1. Seasons What do your students think causes the seasons?
We begin our workshop with a discussion of some of the misconceptions about seasons.
Squirrel image taken at Kennedy Space Center
Blue Heron also taken at Kennedy Space Center
Images at
Created by the Lunar and Planetary Institute
For Educational Use Only
LPI is not responsible for the ways in which this powerpoint may be used or altered.

2. Rising of the Sun for USA
The Sun rises in the East
The Sun sets in the West
During this section, we demonstrate physically, using a planetarium or the horizon or the walls of the classroom, the location of the Sun’s path across the sky for each of the seasons, and ask the participants to predict how high the Sun rises in the sky and where it will set.

3. Earth’s orbit is almost a perfect circle
Earth is CLOSEST to our Sun (91 million miles) in winter—January 3
Earth is farthest from on our Sun (94 million miles) in summer –July 4
Misconception: Distance from the Sun has nothing to do with the seasons
More information at

4. We know that the reason we have day and night is because the Earth
rotates.
Rotate means
to turn.
The Earth rotating on its
______
gives us day and night.
axis
Earth’s axis is
the imaginary line that goes through the center of the Earth.

5. Daylight Hours Across the Globe Time is indicated as number of hours (h)
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
10.5 h h h h h h h h h h h h
14.5 h h h h h h h h h h h h
12 h h h h h h h h h h h h
17.5 h h h h h h h h h h h h
5 h h h h h h h h h h h h
12 h h h h h h h h h h h h
15 h h h h h 10 h h h h h h h
9 h h h h h h h h h h h h
24 h h h h h h h h h h h h
Miami
Brisbane
Nairobi
Punta Arenas
Nome
Singapore
Cape Town
Seattle
Vostok
Once the reason for seasons has been demonstrated, the concepts can be mastered with further activities. For instance, the participants may be able to predict the location of various cities (far north, north, equatorial, south, or far south) from the pattern of daylight hours throughout the year.
From SkyTellers activity
Seasons Across the Continents

6. The tilt of the Earth causes the seasons
Remember: Oceans affect climate. The Gulf Stream flows into the North Atlantic Drift carrying warm water north

7. True color images December March June September
An understanding of seasons can begin with observations. What is it like here in December? In June? What is it like in other cities? In other countries? Teachers can use satellite photos like these, or look at newspapers with temperatures for various cities around the world throughout the year.
Photos from
Using data from the Moderate Resolution Imaging Spectroradiometer (MODIS) aboard NASA’s Terra satellite, scientists and data visualizers stitched together a full year’s worth of monthly observations of the land surface, coastal oceans, sea ice, and clouds into a seamless, photo-like mosaic of every square kilometer (.386 square mile) of our planet.
Changes in ice are most obvious for the northern hemisphere; changes in vegetation can be seen in Africa and South America.
A separate animation can be downloaded and played here:
Images at

8. Average Daily Temperatures (°F) in Tourist Cities
(from ))
January
April
July
October
Cape Town (South Africa) 69 66 60 65
Caracas (Venezuela) 75 81 78 79
London (United Kingdom) 44 56 73 58
Mexico City (Mexico) 77 70
Montreal (Canada) 22 51
Moscow (Russia) 21 47 76 46
Nairobi (Kenya)
Paris (France) 42 59
San José (Costa Rica)
Seoul (Korea) 33 62 84 67
Singapore 86 89 87 88
Stockholm (Sweden) 31 45 48
Sydney (Australia) 72
Tokyo (Japan) 64

9. Animation-Earth’s Life through Seasons
SeaWiFS false color data showing seasonal change in the oceans and on land for the entire globe. The data is seasonally averaged, and shows the sequence: fall, winter, spring, summer, fall, winter, spring (for the Northern Hemisphere).

10. Let’s Start with some Observations
Using free downloaded computer program, Stellarium:
Stellarium is planetarium software that shows exactly what you see when you look up at the stars. It's easy to use, and free.
Let’s look at sunrise & sunset, and Sun’s height in the sky.

11. What Causes Earth’s Seasons?
Earth’s axis is tilted 23.5 degrees – it always points in the same direction (Polaris, the North Star) as we orbit our Sun once a year
This tilt causes the hemispheres to alternate in the amount of our Sun’s light and heat they receive through the year
More information is at
This image shows the reason Earth experiences seasons.  Points we discuss using this image are:
1) Earth’s orbit around the Sun is only slightly elliptical
2) Earth’s path around the  Sun brings us closer to the Sun in January.  Many students think we have seasons because Earth is sometimes closer and sometimes farther from the Sun.  This is correct, however, we actually are closer to the Sun in January in the Northern Hemisphere!
3) Earth’s seasons are caused by Earth’s tilt on its axis (~23 degrees).  Earth’s axis essentially is fixed  - it always points to the same place in the sky (on the celestial sphere) – towards Polaris. As we orbit the Sun each year, first one polar region is tilted toward the Sun, and then the other is tilted toward the Sun. When the north polar region is tilted toward the Sun (summer) the south polar region is tilted away (winter).
Notes: Earth’s tilt does change over very long time periods, but for the most part, it moves between 22 and 23 degrees. Earth’s axis also wobble a bit, but over time periods of thousands of years, pointing toward different stars.
Image at

12. Northern Hemisphere Summer
At this point, we have participants use styrofoam balls with sticks and a bright lamp to model the seasons on the Earth, with the axis of the “Earth” tilted toward a “North Star” that has been placed high in the corner of the room.
For part of our orbit the northern half of Earth is tilted toward the Sun. This is summer in the northern hemisphere; there are longer periods of daylight, the Sun is higher in the sky, and the Sun's rays strike the surface more directly, giving us warmer temperatures. The north pole is in constant daylight!
When the northern half of Earth is tilted toward the Sun, the southern hemisphere is tilted away. People in the southern hemisphere experience the shorter day lengths and colder temperatures of winter.
During winter in the northern hemisphere, our northern axis continues to point to the North Star, but, because we have moved in our orbit around the Sun, our northern hemisphere now points away from our Sun. The north pole is completely dark and other places in the northern hemisphere experience the shorter day lengths and colder temperatures of winter as the Sun traces a lower arc across the southern sky and the Sun's rays strike the surface at a lower angle. When it is winter in the northern half of Earth, the southern hemisphere, tilted toward our Sun, has summer.
During fall and spring, some locations on Earth experience similar, milder, conditions. Earth has moved to a position in its orbit where its axis is more or less perpendicular to the incoming rays of the Sun. The durations of daylight and darkness are more equally distributed across all latitudes of the globe.
Solstices occur when Earth's axis is pointed directly toward our Sun. This happens twice a year during Earth's orbit. Near June 21 the north pole is tilted 23.5 degrees toward our Sun and the northern hemisphere experiences summer solstice, the longest day of the northern hemisphere year. On that same day, the southern hemisphere is tilted 23.5 degrees away from our Sun and the southern regions of Earth experience the shortest day of the year — the winter solstice.
The second solstice occurs on December 21 or 22 when the north pole is tilting 23.5 degrees away from our Sun and the south pole is inclined toward it. This is the shortest day of the year in the northern hemisphere — the northern hemisphere winter solstice.
Twice each year, during the equinoxes (“equal nights”), Earth's axis is not pointed toward our Sun, but is perpendicular to the incoming rays. During the equinoxes every location on our Earth (except the extreme poles) experiences 12 hours of daylight and 12 hours of darkness. The vernal or spring equinox occurs in the northern hemisphere on March 21 or 22 (the fall equinox of the southern hemisphere). September 22 or 23 marks the northern hemisphere autumnal or fall equinox.
As Earth orbits our Sun, the position of its axis relative to the Sun changes. This results in a change in the observed height of our Sun above the horizon. For any given location on Earth, our Sun is observed to trace a higher path above the horizon in the summer, and a lower path in the winter. During spring and fall, it traces an intermediate path. This means that our Sun takes a greater amount of time tocross the sky in the summer and a shorter amount of time in the winter. This effect is greater as you move toward the poles; people living near the equator experience only small changes in daylight during the year. The change is more extreme toward the poles.
From the National Maritime Museum
During the northern hemisphere summer solstice, Earth is tilted such that the Sun's rays strike perpendicular to the surface at the Tropic of Cancer (23.5 degrees north latitude, corresponding to the tilt of Earth's axis). At (solar) noon, our Sun is directly overhead in this location (and at a decreasing height above the horizon north and south of the Tropic of Cancer). At locations north, our Sun will be at its highest position above the horizon and will take the greatest amount of time to cross the sky. All northern locations have more than 12 hours of daylight. All locations south experience less than 12 hours of daylight. Locations above the Arctic Circle (north of 66.5 degrees latitude; 90 degrees minus the tilt of Earth's axis) receive 24 hours of sunlight. Locations below the Antarctic Circle (66.5 degrees south latitude) experience 24 hours of darkness.
During the northern hemisphere winter solstice, the Sun's incoming rays are perpendicular to the Tropic of Capricorn at 23.5 degrees south latitude. The Sun's path is the lowest above the horizon in locations north of the equator, and these regions experience the shortest day of the year. Between the winter and summer solstices, daylight increases as Earth continues its orbit around our Sun.
During the equinoxes, sunlight strikes perpendicular to the surface at Earth's equator. All locations on Earth, regardless of latitude, experience 12 hours of daylight and 12 hours of darkness. The spring equinox marks the change from 24 hours of darkness to 24 hours of daylight at Earth's poles . In these extreme locations, our Sun moves above the horizon at the spring equinox and does not go below the horizon until the fall equinox.
More daylight hours, more direct sunlight
Image at

13. But guess what! Rotating isn’t the only way the Earth moves in space!
The Earth also revolves.
Revolve – When one object moves around another object

14. How long does one revolution take?
It takes the Earth one year, or 365 ¼ days to orbit the sun.
Does anyone know what orbit means?
The path that an object follows as it revolves around another object.
Every 4 years we add a day for the ¼’s- Leap Year