoons, Tropical Depression – 38-62 kph
Hurricanes, Cyclones): Tropical Storm – 63-87 kph
○ Large, rotating storms with Severe Tropical storm – 88-120
strong winds and heavy rain. kph
○ Develop from tropical Tropical cyclone/typhoons – winds
disturbances and can velocity 121-240 kph
escalate to typhoons or - are large rotating storms ranging
hurricanes with wind speeds from 100-1,600 km in diameter and
up to 240 kph. accompanied by violent, destructive
winds, heavy rains, and high tide
Philippine Climate is based on the Supertyphoon – sustained winds of
Modified Coronas Classification at least 240 kph

based on amount, distribution and Eye of the Typhoon:
patterns of rainfall and humidity -
essentially two distinct seasons: Dry Lowest barometric pressure (15%
and Wet less than pressure outside the
Dry month: ˂ 50 mm rainfall : ˂ 100 storm)
mm rainfall after 3 or more surrounded by a ring of towering
succeeding dry months of ˂ 50 mm thunderstorm eyewall – most severe
weather condition
TYPES 30~65 km φ

Type I - Two Pronounced Storm Surge: A rise in ocean levels due to
Seasons- Dry (November- April) strong winds from tropical storms or
Wet( the rest of the year) hurricanes, often causing coastal flooding.
Type II - No Dry season with a
very pronounced rainfall from Landfall - is when a hurricane reaches the
november t april and wet during coast and begins to travel over land after
the rest being over water.
Type III - Seasons are not very *A tropical cyclone is classified as making
Pronounced, Relatively dry from landfall when the center of the storm moves
across the coast; in strong tropical cyclones Additional Warnings:
this is when the eye moves over land.
Storm Surge: Coastal flooding risk
Direct hit- A direct hit is where the core of Heavy Rainfall: Flash floods and
high winds (or eyewall) comes onshore but landslides warning
the center of the storm may stay offshore.

Color Coded Rainfall Advisories
PAGASA Revised Tropical Cyclone Wind
Signals (TCWS) Yellow Warning:
○ Rainfall: 7.5-15 mm in 1 hour
Signal No. 1: ○ Impact: Possible flooding in
low-lying areas
Winds: 30-60 km/h ○ Action: Monitor weather
Light damage to structures and updates, prepare for
crops evacuation
Lead Time: 24 hours Orange Warning:
○ Rainfall: 15-30 mm in 1 hour
Signal No. 2: ○ Impact: Flooding is
threatening, especially in
Winds: 61-120 km/h
flood-prone areas
Moderate damage to light structures
○ Action: Be alert, prepare for
Lead Time: 24 hours
evacuation
Signal No. 3: Red Warning:
○ Rainfall: More than 30 mm in
Winds: 121-170 km/h 1 hour
Heavy damage to structures, ○ Impact: Severe flooding
moderate damage to crops expected, dangerous
Lead Time: 18 hours conditions
○ Action: Evacuate
Signal No. 4: immediately

Winds: 171-220 km/h STORM SURGE WARNING
Severe damage to high-risk
structures Green- No Threat
Lead Time: 12 hours Yellow - 0.5 - 1 meter
Orange - 1- 3 meters
Signal No. 5: Red - Greater than 3 meters

Winds: Over 220 km/h
Catastrophic damage, total
destruction
Lead Time: 12 hours or less
 The new names will be allotted to
developing tropical storms by the Tokyo
Typhoon Centre of the Japanese
Meteorological Agency which is the RSMC
for the basin.

THE NORTHWEST PACIFIC & SOUTH
Reviewer: ABE 137: Meteorology CHINA SEA TROPICAL CYCLONE
and Climatology 2 NAMES

1. Naming of Typhoons in the Philippines 1945: the military weather forecasters (U.S.
Navy and U.S. Air Force)
In 1963, PAGASA started naming
typhoons with Filipino women’s * The names utilized were almost
names ending in "ng". exclusively English feminine names through
In 1997, the Senate (led by Sen. 1978
Ernesto Herrera) questioned
1979 men's names were used with
PAG-ASA about the use of females
women's names in an alternating fashion
names for typhoons
In 1999, PAGASA launched the
“Name a Bagyo” Contest, resulting
in new names that reflect Filipino 2. Typhoon Categories (by PAGASA)
culture.
*The new names was adapted in Tropical Depression: Winds less
2000. than 61 km/h.
A typhoon's name is Tropical Storm: Winds of 62-88
decommissioned if it causes: km/h.
○ At least 300 deaths. Severe Tropical Storm: Winds of
○ At least PHP 1 billion in 89-117 km/h.
damages. Typhoon: Winds of 118-220 km/h.
○ Association with a public Super Typhoon: Winds over 220
figure that could lead to km/h.
ridicule.
3. Retired Typhoon Names
On 1 January 2000, tropical cyclones in
the Northwest Pacific basin are named Typhoons that cause significant
from a new and very different list of deaths and damages have their
names. names retired. For example:
○ Yolanda (Haiyan): One of
The new names are Asian names and were the most destructive
contributed by all the nations and territories typhoons, retired after
that are members of the WMO's Typhoon causing PHP 89.6 billion in
Committee. damages and 6,300 deaths.
4. Weather Disturbances El Niño:
○ Occurs when warm ocean
Tornadoes: Violent winds caused by conditions appear along the
updrafts and downdrafts during western coast of South
storms. America.
-top speed of 110 kph near the ○ Disrupts trade winds and
ground and stay about 10 minutes alters global weather
Super cells- a super cell has only patterns.
one updraft and only one downdraft. ○ El Niño Southern
This way the super cell allows itself Oscillation, or ENSO.
to feed off itself, giving it a long and
intense life Humboldt Current is a cold ocean cuurent
which flows north along the coast of Chile
Mesocyclone- When the and Central Pacific.
combination of wind speeds and
changing directions in a super cell is La Niña:
right the air will rotate, causing a ○ Marked by unusually cold
mesocyclone to form. ocean temperatures in the
equatorial Pacific.
Thunderstorms: Form when moist, ○ Strong trade winds increase
unstable air is lifted into the rainfall and shift warm water
atmosphere, leading to westward
condensation and heat release.
The strong trade winds propagates cold
Causes: waters to the west via the Rossby Waves

○ unequal warming of the
surface of the Earth
○ orographic lifting due to
topographic obstruction of air
flow
○ dynamic lifting because of
the presence of a frontal
zone
Types of Thunderstorms:
○ Air Mass Thunderstorms:
Common in mid-latitudes
during summer and the
equator year-round.
○ Mid-latitude Cyclones:
Associated with cold fronts
and severe weather.

5. El Niño and La Niña