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The MISSIONMaker program uses art and the making experience to investigate NASA mission design, engineering and space exploration. Using common materials, students build a rover that incorporates six simple machines. The building instructions... (View More) include design challenges, background information and examples of how NASA spacecraft incorporate and use those same simple machines. The lesson includes step-by-step instructions, templates, explanatory YouTube videos, and additional related resources. (View Less)
This multi-phased learning package progresses from guided engineering to an open mission-design challenge. Each step is scaffolded and includes easy-to-implement teaching tools, lessons and art activities. Learners, working in collaborative teams,... (View More) build an O-Rex spacecraft model. The building process incorporates inventing, designing and engineering- leading to a deeper understanding of NASA mission work. A leader guide, instructions, templates and a YouTube video are included and accessed through the Related & Supplemental Resources. (View Less)
Explore lunar phases as viewed from Earth using paper plates. While standing in the appropriate spot in the moon's orbit, students hold paper plates that depict the Moon's phase. This activity can be used to assess understanding of lunar phases or... (View More) to continue to build a conceptual model of the phases through kinesthetic activity. Related Next Generation Science Standards (NGSS) are listed. (View Less)
Materials Cost: 1 cent - $1 per group of students
Explore lunar phases as viewed from Earth using a golf ball and an ultraviolet light. With the student's head representing Earth, students hold and move the golf ball to demonstrate the cause of the Moon's phases in their correct order. Related Next... (View More) Generation Science Standards (NGSS) are listed. (View Less)
Materials Cost: $1 - $5 per group of students
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)
Students use the research topic questions generated in the earlier lesson entitled, “Mars Image Analysis,” to refine testable questions and develop hypotheses. The lesson is part of the Mars Education Program series; it models scientific inquiry... (View More) using the 5E instructional model and includes teacher notes and vocabulary. Next Generation Science Standards are listed. (View Less)
The effects of gravity on near-surface objects and those in Earth orbit are explored in this activity. A brief explanation, links to three related videos, a teacher's guide and short assessment are included.
This activity demonstrates optical properties of water: that different constituents in water affect the transmission, absorption, and scattering of different colors in the visible light spectrum. Inexpensive, off-the-shelf components are used to... (View More) build a light sensor and source, creating a simple spectrophotometer that can measure light absorption. In the second part of this activity, principles of ocean color remote sensing are applied to measure reflectance. Using components that are clearly visible allows students to configure them in different ways. Playing with the instrument design gives students a practical understanding of spectrophotometers, in-water optics, and remote sensing. As an extension of this concept, students are encouraged to think about how ocean color is used to estimate the concentration of chlorophyll to infer phytoplankton abundance, colored dissolved organic matter, and suspended sediments. (View Less)
This is an online lesson associated with activities during Solar Week, a twice-yearly event in March and October during which classrooms are able to interact with scientists studying the Sun. Outside of Solar Week, information, activities, and... (View More) resources are archived and available online at any time. This is an activity about measurements of solar activity. Learners will observe an image of the Sun and sketch major features, plot data to begin to recognize patterns of solar activity, look for long-term patterns in graphed data, compare X-ray and visible light images of the Sun to find solar features common to both sets of images, and make a prediction of what the Sun will look like in a visible light image after observing an X-ray image taken on the same day. This activity is scheduled to occur during Monday of Solar Week. (View Less)
In this activity, students create a scale model depicting the vertical distance from Earth’s surface to various features and objects, including Earth’s atmospheric layers, the Van Allen Radiation Belts, and geocentric satellites. Students also... (View More) compare the vertical distances to these features and objects with distances from their classroom to other common points on the ground. Includes background science information; student reading, handouts and worksheet; teacher information; and suggested extensions and adaptations for students with vision impairment. (View Less)