Students build a 9 M X 9 M model of an animal or plant cell with cell organelles inside it and give cell tours to Life Science students. May be done as two large groups, or a whole class project.

Both of these lessons are classroom activities that require students to build models that display understanding of atoms and molecules. One lesson is structured while the other is guided.

This lecture/activity on force will further a students' understanding of forces on an object, as well as the difference between a balanced and unbalanced forces.

In this project, students interpret a high-resolution image of result from an experimental run of the Jurrasic Tank sedimentation simulator at the St. Anthony Falls Lab at the University of Minnesota. They are expected to interpret depositional environments, characterize simulated stratigraphic sections, and interpret the overall sedimentary architecture of the simulated basin. All of these observations are to put together onto a poster which is the final product of the project.

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This activity is designed to help students understand the structures and functions of the cell by building a model.

This activity allows the student to access a webpage that provides examples of stoichiometry using terminology and objects they use in their everyday life. This activity can help a student make a connection between the complex chemical concept of stoichiometry and their current knowledge.

Students use a JAVA interface design by R.M. MacKay to explore the Daisy World model. The JAVA interface comes with a link to a 6-page student activity page in PDF format.

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After constructing a Stella model of Daisyworld students perform guided experiments to explore the behavior of Daisyworld to changes in model parameters and assumptions.

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Students will make "earthquakes" using a simple model, the earthquake machine. It is patterned on the EQ machine described by Ross Stein, Michelle Hall-Wallace, and others. References are given below. We have added force and distance sensors to the machine, and linked them (via GOLINKS) to new new software, that allows students to graph and analyze their data. All SW will be freely available. Students will evaluate the hypothesis that although earthquake patterns can be observed, the exact time and size of an earthquake cannot be predicted. Students then apply these insights to predicting earthquakes on the San Andreas fault, and estimating the magnitude of earthquakes on ancient faults in the region.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

Students explore a Global Energy Balance Climate Model Using Stella II. Response of surface temperature to variations in solar input, atmospheric and surface albedo, atmospheric water vapor and carbon dioxide, volcanic eruptions, and mixed layer ocean depth. Climate feedbacks such as water vapor or ice-albedo can be turned on or off.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

To complete this activity, students can follow the instructions and the tutorial in the Environmental Health Risk Inventory website. In doing this, they will gain an understanding of how to use on-line tools and databases as well as the processes of compiling an environmental health risk inventory for a specific locale. In the activity, students will address the question: "how healthy is your neighborhood?" Students will address anthropogenic and naturally-occurring health risks in their hometown or neighborhood by using data collected from online mapping tools and databases. Students will also complete a reflective summary based on the data that they collect.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

In this out of class tutorial, students explore several examples of natural selection and speciation.

In this exercise, students process LiDAR data for the Hamilton College campus area to determine accurate elevations of wellheads of sampling wells on campus. Students use both GPS readings and orthophotos to determine wellhead locations and combine those with water levels, casing heights, and wellhead elevations to interpolate a groundwater surface under the campus and portray the groundwater in ArcScene. They also learn how to use Model Builder. You might also be interested in our Full GIS course with links to all assignments. You might also be interested in our webinar for the NYS GIS Association on A Simple Example of Working with LiDAR using ArcGIS and 3D Analyst.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

In this exercise, students use both polyhedral model kits designed by the University of Wisconsin at Madison Materials Research Science and Engineering Center (MRSEC) Institute for Chemical Education and computer visualization in Jmol to explore the structures of a variety of phyllosilicate minerals, and relate those structures to physical properties. Students work in small groups to build either a sequence of dioctahedral or trioctahedral minerals and answer a series of questions about structure, arrangement, coordination and bonding. The small dioctahedral and trioctahedral groups combine to compare structures and discuss additional questions about these and other minerals.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

This lab activity is designed to have students use their knowledge of balancing and identifying chemcial reactions and apply it in a fun and interesting way!

There are 1 billion (1,000,000,000) nanometers in a meter. In this classroom activity students will gain an understanding of what that statement means.

This activity is a project in which students research keystone species and report on specific species to the class.

Students will understand that projectile motion is a result of two independent motions, horizontal and vertical by reading, problem-solving, and experimentation.