Unit Overview

Students master Earth-sun-moon cyclic patterns and gravity's role in cosmic motions. Through solving opposite season mysteries or investigating satellite orbital mechanics without engines, conducting three investigations testing light dispersion on flat, round, and tilted surfaces creating travel brochures explaining seasonal differences, and designing scaled solar system amusement parks or constellation models demonstrating distance-brightness relationships, students learn Earth's movements create observable patterns.

  • Lesson 1
    Lesson 1: Solve: Satellite + Summer Snowboarding Mystery

    Solve: Satellite + Summer Snowboarding Mystery

    Neve's ski instructor crew steps off the plane in New Zealand expecting winter and snow jobs—instead, bikinis and summer sun! Panic sets in as employment vanishes. Students follow Mosa disproving wrong theories (New Zealand closer to sun? No! Distance barely changes. Different sun? No! Same sun!). The correct answer: Earth's tilt. Earth is tilted 23.5 degrees on its axis. When Northern Hemisphere (Colorado) tilts toward sun, it receives direct sunlight = summer. Simultaneously, Southern Hemisphere (New Zealand) tilts away, receiving angled sunlight = winter. Six months later, positions reverse. Same day, opposite seasons—Earth's tilt determines angle of sun's rays hitting each hemisphere!

  • Lesson 2
    Lesson 2: Make: Model Light Dispersion and the Earth-Sun System

    Make: Model Light Dispersion and the Earth-Sun System

    Three investigations about light dispersion and seasons. Investigation 1: Flat Surface—shine flashlight at different angles on graph paper, measuring light spread (direct = concentrated/hot, angled = dispersed/cool). Investigation 2: Round Surface—repeat with styrofoam sphere discovering curved surface affects light distribution. Investigation 3: Tilted Earth Orbiting Sun—skewer through tilted styrofoam Earth, orbit around lamp "sun" in darkened room, observe how tilt creates seasons as different hemispheres receive varying light angles. Create travel brochures for Northern and Southern Hemisphere destinations, explaining seasonal differences using Earth's tilt and sun angle knowledge. Research best travel times!

  • Lesson 2
    Lesson 2: Extension: Lunar Phases

    Extension: Lunar Phases

    Students will develop and use a model of the Sun-Earth-Moon system to describe the cyclic patterns of lunar phases, and eclipses of the sun and the moon. (75 minutes)

  • Lesson 3
    Lesson 3: Engineer: Explore Scale and Build a Planet Amusement Park

    Engineer: Explore Scale and Build a Planet Amusement Park

    Design a space-themed amusement park with scaled planet sizes and distances plus rides representing each planet's conditions! Part 1: Mystery bag of spheres—match spheres to planets using scaled diameters (1 cm : 6,370 km scale: Mercury = marble 0.8 cm, Mars = marble 1 cm, Venus = 1.8 cm sphere, Earth = 2 cm, Sun = 218.5 cm diameter or three yoga balls). Part 2: Map scaled distances on classroom walls. Part 3: Design amusement park with rides matching planetary conditions (Venus roller coaster through sulfuric acid clouds? Mars low-gravity trampolines? Jupiter storm simulators?). Accurate scaling teaches solar system proportions!

  • Next Generation Science Standards
    MS-ESS1-1
    Develop and use a model of the Earth sun moon system to describe the cyclic patterns of lunar phases, eclipses of the sun and moon, and seasons. [Clarification Statement: Examples of models can be physical, graphical, or conceptual.]
    MS-ESS1-2
    Develop and use a model to describe the role of gravity in the motions within galaxies and the solar system. [Clarification Statement: Emphasis for the model is on gravity as the force that holds together the solar system and Milky Way galaxy and controls orbital motions within them. Examples of models can be physical (such as the analogy of distance along a football field or computer visualizations of elliptical orbits) or conceptual (such as mathematical proportions relative to the size of familiar objects such as students' school or state).] [Assessment Boundary: Assessment does not include Kepler’s Laws of orbital motion or the apparent retrograde motion of the planets as viewed from Earth.]
  • Inquiry Scale
    • Each lesson in the unit has an Inquiry Scale that provides directions on how to implement the lesson at the level that works best for you and your students.
    • “Level 1” is the most teacher-driven, and recommended for students in 4th-5th grades. “Level 4” is the most student-driven, and recommended for students in 7th-8th grades.
    • For differentiation within the same grade or class, use different inquiry levels for different groups of students who may require additional support or an extra challenge.
  • Common Misconceptions
    • Students sometimes assume that the Earth is flat since the ground they walk on is flat. Emphasize through the Solve that the Earth is round, and this round shape affects angles of sunlight.
    • Students sometimes have a hard time believing that the Earth is moving and orbiting the sun because they can’t feel it. It is true that the Earth is moving at a very fast rate, but the reason they can’t feel it is because Earth is moving at a constant rate. Encourage students to think of how they feel in a car or airplane moving at a constant speed as opposed to a car or airplane that is quickly accelerating.
    • Students tend to assume that every area of the world experiences seasons at the same time. Use the Solve and the model in the Make to emphasize that because the Earth is tilted, the northern hemisphere and the southern hemisphere experience different sun angles at different times of year.
    • Students initially think that different regions of the Earth are warmer from being closer to the sun. Emphasize to students through the Solve and Make that it is not about distance to the sun, but rather the angle at which the sun hits the Earth. Use the example of the equators vs. the poles.
  • Vocabulary
      • Earth
      • Angle of Sunlight
      • Equator
      • Heat
      • Poles
      • Season
      • Sun
  • Leveled Reading

    * To give our users the most comprehensive science resource, Mosa Mack is piloting a partnership with RocketLit, a provider of leveled science articles.

    • Why are Planets Round?

      This article explains how gravity works to pull planets and stars together into spheres.

    • Space Tug o' War!

      Why doesn't the Earth fall into the Sun? In this article, we define the terms mass, gravity, orbit, and velocity. This article serves to introduce students to the ideas behind why planets are able to stay in orbit by flying through space at just the right velocity, and with just the right amount of gravitational pull from their star.

    • The Trip Around the Sun

      In this article, students learn about the different elements of Earth's orbit around the sun. We introduce students to the orbit around the star, the period of revolution, and the tilt of our axis.

    • Light Hits All of Us Differently

      In this article, students will read about all how seasons are affected by earth's axis and rotation. They'll also read about why it's hotter at the equator and colder toward the poles.

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