This resource accompanies our Rethink 6th Grade Science course. It includes ideas for use, ways to support exceptional children, ways to extend learning, digital resources and tools, tips for supporting English Language Learners and students with visual and hearing impairments. There are also ideas for offline learning. 

Please make a copy and edit to fit the needs of your students.

In this lesson, students will learn how cosmic rays were discovered and what they are - including their size and speed. Includes background information for the teacher, questions, activities and information about student preconceptions. This is lesson 1 of 4 from "The Cosmic Ray Telescope for the Effects of Radiation (CRaTER)."

This activity introduces students to the visible light spectrum, and demonstrates what happens to the appearance of an image when certain wavelengths of light are blocked by filters or made visible using special tools. Students are lead through experiments with light and filters, demonstrating that the broader the range of the electromagnetic spectrum we can detect, the more information we gather about the universe. By completing this activity, students gain background information that is necessary for activities that follow this one. This activity is part of the "Cosmic Questions: Our Place in Space and Time" educator's guide that was developed to support the Cosmic Questions exhibit. Activities in the guide can be used in conjunction with, or independently of, the exhibt.

Students learn how CCD cameras use color filters to create astronomical images in this Moveable Museum unit. The four-page PDF guide includes suggested general background readings for educators, activity notes, and step-by-step directions. Students look at black-and-white photos to understand gray scale and construct simple red and green cellophane filters and observe magazine images through them.

Students learn how a telescope's aperture determines how much light it can gather in this Moveable Museum unit. It has three procedures, one of which is optional. The four-page PDF guide includes suggested general background readings for educators, activity notes, step-by-step directions, and information about where to obtain supplies. In this activity, the light collector is not a lens or a mirror, but a hole in a cardboard box. Light enters through the hole and lights up the box. Users can change the size of the hole and see how the amount of light entering the box changes. The results show why increasing the aperture of a telescope increases the amount of light it can collect.

Sample Learning Goals
Explore how light interacts with molecules in our atmosphere
Identify that absorption of light depends on the molecule and the type of light
Relate the energy of the light to the resulting motion
Identify that energy increases from microwave to ultraviolet
Predict the motion of a molecule based on the type of light it absorbs
Identify how the structure of a molecule affects how it interacts with light

A complete introduction to scientific investigation and the scope of physical science. Includes: states of matter, atoms, periodic table, chemical bonding, chemical reactions, carbon chemistry, chemistry of solutions, nuclear chemistry, motion, forces, Newton's Laws of Motion, work and machines, energy, waves, sound, electromagnetic radiation, visible light, electricity, and magnetism.

This course was created by the Rethink Education Content Development Team. This course is aligned to the NC Standards for 6th Grade Science. 

This course was created by the Rethink Education Content Development Team. This course is aligned to the NC Standards for 6th Grade Science. 

This course was created by the Rethink Education Content Development Team and is aligned to the NC Standards for 6th Grade Science.

This article describes an indoor, game-type demonstration, incorporating physics (EM wave modulation), math (binary codes), space technology, and music to show how spacecraft put information into the radio signals they send back to Earth. The article was originally written for and published by the International Technology Education Association in its journal, The Technology Teacher. It is now archived on The Space Place Web site.

8th Grade Integrated Science textbook for the 2019-2020 school year. This textbook was developed to align to the Utah Science Core Curriculum. (Updated: May 29, 2019)

Sample Learning Goals
Make waves with water, sound, and light and see how they are related.
Design an experiment to measure the speed of the wave.
Create an interference pattern with two sources, and determine the ways to change the pattern.
Find points of constructive and destructive interference by eye and by using the detectors.
Put up a barrier to see how the waves move through one or two slits. What sort of pattern do the slits create? How can you change this pattern?
For light, predict the locations of the fringes that appear on the screen using d sin(θ) = mλ. Use the tape measure to verify your predictions.
Explain how the aperture geometry relates to the diffraction pattern.
Predict how changing the wavelength or aperture size affects the diffraction pattern.

Sample Learning Goals
Discuss wave properties using common vocabulary.
Predict the behavior of waves through varying medium and at reflective endpoints.

Sample Learning Goals
Make waves with water, sound, and light and see how they are related.
Discuss wave properties using common vocabulary.
Explain how changing the frequency and amplitude affects the characteristics of the wave.
Design an experiment to measure the speed of the wave.