You are here
Home ›Now showing results 1-10 of 15
Students analyze and interpret the accompanying large-format images of Mars taken by NASA’s Mars Thermal Emission Imaging System (THEMIS) camera. The analysis involves identifying geologic features, calibrating the size of those features, and... (View More) determining surface history. The lesson culminates in students conducting in-depth research on questions generated during their analyses. The lesson is part of the Mars Education Program series; it models scientific inquiry using the 5E instructional model and includes teacher notes and vocabulary. Next Generation Science Standards are listed. (View Less)
This lithograph outlines the components of our heliosphere, using current information released by the Interstellar Boundary Explorer, or IBEX, spacecraft team. Learners will view an illustration of our heliosphere on the front of the product, read... (View More) information about the heliosphere on the back, and then use the lithograph image itself as part of a model of the heliosphere that uses water to represent outflowing solar wind in an activity titled, "Model The Heliosphere Using Your Kitchen Sink." (View Less)
In this hands-on activity, students learn about the different realms of the Universe and explore their sizes and relative scales. They will be guided through a process that uncovers the immense sizes of the Sun, Solar System, Solar Neighborhood,... (View More) Milky Way, Local Group, Supercluster, and the observable Universe. The full version of this activity involves students doing simple math computations, however it can also be done without the math. There are some inexpensive materials involved, as well as a powerpoint presentation. It is intended for grades 8-12, but can be adapted down for lower grade levels. (View Less)
This 12-lesson unit includes inquiry-based lessons about the surface features of the Moon and the Earth and how these two worlds formed and continue to evolve. Students participate in real science as they help lunar scientists map the surface of the... (View More) Moon with MoonMappers, an online citizen science project that lets the public analyze real data from NASA's Lunar Reconnaissance Orbiter. The lessons in this unit follow the 5E instructional model. Includes an overview of citizen science, glossary of lunar feature vocabulary, alignment to NGSS and NSES, and featured links. Each of the lessons addresses different topics and can be used together as a unit, or independently. (View Less)
After creating a model of multiple volcanic lava flows, students analyze the layers, sequence the flows, and interpret the stratigraphy. Students use that same volcanic layering model to investigate relative dating and geologic mapping principles-... (View More) which they will then apply to satellite imagery. The lesson is part of the Mars Education Program series; it models scientific inquiry using the 5E instructional model and includes teacher notes and vocabulary. Next Generation Science Standards are listed. (View Less)
In this activity, students are introduced to light and colored gels (filters). Students make and test predictions about light and color using gels; learn about the importance of gels (filters) to astronomers; then analyze images taken with regular... (View More) and infrared cameras to see that objects opaque to light at one wavelength, may be transparent to light of a different wavelength. Section 1 of the activity guide includes teacher notes, information on materials and preparation, student misconceptions, and a student pre-test. Each activity section also includes teacher notes, student activity sheets, and answer keys. This activity is the first of four activities in Active Astronomy, which are designed to complement instruction on the electromagnetic spectrum, focusing on infrared light. (View Less)
In this activity, students build a photocell detector, and use it to detect different colors of light in a spectrum. Then they place the detector just outside the red region of the visible light spectrum and see that the detector detects the... (View More) presence of light there, even though there is no color visible. Students learn that invisible light exists and that we can detect this light with instruments other than our eyes. In a final part of the activity, students investigate the infrared signals emitted by TV and VCR remote controls. The activities build upon each other and are best taught in order. Section 1 of the activity guide includes teacher notes, information on materials and preparation, student misconceptions and a student pre-test. Each activity section also includes teacher notes, student activity sheets, and answer keys. This activity requires some special materials (e.g. a small solar cell, alligator clip leads, plus common classroom materials (e.g., overhead or slide projector). This activity is the second of four activities in Active Astronomy, which are designed to complement instruction on the electromagnetic spectrum, focusing on infrared light. (View Less)
In this activity, students learn that infrared light is reflected in the same manner as visible light. Students align a series of mirrors so that they can turn on a TV with a remote control when the remote is not in a direct line with the TV. As a... (View More) result of their experiment with reflection, students deduce that infrared light is another form of light and is a part of the electromagnetic spectrum. Section 1 of the activity guide includes teacher notes, information on materials and preparation, student misconceptions and a student pre-test. Each activity section also includes teacher notes, student activity sheets, and answer keys. This activity requires a TV and remote control. It is the third of four activities in Active Astronomy, which are designed to complement instruction on the electromagnetic spectrum, focusing on infrared light. (View Less)
In this activity, students learn that light carries information. Students also discover that infrared (IR) radiation is a form of light that in some cases behaves like visible light and in other cases behaves very differently. For example, some... (View More) objects that block visible light allow infrared light to pass through. This activity requires the use of both common classroom materials (e.g., laser pointer) and special materials (e.g., photocell). It is supported by teacher notes, information on materials and preparation, background information on student misconceptions, an activity sheet, an answer key, and a pre-assessment activity. This activity is the last of four activities in the "Active Astronomy" educator's guide. Activities in the guide are designed to complement instruction on the electromagnetic spectrum with a focus on infrared light. The activities build upon each other and are best taught in order. (View Less)
This is an activity exploring the concept that distance affects how we perceive an object's size, specifically pertaining to the size of the Sun and the Moon as seen from Earth. Learners will complete a hands on activity where two balls of differing... (View More) sizes stand in for the Sun and the Moon. By moving the balls away from each other, students will determine how far the larger ball needs to be in order to make the two seem similar in size. They will also use the balls to demonstrate a solar eclipse. Lastly, learners will complete a worksheet explaining their findings. This is Activity 12 of a larger resource entitled Eye on the Sky. (View Less)