EARTH-SUN RELATIONS - Los Angeles Mission College
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Transcript EARTH-SUN RELATIONS - Los Angeles Mission College
EARTH-SUN
RELATIONS
Rotation, Revolution, Seasons
7/18/2015
(c) Vicki Drake, SMC
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EARTH’S ROTATION
The Earth rotates on
its axis
One complete rotation
(3600) takes
approximately 24
hours
• Rotation is from West to
East
Sun appears to ‘rise’ in
East and ‘set’ in West
• Rotation speed is
variable
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Fastest at the equator
(c) Vicki Drake, SMC
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EARTH’S REVOLUTION ABOUT
THE SUN
The Earth revolves about the Sun
• One complete revolution takes
365.2422 days
365 days, 5 hours, 48 minutes, 36 seconds
Approximately 365 ¼ Earth days
The Earth’s revolution is slightly
elliptical, not circular
• Direction of revolution is counterclockwise from an outer space
perspective
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(c) Vicki Drake, SMC
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AXIS TILT AND REVOLUTION
Earth moves in a constant
plane – Plane of the
Ecliptic – in its revolution
about the Sun
• All the planets (and even
the sun) are moving in the
Plane of the Ecliptic
Earth’s axis is tilted about
23.50 from perpendicular
to Plane of Ecliptic
Earth’s tilt has two
characteristics:
• Angle of inclination
• Parallelism
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(c) Vicki Drake, SMC
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ANGLE OF INCLINATION AND
PARALLELISM
The angle of
inclination, the tilt
of 23½ degrees, is
a constant.
• The angle does not
change throughout
the entire revolution
Parallelism means
the axis is always
pointed in the
same direction
• The axis does not
point in different
directions as the
Earth moves in its
orbit
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(c) Vicki Drake, SMC
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EARTH’S ELLIPTICAL
REVOLUTION
The Earth, in its elliptical revolution,
has an average distance of
approximately 93,000,000 miles
from the Sun
At two points in the revolution, the
distance varies
• Perihelion: Earth is closest to Sun,
~91.5 million miles
• Aphelion: Earth is farthest from Sun,
~95.5 million miles
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(c) Vicki Drake, SMC
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PERIHELION AND APHELION
95,500,000
miles
91,500,000
miles
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(c) Vicki Drake, SMC
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PERHELION AND APHELION DATES
Perihelion occurs on, or about,
January 3
• Northern Hemisphere Winter
Aphelion occurs on, or about, July 4
• Northern Hemisphere Summer
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(c) Vicki Drake, SMC
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PERIHELION
At Perihelion, the Earth’s orbit is the
closest to the Sun .
The Northern Hemisphere is ‘tilted
away’ from the sun, receiving less
solar radiation, with shorter daylight
hours.
This is the Winter period for the
Northern Hemisphere.
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(c) Vicki Drake, SMC
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PERIHELION
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APHELION
At Aphelion, the Earth’s orbit is
furthest away from the Sun.
The Northern Hemisphere is ‘tilted
toward’ the Sun, resulting in more
solar radiation, and longer daylight
hours.
This is the Northern Hemisphere
Summer period.
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(c) Vicki Drake, SMC
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APHELION
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Changes in Axis Orientation, Tilt
and Revolution
Orientation of Earth’s axis changes during a
23,000-year cycle called precession
The Earth’s degree of tilt (obliquity) changes
through a 41,000-year cycle – ranging between
22.5 and 24 degrees
Earth’s orbit (revolution) about the Sun changes
from nearly circular to elliptical and back every
100,000 years – this process is called eccentricity
Milankovitch Theory: these changes can be linked
to long-term climate changes based on latitudinal
differences in insolation (incoming solar radiation)
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(c) Vicki Drake, SMC
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CIRCLE OF ILLUMINATION
During rotation, at any given time, half of the Earth is
receiving solar radiation – daylight
The other half of the Earth is in darkness – night
The ‘line’ separating day from night is the Circle of
Illumination
The image below illustrates the Circle of Illumination
without the tilt of the axis
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(c) Vicki Drake, SMC
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INSOLATION AND LATITUDES
Insolation: solar radiation received by
the Earth (incoming solar radiation)
Seasons: Variations of insolation due to
spherical surface of Earth
Some latitudes receive more insolation:
• Angle of incidence
• Duration
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(c) Vicki Drake, SMC
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INSOLATION AND LATITUDES
Only one latitude, at any
time during Earth’s
revolution, receives
insolation at right angles at
noon
• The subsolar point on the
Earth
• Zenith Angle for Sun
Intensity of insolation
measured by using Sun’s
zenith angle
Subsolar
point
• Sun’s angle above horizon
at local noon
The angle at which Sun’s
rays strike Earth’s surface
determines amount of
insolation
• More direct angle =
greater insolation
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(c) Vicki Drake, SMC
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LATITUDES and SUN RELATIONS
The following three latitudes are important because of their significance
to seasons on the Earth
•
Equator: 00
•
•
an imaginary line on the Earth's surface equidistant from the North Pole and South Pole
that divides the Earth into a Northern Hemisphere and a Southern Hemisphere
Two days per year (Autumnal Equinox: September 21,22 and Vernal Equinox: March 20)
the Sun’s location, at local noon is directly over the Equator
Tropic of Capricorn: 23½0 South
•
On certain days of the year (Equinoxes and Solstices), the Sun’s Zenith Angle, at
local noon, will be 900 above one of these latitudes
One day per year (Winter Solstice: December 21, 22) the Sun’s location, at local noon, is
in the Capricorn constellation
Tropic of Cancer: 23½0 North
•
One day per year (Summer Solstice: June 21,22) the sun’s location, at local noon, is in
the Cancer constellation
------------------------------------------------------------------------------
Arctic Circle: 66½0 North
•
marking the southern limit of the area where the sun does not rise on the Northern
Hemisphere winter solstice (December 21) or set on the summer solstice (June 21)
Antarctic Circle: 66½0 South
•
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marks the northern limit of the area where the Sun does not set on the Southern
Hemisphere summer solstice (December 21) or rise on the winter solstice (June 21)
(c) Vicki Drake, SMC
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ZENITH ANGLE AND LATITUDES
– WITHOUT TILT
66 1/20 N
23 1/20 N
00
23 1/20 S
66 1/20 S
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SOLSTICES, EQUINOXES, AND LATITUDES:
NORTHERN HEMISPHERE BIAS!
Summer Solstice: Sun’s Zenith Angle of
900, at noon, is located at Tropic of
Cancer, 23.50 (23 ½0) North
• On or about June 21, 22
Winter Solstice: Sun’s Zenith Angle of 900,
at noon, is located at Tropic of Capricorn,
23.50 (23 ½0) South
• On or about December 21, 22
Vernal Equinox and Autumnal Equinox:
Sun’s Zenith Angle of 900, at noon, is
located at the Equator, 00
• On or about March 20 and September 21, 22
respectively
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(c) Vicki Drake, SMC
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SUMMER SOLSTICE
Summer Solstice, June
21, 22
Northern Hemisphere is
tilted towards the Sun
Latitudes higher than 66.50
North receive 24 hours of
sunlight
Latitudes higher than 66.50
South receive 24 hours of
night
Longest period of daylight
for one day in year for
Northern Hemisphere
latitudes
• First day of Summer:
Northern Hemisphere
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(c) Vicki Drake, SMC
Vertical rays of
Sun at noon
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WINTER SOLSTICE
Winter Solstice,
December 22
Northern Hemisphere tilted
away from the Sun
Latitudes higher than 66.50
North receive 24 hours of
night
Latitudes higher than 66.50
South receive 24 hours of
daylight
Longest period of night for
one day for Northern
Hemisphere latitudes
• First day of Winter:
Northern Hemisphere
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(c) Vicki Drake, SMC
Vertical rays
of sun at
noon
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EQUINOXES: VERNAL, AUTUMNAL
Sun’s
vertical rays
at noon
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(c) Vicki Drake, SMC
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VERNAL (SPRING) EQUINOX
Vernal Equinox, March 20
Zenith Angle of Sun at noon is 900 above Equator
Day and night are of equal length at all locations
on the Earth
First day of Spring, Northern Hemisphere
Calendar (including specific dates) and even
monuments based on Vernal Equinox
• For example: the Council of Nice decreed in 325 A.D.
that "Easter was to fall upon the first Sunday after the
first full moon on or after the Vernal Equinox”
• Julian and Gregorian Calendar
• Early Egyptians built the Great Sphinx so that it points
directly toward the rising Sun on the day of the Vernal
Equinox.
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(c) Vicki Drake, SMC
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AUTUMNAL (FALL) EQUINOX
Autumnal Equinox, September 22
Zenith Angle of Sun at noon is 900
above Equator
Day and night are of equal length at
all locations on the Earth
First day of Fall, Northern
Hemisphere
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(c) Vicki Drake, SMC
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SEASONS AND EARTH’S REVOLUTION
Direct Rays
23 1/20 N
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Direct Rays
23 1/20 S
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CALENDARS AND SEASONS
Julian Calendar:
• Introduced in 46 BC
• A regular year of 365 days divided into
12 months, and a leap day is added to
February every four years.
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The Julian year is, on average, 365.25 days
long.
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CALENDARS AND SEASONS
Gregorian Calendar
Decreed in 1582 by Pope Gregory
• Equinox and solstices almost two weeks early
on Julian Calendar
• Pope Gregory dropped 10 days from calendar
to put equinoxes and solstices back on track.
October 4 followed by October 15
Changes in Gregorian Calendar
• Add extra day to month of February every four
years: “Leap Year”
• Exception - only century years divisible by 400
become leap years
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SEASONS
Distance between Earth and Sun NOT a
determinant of seasons
• Perihelion occurs during Northern Hemisphere winter
Determinant # 1: Angle of Incidence of Sun’s
rays striking Earth’s surface
• Latitudes receiving more perpendicular rays receive
more insolation for heating
Determinant # 2: Length of daylight hours
• Longer daylight hours means more insolation
Determinant # 3: Angle of Incidence and length
of daylight hours directly affected by tilt of
Earth’s axis
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ANGLE OF INCIDENCE INSOLATION
The more
vertical the
rays of Sun
means a more
concentrated
amount of
solar radiation
for a location.
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(c) Vicki Drake, SMC
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ANALEMMA – MAPPING THE
SUN’S MOVEMENT
An analemma traces the annual
movement of the Sun on the sky.
• It illustrates the positions of the Sun at the
same time of day (at approximately 24 hour
intervals) and from the same location on Earth
on successive days through the calendar year.
• This apparent shift of Sun’s position is due to
the Earth’s orbit about the Sun
• An analemma appears as a ‘loopy’ figure eight
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the highest point is Summer
the lowest point, Winter
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ANALEMMA
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ANALEMMA
The Analemma has a
calendar printed on it
• This calendar indicates
which latitude (subsolar
point) receives the Sun’s
direct rays at noon
(“Zenith Angle”) on any
day of the year.
The most northern
latitude is 23.50 North
The most southern
latitude is 23.50 South
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(c) Vicki Drake, SMC
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