In this activity, learners work in teams to assess environmental conditions, resources, …
In this activity, learners work in teams to assess environmental conditions, resources, and scientific relevance of different locations on the Moon using data collected from previous lunar missions. Each team selects the site they believe has the best potential for a future lunar outpost. The teams debate their conclusions and work together to determine which single site to recommend to NASA. This activity takes approximately 1.5 hours, and can be divided into parts. Learners should be familiar with NASA's LRO Mission and the lunar environment through other Explore! To the Moon and Beyond! activities. These activities were developed specifically for use in libraries.
In this online card game, players prepare five important NASA Earth missions. …
In this online card game, players prepare five important NASA Earth missions. The object of the game is to be the first to complete three of five missions. A mission is completed when all four of its required components have been supplied. Each mission needs a rocket, an orbit, a spacecraft, and a science objective. There are different kinds of each of these components; each mission needs a different combination of the components. The game is based on real NASA Earth missions: Aqua, Aura, CloudSat, IceSat, and Terra.
In this activity, student teams design small-scale physical models of hot and …
In this activity, student teams design small-scale physical models of hot and cold planets, (Venus and Mars), and learn that small scale models allow researchers to determine how much larger systems function. There is both a team challenge and competition built into this activity. Experimental findings are then used to support a discussion of human outposts on Mars. The resource includes an experimental design guide for students as well as a handout outlining a method for the design of controlled experiments, and student data sheets. Student questions and an essay assignment are provided as classroom assessments. This is Activity A in the second module, titled "Modeling hot and cold planets," of the resource, "Earth Climate Course: What Determines a Planet's Climate?" The course aims to help students to develop an understanding of our environment as a system of human and natural processes that result in changes that occur over various space and time scales.
In this activity, students pose several hypotheses for what will happen if …
In this activity, students pose several hypotheses for what will happen if you continue heating or supplying energy to the hot and cold planet models (Mercury, Mars, Venus, and Earth) and then test their hypotheses using a spreadsheet based radiation balance model. The activity supports investigation of a real world challenge, experimenting with life support conditions for Mars at an Arctic outpost. The interactive model runs are conducted using a Java applet. This resource includes student worksheets, assessment questions and a teacher's guide. This is Activity B in module 2, Modeling hot and cold planets, of the resource, Earth Climate Course: What Determines a Planet's Climate? The course aims to help students to develop an understanding of our environment as a system of human and natural processes that result in changes that occur over various space and time scales.
In this activity, students explore the importance of adequate sampling strategies when …
In this activity, students explore the importance of adequate sampling strategies when conducting a scientific investigation. They are tasked with determining the average temperature of the Earth, using data sets easily found on the Internet, and determine the kind and size of sample necessary to calculate a representative average. The resource includes a student data sheet and an authentic assessment for the module, where students discuss the establishment of a habitation site on Mars. This is Activity C in module 2, titled "Modeling Hot and Cold Planets," of the resource, Earth Climate Course: What Determines a Planet's Climate? The course aims to help students to develop an understanding of our environment as a system of human and natural processes that result in changes that occur over various space and time scales.
In this activity, students use rulers to measure distances between hypothetical galaxies …
In this activity, students use rulers to measure distances between hypothetical galaxies and then use these distances to calculate the velocities of the galaxies. This activity is part of the "Cosmic Questions" educator's guide that was developed to support the Cosmic Questions exhibit. This activity can be in conjunction with, or independently of, the exhibit.
The purpose of this kinesthetic activity is for students to learn the …
The purpose of this kinesthetic activity is for students to learn the relative motions of the Earth, Sun and Moon. Awareness of these different motions is needed to develop an understanding of the causes of the day/night cycle, the seasons and the cycle of lunar phases. This resource is from PUMAS - Practical Uses of Math and Science - a collection of brief examples created by scientists and engineers showing how math and science topics taught in K-12 classes have real world applications.
In this activity students are challenged to create a model of the …
In this activity students are challenged to create a model of the universe in a single class period. This activity is designed to elicit student ideas and preconceptions about the contents and organization of the cosmos. Most students will be somewhat familiar with solar system objects, but may be confused about the relationship of stars to planets, and about their relative distances. This activity is part of the "Cosmic Questions Educator's Guide" developed to support the Cosmic Questions exhibit. The activites in the guide can be used in conjunction with or independently of the exhibit.
This is an activity about the lunar cycle and the pattern of …
This is an activity about the lunar cycle and the pattern of the moon‰Ûªs motion in our sky. Learners will use the Sky Tonight online program to observe the different phases of a lunar month and predict where the moon will be in the night sky throughout the month. This activity requires the use of a computer with Internet access, and is Sky Tonight Activity 4 in a larger resource, Space Update.
In this activity, students compute the strengths of the gravitational forces exerted …
In this activity, students compute the strengths of the gravitational forces exerted on the Moon by the Sun and by the Earth, and demonstrate the actual shape of the Moon's orbit around the Sun. The lesson begins with students' assumptions about the motions of the Moon about the Earth and the Earth about the Sun, and then test their understanding using an experimental apparatus made from a cardboard or plywood disk and rope. This resource is from PUMAS - Practical Uses of Math and Science - a collection of brief examples created by scientists and engineers showing how math and science topics taught in K-12 classes have real world applications.
This is an activity about the phases of the moon. Learners will …
This is an activity about the phases of the moon. Learners will view and identify images of the different phases and measure the moon's size in each. This activity is Astronomy Activity 5 in a larger resource, Space Update.
Learners will work in teams to apply their knowledge about the Moon, …
Learners will work in teams to apply their knowledge about the Moon, its environment, and the LRO mission to match responses to Moon questions. With the correct responses, they build a picture of the Moon. This activity is part of Explore! To the Moon and Beyond! - a resource developed specifically for use in libraries.
This is a lesson about NASA's Lunar Reconnaissance Orbiter (LRO). Learners will …
This is a lesson about NASA's Lunar Reconnaissance Orbiter (LRO). Learners will sing about the LRO mission to the Moon, learn that craters on the Moon may harbor water ice, and they discover how LRO is searching for this and other resources needed to build future lunar outposts. This is a good introductory activity. This activity is part of Explore! To the Moon and Beyond! - a resource developed specifically for use in libraries.
This is an activity about gravity. Learners will design their own experiments …
This is an activity about gravity. Learners will design their own experiments to explore the fundamental force of gravity and then extend their thinking to how gravity acts to keep objects like moons and ring particles in orbit. They use the contexts of the solar system and the Saturn system to explore the nature of orbits. The lesson enables students to correct common misconceptions about gravity and orbits and to learn how orbital speed decreases as the distance from the object being orbited increases. This is lesson 3 of 6 in the Saturn Educators Guide.
This module focuses on the population of mountain gorillas living in the …
This module focuses on the population of mountain gorillas living in the central highland area of Africa. The module looks at human activity around the gorilla habitat and how that activity is threatening the survival of the remaining gorillas.
In this activity, students learn about the changing configuration of the continents …
In this activity, students learn about the changing configuration of the continents over geological time resulting from plate tectonics. Using a map pair, students measure the difference in distance between continents 94 million years ago and today, and calculate the speed at which the plates have moved. The resource includes the images and a student worksheet. This is an activity from Space Update, a collection of resources and activities provided to teach about Earth and space. Summary background information, data and images supporting the activity are available on the Earth Update data site.
This is a set of three, one-page problems about mass and power …
This is a set of three, one-page problems about mass and power of spacecraft. Learners will use multi-step equations to solve several diverse problems. Options are presented so that students may learn about different types of power systems to generate electricity through a NASA press release or by viewing a NASA eClips video [7 min.]. This activity is part of the Space Math multi-media modules that integrate NASA press releases, NASA archival video, and mathematics problems targeted at specific math standards commonly encountered in middle school.
In this activity, students explore images taken with telescopes sensitive to several …
In this activity, students explore images taken with telescopes sensitive to several different wavelengths of the electromagnetic spectrum. Students compare the images to determine that light carries information about physical features in the universe. Students also determine that, because light of different wavelengths comes from different physical sources, combining multiwavelength views helps astronomers develop a more complete picture of the universe and the objects in it. This activity is one of several in the "Cosmic Questions Educator's Guide," a guide developed to support the Cosmic Questions exhibit. The activities in the guide can be used either in conjunction with or independently of the exhibit.
In this activity students construct multiplying slide rules scaled in Base-10 exponents …
In this activity students construct multiplying slide rules scaled in Base-10 exponents and use them to calculate products and quotients. They will come to appreciate that super numbers (exponents, orders of magnitude and logarithms) play by different rules of arithmetic than ordinary numbers (numbers, powers of ten and antilogs).åÊåÊThis is activity A2 in the "Far Out Math" educator's guide. Lessons in the guide include activities in which students measure,compare quantities as orders of magnitude, become familiar with scientific notation, and develop an understanding of exponents and logarithms using examples from NASA's GLAST mission. These are skills needed to understand the very large and very small quantities characteristic of astronomical observations. Note: In 2008, GLAST was renamed Fermi, for the physicist Enrico Fermi.
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