This is a student-centered activity for a synchronous online course where students access google slides to complete during a video conferencing session (eg. Zoom) in break out rooms. Students will be introduced to plate tectonics through a series of scaffolded mini activities which includes: active learning jigsaws, group research and presentations, and assessments. Students will familiarize themselves with types of plate boundaries as well as features found at plate boundaries using the Jules Verne Voyager Jr. website, and will use GPS data to visualize direction and speed of plate motion. Additional activities suggested include using Google Earth to visualize plate boundaries, drawing a transect across a plate boundary, and calculating the rate of plate motion using the Hawaiian Islands.

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In this lesson, the teacher will demonstrate how to use the Pythagorean Theorem to find distance between two points in the coordinate system. In the coordinate plane, the difference in the x- and y-values will determine the numbers to calculate the distance. This lesson will use online graphing tools as well as graph paper to plot the points. This lesson can also be used to show the relationship between the distance formula and the Pythagorean Theorem. This lesson results from the ALEX Resource Gap Project.

Docs Teach is the online tool for teaching with documents, from the National Archives.
* Choose from thousands of primary sources for use in classroom activities.
* Find and use activities crafted by educators using documents from the National Archives.
* Create your own interactive learning activities.

Collection of Driver's Education resources from the State of Colorado. Resources include Driving Schools and Testers, Map of Schools and Testers, Motorcycle Schools and Testers, Commercial Driver Testers Map, Log Sheets, Safety Training, an Interactive Practice Quiz. Additional links are provided for the most current Driver Handbook, for students and parents. Written, Video and Audio versions are provided as well as materials in Spanish.

The DMT Clearinghouse is a registry for online learning resources about research data management. Initial seed funding was provided by the U.S. Geological Survey's Community for Data Integration. Subsequent funding has been granted by an Institute of Museum and Library Services National Leadership Grant (LG-70-18-0092-18). Developed in collaboration with the Earth Sciences Information Partnership (ESIP) Federation, and DataONE, with subsequent support from the University of New Mexico Libraries Research Data Services, the DMT Clearinghouse is available for searching, browsing, and submitting information about learning resources on data management topics. DMT Clearinghouse FeaturesThe Search Interface allows users to find learning resources by entering terms, names of people and organizations, dates, and keywords. The Browse Interface allows users to view the entire list of learning resources, and to filter by educational framework. An educational framework is a plan or set of steps that defines or collects the content using clear, definable standards about what the student should know and understand. For purposes of the DMT Clearinghouse, a given learning resource may be associated with a community-defined standard for data management, for example:USGS Science Support FrameworkDataONE Data Life CycleESIP Data Management Short Course for Scientists The Digital Preservation NetworkInternational Council for Science (ICSU) World Data System (WDS) Training Resource GuideFAIR Data Principles The Submission Form allows users to enter information about learning resources that they would like to see included in the DMT Clearinghouse. A user log in is not required to submit a resource with key, required information. To add more information about a learning resource than just that required, please log in or create an account (click "Log In at the upper right side of the screen.) NOTE: Submissions will be published to the DMT Clearinghouse following an editorial review to ensure the resource meets quality and selection criteria for inclusion.. You may be contacted for more information about your submission, if needed. Your contact information will not be made available publicly without your permission. For questions or feedback, please contact clearinghouseEd@esipfed.org.

DATA: Ocean Buoy Data, MODIS Images TOOLS: GoMOOS Online Graphing Tool SUMMARY: Learn about conditions that influence the spring phytoplankton bloom. Use an online graphing tool to predict the date of the bloom.

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Free online Earth and Space Science Textbook by Jeffrey Bennett. Jeffrey Bennett holds a B.A. in Biophysics from the University of California at San Diego and an M.S. and Ph.D. in Astrophysics from the University of Colorado at Boulder. He specializes in mathematics and science education, writing for and speaking to audiences ranging from elementary school children to college faculty. He is a well known author of science textbooks and children's books. Promo: Are you satisfied with your textbook for Earth and Space Science? We didn’t think so. Now,
imagine an online “textbook” that
• contains everything you need to teach your course, including activities and assessments, and
resources to help you meet the needs of students with varying levels of background.
• meets all your state and NGSS standards for middle school Earth and Space Science, and can
also be used for many high school courses.
• is fully up-to-date with the latest science, all presented in an engaging and scientifically
accurate manner.
• is designed for a course that is “teacher driven” and that can be used in person, online, or
even for independent learning.
• is filled with extensive Teacher Notes that will help you both to effectively engage your
students and to understand subtleties of the science for yourself.
• is written by the award-winning author of college textbooks in four subjects (astronomy,
astrobiology, mathematics, and statistics) and of numerous science books for the public,
including 6 children’s books that have all been read from orbit on the International Space
Station for the Story Time From Space Program
• and it is completely FREE, posted to a web site online.
Now you can stop imagining, because this “textbook” is here and ready for you to use!
Explore it at www.grade8science.com, use it with your students, and share it with
others. You may send feedback direct to the author at jeff@bigkidscience.com.

In this activity, students explore of the concept of probability and the distribution of earthquake sizes, and then work to understand how earthquake hazards are described by probabilities. Students then work in small groups to collect and analyze data from a simple physical earthquake model and use online data to investigate and compare the earthquake hazards in California and Missouri. The activity concludes with a reflection where they students are asked to consider how, in the role of a city planner or emergency manager, they would use what they have learned to mitigate the earthquake hazard in California and Missouri.

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Earthquake location is an interesting and significant aspect of seismology. Locating earthquakes is necessary for compiling useful seismicity information, calculating magnitudes, and study of fault zones, Earth structure and the earthquake process. Methods of earthquake location involve understanding of seismic waves, wave propagation, interpretation of seismograms, Earth velocity structure, triangulation, and the concepts (and mathematics) of inverse problems. Because earthquake location can be approached with relatively simple to very complex methods, it can be included in various levels of educational curricula and for "in-depth" study. Progressively developing a deep understanding of concepts, computational techniques and applications (and the capabilities, limitations and uncertainties of these applications) is a characteristic of science and an -- opportunity to "learn science by doing science." A number of methods that vary from simple to complex are available for learning about earthquake location. The methods also allow connections to other important concepts in seismology and provide a variety of approaches that address different learning styles and can be used for reinforcement and assessment.
Uses online and/or real-time data
Has minimal/no quantitative component

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Students learn about factors that engineers take into consideration when designing buildings for earthquake-prone regions. Using online resources and simulations available through the Earthquakes Living Lab, students explore the consequences of subsurface ground type and building height on seismic destruction. Working in pairs, students think like engineers to apply what they have learned to sketches of their own building designs intended to withstand strong-magnitude earthquakes. A worksheet serves as a student guide for the activity.

Students learn what causes earthquakes, how we measure and locate them, and their effects and consequences. Through the online Earthquakes Living Lab, student pairs explore various types of seismic waves and the differences between shear waves and compressional waves. They conduct research using the portion of the living lab that focuses primarily on the instruments, methods and data used to measure and locate earthquakes. Using real-time U.S. Geological Survey (USGS) data accessed through the living lab interface, students locate where earthquakes are occurring and how frequently. Students propose questions and analyze the real-world seismic data to find answers and form conclusions. They are asked to think critically about why earthquakes occur and how knowledge about earthquakes can be helpful to engineers. A worksheet serves as a student guide for the activity.

Individual project designed to combine basic oceanographic concepts in the creation of a travel brochure. Involves some group interaction, but project is individual. Can be done online or in a face-to-face class.
Best completed at midterm or later in the semester so that most concepts have been introduced.

LEARNING OUTCOMES

Describe major oceanic processes and evaluate their influence on the coastal environment.
2Use global data on climate and wind patterns to quantify and describe conditions at various specific coastal sites.

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Our standard of living depends on the pace of economic growth. That pace can be enhanced through increased productivity brought about by investment in physical and human capital and advances in technology. In this course, students will learn about these tools to increase productivity and advance our standard of living.

This guide is meant to help teachers utilize technology in the classroom while protecting their students’ privacy.

Technology tools and apps are making it possible for educators and students to collaborate, create, and share ideas more easily than ever. When schools use technology, students’ data—including some personal information—is collected both by educators and often the companies that provide apps and online services. Educators use some of this data to inform their instructional practice and get to know their students better. It is just as essential for educators to protect their students as it is to help them learn.

Young children are not likely to think past their piggy banks when it comes to safe places to set money aside for those special items. In this short course from our Ella's Adventures series, your students will learn that a bank account offers security and a return on their savings.

Experiential learning, yes! But...online? at a distance? independent undergraduate research? This capstone course in Energy and Sustainability Policy is a novel approach to exactly this. Each student follows the same overarching structure: a four-part written research report, weekly journals, group discussions, a LinkedIn presence, an in-person presentation and a video submission. Along the way, the student has numerous personal interactions with real world stakeholders and gives an in-person presentation to an interested local audience. Proven over many semesters now, this engaged scholarship model serves senior students well, guiding and building confidence and professional opportunities.

L’apprentissage par le jeu préconise des activités centrées sur les apprenants leur permettant d’explorer, d’échouer et de relever des défis dans un environnement sécuritaire. Il permet également de favoriser l’autonomie des étudiants au sein d’univers créés par les professeurs. De plus, les jeux sont de nature à renforcer l’engagement des étudiants dans le processus d’apprentissage. Dans le contexte éducatif, ces traits caractéristiques et ses qualités peuvent grandement favoriser l’engagement, la motivation et l’apprentissage des étudiants. Un panel interdisciplinaire d’experts propose des recettes pour intégrer différents types d’activités d’apprentissage par le jeu dans le contexte de l’enseignement en ligne. Une gamme d’activités vous sera proposée : du quiz jusqu’aux jeux d’évasion en passant par les jeux coopératifs ou encore les mots-croisés.

Increasingly volatile climate and weather; vulnerable drinking water supplies; shrinking wildlife habitats; widespread deforestation due to energy and food production. These are examples of environmental challenges that are of critical importance in our world, both in far away places and close to home, and are particularly well suited to inquiry using geographic information systems. In GEOG 487 you will explore topics like these and learn about data and spatial analysis techniques commonly employed in environmental applications. After taking this course you will be equipped with relevant analytical approaches and tools that you can readily apply to your own environmental contexts.

This is a field and computer laboratory exercise that introduces undergraduate students, advanced high school students, and members of the general public to using Google Earth, GPS, aerial imagery, and an online illustrated vegetation and tidal marsh environment identification guide to distinguish and map vegetational and physical environmental zones within a salt marsh. They also learn about the physical and ecological relationships between these environments.

Students use GPS devices to collect field data as waypoints and tracks, and upload the data to computers in GPX format. They learn to open the data in Google Earth along with infrared and color aerial imagery, and use the GPS data to interpret the aerial imagery. Using Google Earth tools, they draw polygons to demarcate the boundaries of environmental zones in the wetlands that they recognize on the imagery.

The students and instructors also take photographs of the students in each of these environmental zones and embed the photographs into information balloons of placemarks in Google Earth.

The exercise was originally designed for use at Flax Pond, a salt marsh on the North Shore of Long Island. However, it can easily be adapted for use in other tidal marshes, and can serve as a template for developing similar activities to be conducted at other locations in which aerial imagery can be used to distinguish various forms of land cover.

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Each issue of the free, online magazine Beyond Weather and the Water Cycle explores an essential principle of climate science and climate literacy with background information, lessons, activities, original stories, and more for the K-5 classroom. This article shows the alignment of these materials with the content standards of the National Science Education Standards.