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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)
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)
Using an online interactive platform, learners will explore our solar system from the perspective of the Sun. They will observe the motion of different worlds to determine their location in the solar system. Then they will launch probes to search... (View More) these small worlds (bodies in the solar system not classified as a planet or a moon) for the caches hidden on them in order to collect the astrocoins inside. A 5E instructional lesson allows students to analyze a model to locate small worlds, define speed/distance relationships, and identify model limitations. Images, worksheets and a rubric are included. Instructional objectives and learning outcomes are aligned with Next Generation Science Standards (NGSS); the NRC Framework for K-12 Science Education; Common Core State Standards for English Language Arts; and A Framework for 21st Century Learning. (View Less)
This afterschool curriculum includes six lessons plus supplementary materials (e.g., videos, PowerPoint presentations, and images) that explore how light from the electromagnetic spectrum is used as a tool for learning about the Sun. The curriculum... (View More) is designed to be flexible to meet the needs of afterschool programs and includes recommendations for partial implementation based on time constraints. It was specifically designed to engage girls in science. (View Less)
NuSTAR has a 10-meter rigid mast that separates the optics from the detector. Inspired by this, students will design, test, and build a lightweight mast 1 meter tall that can fully support the weight of a typical hardcover textbook (~2 kg). The... (View More) footprint of the mast must be no larger than 11" x 14". This activity is from the NuSTAR Educators Guide: X-Rays on Earth and from Space, which focuses on the science and engineering design of NASA's NuSTAR mission. The guide includes a standards matrix, assessment rubrics, instructor background materials, and student handouts. (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 is the first module in the Solar Dynamic Observatory (SDO) Project Suite curriculum. Activities are self-directed by students or student teams using online videos and data from the SDO satellite to explore, research and build knowledge about... (View More) features of the Sun. Students build vocabulary, apply or demonstrate learning through real world connections, and creating resources to use in their investigations. Each activity comes with both a teacher and student guide with sequential instructions and embedded links to the needed videos and internet resources. Activity 1A: Structure of the Earth's Star takes students through the features and function of the Sun's structures using online videos, completing a "Sun Primer" data sheet using information from the videos, and creating a 3D origami model of the Sun. Students use a KWL chart to track what they have learned. Activity 1B: Observing the Sun has students capture real solar images from SDO data to find and record sunspots and track their movement across the surface of the Sun. Activity 1C has students create a pin-hole camera to use in calculating the actual diameter of the Sun, and then calculate scales to create a Earth-Sun scale model. Students reflect on their learning and results at the end of the module. An internet connection and access to computers are needed to complete this module. See related and supplementary resources for link to full curriculum. The appendix includes an alignment to the Next Generation Science Standards (NGSS). (View Less)