Fundamentals Of Meteorology PDF

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This document is lecture notes on fundamentals of meteorology from a university in the Philippines. It covers concepts such as seasons, temperature variations, and their applications.

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FUNDAMENTALS OF
METEOROLOGY
CAMILLE RAFAL
Instructor 1
College of Arts and Sciences
Department of Physical Sciences

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
Unit III: Seasonal and Daily
Temperature
1. Seasons in the Northern Hemisphere
2. Seasons in the Southern Hemisphere
3. Local Seasonal Variations
4. Daily Warming and Cooling of Air Near
the Surface
5. Applications of Air Temperature Data
 Learning Objectives
At the end of this topic, you should be able to:
1. explained why seasons change and how it affects the
weather;
2. described the seasonal and hourly variations of air
temperature; and
3. assessed the local diurnal cycle of temperature.

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
Why Earth has Seasons?

Our seasons are regulated by the amount of solar energy received at Earth’s surface. This amount is determined primarily
by the angle at which sunlight strikes the surface, and by how long the sun shines on any latitude (daylight hours).
Why Earth has Seasons?
The 23.5° tilt is the key
reason for the changing
seasons.
In June, the Northern
Hemisphere is tilted toward
the sun: summer.
In December, the Northern
Hemisphere is tilted away
from the sun: winter.
Seasons in the Northern
Hemisphere
Seasons in the Northern Hemisphere
Summer Solstice
On June 21, the Northern
Hemisphere is tilted toward
the sun, receiving the most direct
sunlight of the year.
The sun is directly overhead at
23.5°N latitude (Tropic of Cancer)
at noon.
This marks the astronomical start
of summer and the longest day
of the year.
Seasons in the Northern Hemisphere
Longer Daylight
On June 21, latitudes in the
Northern Hemisphere experience
more than 12 hours of daylight.
The farther north you go, the
longer the daylight, with 24 hours
of daylight at the Arctic Circle
(66.5°N) and beyond.
The North Pole has continuous
sunlight from March 20 to
September 22.
Seasons in the Northern Hemisphere
Autumnal Equinox
By September 22, the sun is
directly over the equator,
marking the autumnal equinox.
Days and nights are of equal
length around the world.
At the North Pole, the sun sets
for six months, leading to long
periods of darkness and cold
Seasons in the Northern Hemisphere
Winter Solstice
On December 21, the Northern
Hemisphere is tilted away from
the sun, marking the shortest day
of the year.
The sun is directly overhead at
23.5°S (Tropic of Capricorn).
Solar energy is spread over a
larger area, and the sun remains
low in the sky, resulting in colder
temperatures.
Seasons in the Southern
Hemisphere
Seasons in the Southern Hemisphere
Winter Solstice On June 21, the Southern
Hemisphere is tilted away
from the sun, marking the
winter solstice.
Days are short, nights are
long, and sunlight hits the
surface at a low angle,
resulting in cooler
temperatures.
This is the astronomical
start of winter in the
Southern Hemisphere.
Seasons in the Southern Hemisphere
Summer Solstice On December 21, the sun is
directly over the Tropic of
Capricorn (23.5°S), marking
the start of summer in the
Southern Hemisphere.
This is the opposite of the
Northern Hemisphere,
which experiences winter
during this period.
Travel to the Southern
Hemisphere in December to
enjoy warm, summer-like
conditions while it’s winter
up north!
Seasons in the Southern Hemisphere

When it’s summer in the
Northern Hemisphere,
it’s winter in the
Southern Hemisphere,
and vice versa.
Seasons in the Southern Hemisphere

Due to Earth’s elliptical
orbit, spring and summer in
the Southern Hemisphere are
about a week shorter than in
the Northern Hemisphere.
This slightly offsets the
additional solar energy the
Southern Hemisphere
receives when it’s closer to
the sun.
Local Seasonal Variations
 Climate of the Philippines
The climate of the Philippines is
tropical and maritime.
It is characterized by high
temperatures, high humidity, and
abundant rainfall throughout the
year.
Similar to the climate of Central
American countries.

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
 Climate of the Philippines
Temperature
The mean annual temperature
across the Philippines (excluding
Baguio) is 26.6°C.
Coolest month: January, with an
average of 25.5°C.
Warmest month: May, with an
average of 28.3°C.
Temperature variation is primarily
influenced by altitude, not latitude.

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
 Climate of the Philippines
Humidity
Humidity refers to the moisture
content in the air.
Due to the country’s high
temperatures and proximity to
surrounding bodies of water, the
Philippines experiences high relative
humidity.
Average monthly relative humidity:
71% in March (lowest)
85% in September (highest)

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
 Climate of the Philippines
Rainfall
Rainfall is the most important climatic
element in the Philippines.
Rainfall distribution varies across regions,
influenced by:
Direction of moisture-bearing winds.
Location of mountain systems.
Mean annual rainfall: Ranges from 965
mm to 4,064 mm.
Areas with highest rainfall:Baguio City,
Eastern Samar, Eastern Surigao.
Lowest rainfall: Southern Cotabato
General Santos City: Receives only 978 mm
annually.

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
 Climate of the Philippines
The Seasons
The climate of the Philippines is categorized into
two major seasons:
Rainy Season: June to November
Dry Season: December to May
Cool Dry Season: December to February
Hot Dry Season: March to May

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
 Climate of the Philippines
Climate Types
The Philippines has four distinct climate
types based on rainfall distribution:
Type I: Two distinct seasons (dry and wet).
Type II: No distinct dry season; rainfall is evenly
distributed throughout the year.
Type III: Rainfall more or less evenly
distributed, but with a pronounced dry period.
Type IV: Rainfall is evenly distributed
throughout the year with no significant dry
season.

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
Daily Warming and Cooling
of Air Near the Surface
 Daytime Warming
▪ Sunlight warms the ground, and the ground warms the air in contact
with it by conduction.
▪ Air is a poor heat conduction.
▪ Near surface, convection can also help to
redistribute the heat. In calm weather, the
thermal convection effect is small
and do not effectively mix the air
near the surface.
▪ Thus, there is a substantial temperature
difference above the ground on windless
day.
Daytime Warming
▪ On windy days, turbulence eddies are able to mix hot,
surface air with cooler air above.

▪ This form of mechanical
stirring, called forced
convection, helps the
thermals to transfer heat
away from the surface more
efficiently.
Daily Temperature Variations
▪ Around noon, the sun’s rays are most intense.
▪ However, even though incoming solar radiation
decreases in intensity after noon, it still exceeds
outgoing heat energy from the surface for a time.
▪ This situation leads to energy surplus for 2-4 hours
after noon.
▪ It leads to a lag between the time of maximum
solar heating and the time of maximum air
temperature.
Daily Temperature Variations
Daily Temperature Variations
▪ The exact time of the maximum temperature varies.
▪ Tmax is about 3-5pm during summer cloud-free days.
▪ If there is afternoon cloudiness or haze, Tmax usually occurs an hour or
two later.
▪ Tmax also depends on surface type and cover
1. Absorption characteristics (Strong absorbers enhance surface
heating)
2. Vegetation/moisture (Available energy partially used to
evaporate water)
▪Tmax also depends on wind. Strong mixing by wind will mix heated air
near ground to higher altitudes.
 Nighttime Cooling
▪ At night, both ground and air above cool by radiating infrared energy,
a process called radiational cooling.
▪ Ground, a better radiator than air, is
able to cool more quickly.
▪ After sunset, surface is cooler
than the air above it.

Measured increase in air temperature above the
ground is known as radiation inversion or
nocturnal inversion.
Nighttime Cooling

Temperature gradient is smaller in
windy night than calm night.
Evening length, water vapor,
clouds, and vegetation affect
earth’s nighttime cooling.
 Cold Air Near the Surface

Night time radiational cooling increases air density. Cold, heavier air settles to the valley bottom.
It leads to a thermal belt of warmer air between lower and upper cooler air.
 Cold Air Near the Surface

On the valley floor, cold and dense air cannot rise. Smoke and other pollutants are trapped. Thus,
valley bottom is colder and more frequently polluted than nearby hillsides.
Applications of Air
Temperature Data
Protecting Crops from the Cold Night Air
▪ On cold nights, many plants may be damaged by low
temperatures.
▪ To protect small plants or shrubs, cover them with straw, cloth, or plastic
sheeting. This prevents ground heat from being radiated away to the colder
surroundings.
▪ The lower branches of fruit trees are
the most susceptible to damage.
Increasing the air temperature close to
the ground may prevent damage. We
can increase near-ground temperature
by using orchard heaters. It can warm
the air around the trees by setting up
convection currents close to the
ground.
Protecting Crops from the Cold Night Air
▪ Another way to protect trees is to mix
the cold air at the ground with the
warmer air above, thus raising the
temperature of air next to the ground.
This can be accomplished by using
wind machines.
Daily (Diurnal) Range of Temperature
▪ Greatest variation in daily temperature
occurs at the earth’s surface. It becomes
smaller as we move away from the
surface.
▪ By day, clear summer skies allow the
sun’s energy to quickly warm the ground.
At night, the ground cools rapidly by
radiating infrared energy to space.
Daily (Diurnal) Range of Temperature
▪ The largest diurnal range of temperature occurs on high deserts, where
the air is fairly dry, often cloud-free. There is little water vapor to radiate
much infrared energy back to the surface.

▪ Clouds are good reflectors of incoming solar radiation, and so they
prevent much of the sun’s energy from reaching the surface during
daytime.

▪ If the clouds persist into the night, they tend to keep nighttime
temperatures higher, as clouds are excellent absorbers and emitters of
infrared radiation.
Measuring Air Temperature
▪ Thermometers were developed to measure air temperature.

▪ Liquid-in-glass thermometers are often used for measuring
surface air temperature because they are easy to read and
inexpensive to construct.

▪ Thermometers have a glass bulb attached to a sealed tube about 25
cm long. When the temperature rises (decreases), the liquid in
the bulb expands (contracts). Hence, the length of the liquid in the
tube represents the air temperature.
Maximum Thermometer
▪ Maximum thermometer looks like any other liquid-in-glass thermometer
with one exception:
▪ It has a small constriction within the bore just above the bulb.
▪ As the air temperature increases, the mercury expands and freely moves past the
constriction up the tube, until the maximum temperature occurs.
▪ However, as the air temperature begins to drop, the small constriction prevents the
mercury from flowing back into the bulbs.
▪ Thus, the end of the stationary mercury column
indicates the maximum temperature for the
\day.
Maximum Thermometer
Minimum Thermometer
▪ A minimum thermometer measures the lowest temperature during a given period.

▪ It is similar to other liquid-in-glass thermometers except that it contains a small barbell-shaped index
marker in the bore.

▪ As the air temperature drops, the contracting liquid moves back into the bulb and brings the index marker
down the bore with it.

▪ When the temperature stops decreasing, the liquid and the index marker stop moving down the bore.

▪ When the temperature increases, the alcohol expands and moves freely up the tube past the stationary
index marker.
▪ Because the index marker does not move as the air
warms, the minimum temperature is read by

observing the upper end of the marker.
Other Thermometers
▪ Electrical thermometer: Since the
resistance of the material chosen for
these thermometers changes as the
temperature changes, the resistance can
be calibrated to represent air
temperature.
▪ Infrared sensors (Radiometers): By
measuring both the intensity of radiant
energy and wavelength of maximum
emission of a particular gas (either H2O
or CO2), radiometers in orbiting
satellites are able to estimate the air
Temperature from Atmospheric
temperature at selected levels in the Infrared Sounder on Aqua Satellite
atmosphere.
Other Thermometers
▪ Bimetallic thermometer: It consists of two different metal (brass and iron)
welded together to form a single strip. As the temperature changes, the brass
expands more than the iron, causing the strip to bend.The small amount of
bending is amplified through a system of levers to a pointer on a calibrated scale.
 Summary
1. Daily variation in air temperature near the earth’s surface is
controlled mainly by the input of energy from the sun and output
energy from the surface.
2. On a clear, calm day, surface air warms as long as heat input (sunlight)
exceeds heat output (convection and radiated infrared energy).
3. Surface cools at night as long as heat output exceeds input.
4. Coldest air is normally found at the surface, for the ground at night
cools more quickly than the air above.
5. Greatest daily variation in air temperature occurs at the earth’s
surface.
 ACTIVITY 2
Temperature Diurnal Cycle
DEADLINE: SEPT 23. 2024
Objectives:
Understand the daily temperature variation (diurnal cycle).
Explore factors influencing temperature changes throughout
the day.
Learn how temperature is measured and the instruments
used.
Formatting: Use A4 paper, Times New Roman, size 12 font,
and justified alignment for your report.

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
 ACTIVITY 2
Temperature Diurnal Cycle
Instructions:
Data Gathering:
Utilize weather apps or online platforms to gather hourly temperature data for a 24-
hour period.
Graphing:
Plot the recorded temperature data on a graph with the time of day on the x-axis
and temperature on the y-axis.
Identify and mark key features of the temperature curve, such as:
Time of Maximum Temperature (Tmax): The point at which the
temperature is highest Time of Minimum Temperature (Tmin): The point
at which the temperature is lowest

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
 ACTIVITY 2
Temperature Diurnal Cycle
Analysis: (5-10 Sentences only) (You must elaborate the graph you created)
Discuss the observed diurnal temperature pattern and compare it with theoretical
expectations.
Discuss how factors such as cloud cover, wind, and surface type affect the
temperature cycle:
Cloud Cover: Clouds can block solar radiation, leading to cooler daytime
temperatures and warmer nighttime temperatures.
Wind: Wind can enhance cooling during the day by mixing air and dissipating
heat, and it can prevent temperature extremes at night.
Surface Type: Different surfaces absorb and radiate heat differently. For
instance, urban areas with asphalt and concrete heat up more during the day and
cool down faster at night compared to rural areas with vegetation.

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
 ACTIVITY 2: RUBRICS
Criteria Excellent (4 points) Good (3 points) Fair (2 points) Poor (1 point)

Accurate and complete data Accurate data but may miss Incomplete data or missing Data is incomplete or
Data Gathering
for a full 24-hour period minor details several hours highly inaccurate

Clear, accurate graph with
Graph is mostly clear with Graph is unclear or missing Graph is incomplete or
Graphing well-labeled axes and key
minor issues important labels poorly labeled
features
Identification of Key Accurately identifies and Identifies Tmax and Tmin Identifies Tmax and Tmin Does not correctly identify
Features marks Tmax and Tmin with minor errors with several errors Tmax or Tmin
Thorough discussion that
Analysis of
accurately compares Good discussion with some Basic discussion with Limited or inaccurate
Temperature
observed data with minor inaccuracies significant gaps discussion
Pattern
theoretical expectations

Comprehensive discussion
Discussion of Good discussion with minor Basic discussion with Limited or inaccurate
of cloud cover, wind, and
Influencing Factors gaps several inaccuracies discussion
surface type impacts
Perfect adherence to
Formatting and Noticeable formatting Poor formatting and
formatting instructions (A4, Minor formatting errors
Presentation errors presentation
TNR, 12, Justified)

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
 LONG EXAM
SEPT 23. 2024
Coverage: Units II & III
50 items
1-30 Multiple choice

31-40 Identification

41-50 Essay

COLLEGE OF ARTS & SCIENCES Department of Physical Sciences
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