The Florida River Project is a semester-long project involving (1) an individual project in which students pose a scientific question and use existing data to test their hypothesis, and (2) a group project in which students collect and present data associated with stream monitoring.

Outcomes of the individual project include:
- Practice applying the process of science
- Graphing and interpreting data
- Making an argument supported by quantitative evidence.
- Communicating a scientific argument in writing.
- Supporting a scientific argument using appropriate formats (especially graphs and tables)

Outcomes of the group project include:
- Collecting field data (discharge, sediment load, water chemistry)
- Presenting data orally.
- Discussing preliminary interpretations of data.

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This activity is a field investigation where students make observations, formulate a question, construct and collect data on that question on stream flow on the Crow River in Central Minnesota

The lab starts with a short lecture on the scientific method, after which students observe the results of a flume run that includes skeletal clasts. They form hypotheses about how bone clasts (or any clast for that matter) move and are deposited by a flow, then the students test their hypotheses by running a flume trial. The hypothesis tests take place in small groups (3-5 students), and the lab ends with homework where students use the information they learned from their hypothesis tests to interpret a fossil assemblage. As such, this is a wonderful activity for introductory geology classes, could be used effectively with minor adjustments for advanced paleontology, taphonomy, and forensic physical anthropology classes.

Short Description:
Drawing upon the food security literature and current events in the media, this survey course will encourage learners to build a new understanding of food security, water shortages in agricultural production, and climate change challenges in agriculture. We will introduce policy tools and case studies illustrating the effects that climate change has on agriculture which will be useful and applicable to individual cross-disciplinary learning.

Long Description:
Food security is one of the most pressing dilemmas of our time. Around the globe, approximately 2 billion people experience some form of food deprivation each day. One in ten people suffer from some form of food insecurity in Canada. This has led scholars to question why food insecurity exists in an ostensibly food secure country. The literature on food security and climate change has also grown exponentially over the past several decades in large part as a response to world events such as the Green Revolution and other forms of industrial agricultural development since the 1970s. Despite the advances in research and technology, we still possess inadequate knowledge of the dynamics causing the onset of food insecurity, and significant disagreement persists among scholars concerning the best way to ameliorate food insecurity.

Drawing upon the food security literature and current events in the media, this survey course will encourage learners to build a new understanding of food security, water shortages in agricultural production, and climate change challenges in agriculture. We will introduce policy tools and case studies illustrating the effects that climate change has on agriculture which will be useful and applicable to individual cross-disciplinary learning.

This course is part of the Adaptation Learning Network led by the Resilience by Design Lab at Royal Roads University. The project is supported by the Climate Action Secretariat of the BC Ministry of Environment & Climate Change Strategy and Natural Resources Canada through its Building Regional Adaptation Capacity and Expertise (BRACE) program. The BRACE program works with Canadian provinces to support training activities that help build skills and expertise on climate adaptation and resilience.

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Between 70 and 75% of the Earth's surface is covered with water and there exists still more water in the atmosphere and underground in aquifers. In this lesson, students learn about water bodies on the planet Earth and their various uses and qualities. They will learn about several ways that engineers are working to maintain and conserve water sources. They will also think about their role in water conservation.

In this activity, students will use a tutorial on the U.S. Environmental Protection Agency's website to learn about how surface water is treated to make it safe to drink.

This is one component of the Source to Sink Mini Lesson Set
Continental margins are phenomenal places to study the modern sedimentary cycle because sediment in margin regions has been routed from mountains (source) through river systems to the sea (sink); in some cases, sediment has continued across continental shelves and been delivered to the deep sea. The goal of this mini-lesson is to let students explore the characteristics of some key regions in the modern sedimentary cycle to identify and relate the variables that control source-to-sink systems. Which areas are eroding most rapidly and why? Which systems are responsible for the most rapid transfer of sediments from continents to the oceans? How do the characteristics of river systems affect the properties of the sediments they discharge? How can we apply our knowledge of these modern source-to-sink systems to the ancient sedimentary rock record?

Students will learn about the water cycle, watersheds, and specifically, the watershed that feeds Springfield, Oregon. After analyzing drought maps, reading news reports, and seeing images and videos, students will realize that drought is a real life concern. Students, as concerned citizens, will create a water collection device, at first on a small scale, and then a true to life water collection system to help re- purpose rainwater in our garden area.

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This project is used instead of a final exam in an upper level undergraduate course in Applied GIS. A student may propose their own project, or choose one from a list from the instructor. A brief proposal must be approved by the instructor before the project can begin. Students will construct a working, query-able database, use appropriate imagery, and use it to analyze a problem, understand cause and effect, and show changes with time. A final report must be submitted with all supporting documentation in digital form. Students also give a PP presentation in one of the last class meetings.

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Students work with data bases and GIS to develop saturated thickness maps. Each data base consists of observations made by drillers where they have encountered the High Plains aquifer base and the annual water-level measurements taken in wells screened in the High Plains aquifer by field technicians.

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Focusing on air, water, land and life, this video describes how these components are connected in the Earth system through the flow of energy, cycles of water and biogeochemistry. Methods of studying the Earth system, ranging from field observations to analysis of satellite images are discussed. This video is one of the 24-part instructional video series describing scientific protocols used by GLOBE (Global Learning and Observation to Benefit the Environment), a worldwide, hands-on, K-12 school-based science education program.

This video highlights students taking scientific measurements to support investigations in atmospheric science, hydrology, soils, and land cover. It shows students reporting data through the Web, creating scientific visualizations for analysis, and collaborating with students and scientists around the world. This is one two introductory videos in the 24-part GLOBE video series. GLOBE (Global Learning and Observation to Benefit the Environment) is a worldwide, hands-on, K-12 school-based science education program.

During this activity, the instructor introduces a miniature watershed, named a GeoSandbox, to provide a conceptual bridge between the schema created in the soup can water budget activity and the schoolyard watershed activity to follow. Students introduce known quantities of water to the GeoSandbox using spray bottles and measure the resulting surface flow and infiltration. The concepts of topography and land use are also introduced. Additional instructional materials are provided to firmly establish the concept of a watershed for students who need the support.

This exercise posits a hypothetical situation: you would like to purchase land that will provide your family with opportunities to fish and swim in a stream on your property. Additionally, you would like the land to afford some privacy. In order to find such a place, you need to locate land for sale that has a stream running through it and you want to confirm that the stream water is clean. The following activity illustrates how one can locate land with particular characteristics and also assess surface water quality for local bodies of water. The data you will use might pertain to any location where streams flow through residential areas.

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Geography 431 is designed to further understanding of the natural processes of aquatic ecosystems, management of water resources, and threats to sustaining water quantity. Develop awareness and appreciation of the perspectives about water as a precious resource, commodity, and sometimes hazard. Learn how and why water is distributed unevenly around the Earth. Examine how resource management decisions are strongly related to water availability, quantity, and quality. The course examines water resources management; dams and dam removal; provision of safe potable water; threats to water quantity and quality; land use changes; the water economy; water laws and policy; institutions for water management at the global, national, regional, and local scale; and issues of water security and climate change.

This two-week long laboratory exercise examines the linkages between the endogenic (tectonic and isostatic) and exogenic processes that created the Eastern Snake River Plain (ESRP) landscape. The landform analysis portion of the exercise focuses upon recent basaltic volcanism and the Menan Buttes, the St. Anthony dunes and the fluvial drainage patterns that developed in the region.

This exercise takes advantage of student's interest in Google Earth to teach some basic concepts about meandering rivers. Students prepare for class by reading about lowland rivers and/or hearing a lecture on them. They bring their own laptops to class or share with a partner or I take the entire class to the computer lab next door. In class they work through the worksheet and use Google Earth to take quantitative measurements of the rivers. They look at historic migration of meander bends and quantify river sinuousity, wavelength, amplitude, and radius of curvature of meander bends. They explore meandering bedrock rivers in Taiwan as a cool thought exercise in how that can happen. They end with looking at images from an area that they will have a field trip to during their next lab period. To keep people from flying through the exercise and getting bored, we do the whole activity in think-pair-share style. Students work on a location, answer the questions, and then we discuss it as a class.

(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 video segment adapted from NOVA features the youngest rock formations in the Grand Canyon, lava dams, and how they are subject to the eroding power of water.

Students learn about water poverty and how water engineers can develop appropriate solutions to a problem that is plaguing nearly a sixth of the world's population. Students follow the engineering design process to design a gravity-fed water system. They choose between different system parameters such as pipe sizes, elevation differentials between entry and exit pipes, pipe lengths and tube locations to find a design that provides the maximum flow and minimum water turbidity (cloudiness) at the point of use. In this activity, students play the role of water engineers by designing and building model gravity-fed water systems, learning the key elements necessary for viable projects that help improve the lives people in developing communities.