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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 simulated remote sensing techniques to observe a clay model of a planet. Observations are done from the perspective of a telescope at Earth’s surface, a telescope above Earth’s atmosphere, and from closer proximity to the planet in a... (View More) fly-by, an orbit and a landing. This activity illustrates the integration between science, engineering, technology and teamwork. 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 lesson, students participate in a skit presenting a mock-up of a planetary surface rover they designed. Students will be able to: demonstrate their knowledge of Mars and rovers by presenting their team skit; present their rover, its... (View More) requirements and features to the class; answer questions asked by the class based on research conducted during the unit; incorporate feedback from others and ideas from other presentations into student work. The lesson plan has a number of appendices, including: standards alignment, essential question, and exit ticket. This is Lesson 15 of the middle school version of the 6-week Mars Rover Celebration curriculum. (View Less)
In this lesson, students will design a planetary surface rover to conduct a planetary surface investigation. It uses the 5E learning cycle and is designed around an essential question: How will creating a prototype of your rover help you prepare for... (View More) the Mars Rover Celebration? The lesson objectives are to: learn about scientific careers to gain a better understanding of a sampling of careers that have contributed to designing and developing Curiosity; draw a detailed, final-design sketch/diagram of the rover that will be built; identify missions, requirements and features of the rover using labels and captions when necessary. A number of appendices are provided, including standards alignment. This is Lesson 12 of the middle school version of the 6-week Mars Rover Celebration curriculum. (View Less)
This lesson plan uses the 5E learning cycle and is designed around an essential question: Why is the method you chose for landing your Rover on Mars the best one for your mission? The lesson objectives include: examine different methods for landing... (View More) rovers on Mars; determine which landing strategy is best suited to land the team's rover; research solutions to different problems that may occur once the rover lands on Mars; learn how to write in a persuasive manner; and present a well-written persuasive argument to teammates. The lesson plan has a number of appendices, including standards alignment. This is Lesson 10 of the middle school version of the 6-week Mars Rover Celebration curriculum. (View Less)
This lesson plan uses the 5E learning cycle and is designed around an essential question: How do I know when I've found important information in my reading? Learning objectives include: identify important details in informational texts; learn and or... (View More) review summarizing skills, work collaboratively to locate important information about Mars such as terrain, climate, and atmosphere; understand the rationale and importance of note-taking; develop effective note-taking strategies; and apply note-taking skills to record key information in students’ science notebooks. The lesson plan has a number of appendices, including standards alignment. This is Lesson 4 of the middle school version of the 6-week Mars Rover Celebration curriculum. (View Less)
Become a crime scene investigator! Learners model Dawn Mission scientists, engineers, and technologists and how they use instrumentation to detect distant worlds. After a briefing to build context, students explore interactions between different... (View More) frequencies/wavelengths of the electromagnetic spectrum and matter as they investigate the different ways scientists gather and understand remote sensing data, using Dawn instruments as examples. This module is organized around a learning cycle, engaging students through several experiences to activate students' prior knowledge and assess conceptual understanding, informing next steps. (View Less)
Students combine science and systems engineering to develop a mission to search for life in our solar system. The mission must meet budgetary, mass and power constraints while still producing significant science. An extensive set of "equipment... (View More) playing cards" determines all critical mission factors such as mass limit, cost, weight, scientific instruments, mobility, and all systems- including power, computer, communication, instrumentation, mechanical, as well as entry, descent and landing. The equipment cards, a design mat and student worksheets are included. 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. Next Generation Science Standards are listed. (View Less)
This activity allows participants to build a paper model of the GPM Core Observatory and learn about the technology the satellite uses to measure precipitation from space. Directions explain how to cut, fold and glue the individual pieces together... (View More) to make the model. The accompanying information sheet has details about the systems in the satellite including the Dual-frequency Precipitation Radar (DPR), the GPM Microwave Imager (GMI), the High Gain Antenna, avionics and star trackers, propulsion system and solar array, as well as a math connection and additional engineering challenges. (View Less)
Materials Cost: 1 cent - $1 per group of students
In this kinesthetic activity, students will demonstrate how two spacecraft are able to document a space weather event across the Van Allen radiation belts better than one spacecraft can. Students will graph the data collected by one spacecraft and... (View More) by two spacecraft during a space weather event; compare and contrast the graphical data from one spacecraft and from two spacecraft collected during a space weather event; and explain that space weather events can change from time-to-time and place-to-place across the Van Allen radiation belts, which is why it is helpful to observe them from two spacecraft simultaneously. Includes background science information, student handouts and data collection sheets, teacher answer key, and suggested extensions and adaptations for students with vision or hearing impairments. (View Less)