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This comic addresses the question "What is color?" Using the Sun as an example, the comic discusses how visible light (white light) contains all the colors of the rainbow. It goes on to describe why our Sun is white, our sky is blue, and why sunsets... (View More) are red/orange. The discussion ends with a thought-question and provides further information on NASA missions and websites that address issues related to the Sun. The comic is illustrated mostly with NASA imagery and is part of the series Tales from Stanford Solar, featuring Camilla Corona and Colours O’Iris. The topic “What is Color?” was inspired by the 2014 Alan Alda Flame Challenge, an international competition asking scientists to communicate complex science in ways that would interest and enlighten an 11-year-old. (View Less)
Two comic characters, Camilla Corona, a rubber chicken, and Colours O'IRIS, a peacock, explore spectrographs. This comic is part of the series Tales from Stanford Solar.
This set of physics-based labs uses data from NASA's Solar Dynamics Observatory spacecraft. Students create movies using near-real-time data, explore the connection between solar activity and space weather, use different types of data to generate... (View More) and test hypotheses, and collaborate with other students to explore further. Students present their results in a scientifically-appropriate manner. (View Less)
This series of laboratory lessons and activities uses authentic solar imagery and data to introduce students to solar science. Students are asked to explore details in imagery, including how to deal with the issues of noise and resolution, and... (View More) understand scale. They are introduced to the concept of space weather and how that affects both observing instruments and the Earth. Students learn about spectra, how helium and coronium were discovered, and go on to explore real spectra from the Sun. Most activities are mathematically based, and targeted for grades 9-10. Imagery is included from NASA/ESA's SOHO mission, NASA's SDO mission, and Japan's Hinode satellite. (View Less)
This is an activity about electromagnetism and the Sun. First, learners will do a KWL activity using six vocabulary words. Next, they will build an electromagnet and investigate how it works. Finally, learners will relate the workings of their... (View More) electromagnet to a Solar Dynamics Observatory magnetogram image of the Sun. Per group of learners, this activity requires materials such as a length of insulated wire, alligator clips, a 2-D-battery holder, two D-batteries, and a nail. (View Less)
This is a lithograph about NASA's Magnetospheric Multiscale Mission, or MMS. Learners will cut out and assemble a colorful 3D model of an MMS spacecraft. Web links, additional facts, and QR codes are included for audiences to access more information.
This is an activity about Earth's magnetic field. Learners will construct a soda bottle magnetometer, collect data, and analyze the results to detect magnetic storm events. Ideally, learners should collect data for at least a month. If several... (View More) months are available for data collection, this is ideal. This is the first activity as part of the iMAGiNETICspace: Where Imagination, Magnetism, and Space Collide educator's guide. Instructions for downloading the iBook educator's guide and the associated Transmedia book student guide are available at the resource link. (View Less)
This is a promotional folder for Sun-Earth Days 2013, containing images and illustrations of the Sun and its effects on the Solar System. Also included is information about the period known as solar maximum, as well as links to Sun-Earth Day... (View More) resources and the Space Weather Action Center. (View Less)
This is an activity about color. Participants will use scientific practices to investigate answers to questions involving the color of the sky, sunsets, the Sun, and oceans. This activity requires use of a clear acrylic or glass container to hold... (View More) water, a strong flashlight, batteries for the flashlight, and powdered creamer or milk. (View Less)
This is a set of instructions for building a physical model. The model simulates the Sun's paths across the sky at summer solstice, winter solstice, and the spring and fall equinoxes. A bead simulates the Sun, moving along a cord, from rising along... (View More) the eastern horizon to setting on the western. The bead can be moved from path to path to demonstrate solar alignments, the solstices, and equinoxes. The model is created to be unique to the user's latitude, and is useful for including in lessons that teach about the seasons or archaeoastronomy. (View Less)