Students will identify water sources in the school environment in order to understand the origins of our water and to gain perspective about the students' place in the water cycle. Students will learn about the water cycle using a variety of resources and discover connections between the water cycle and the water that they use every day.

This module is focused on increasing the users understanding and familiarity with the fate and transport of contaminants. Video clips of sand tank models showing the movement of contaminants in subsurface porous media are included. The sand tank models provide a visual guide to help see how different geologic materials with different permeability's effect the movement of fluids and ultimately the distribution of contaminants.

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In a class demonstration, students observe a simple water cycle model to better understand its role in pollutant transport. This activity shows one way in which pollution is affected by the water cycle; it simulates a point source of pollution in a lake and the resulting environmental consequences.

The Next Generation Science Standards (NGSS)* call for students to use the practices, concepts and content of science and engineering to understand phenomena and solve problems that are relevant to their lives. Starting from a student’s own experiences and community makes the science meaningful and increases engagement while helping students understand how global issues like climate change are present and addressable in their lives. In this series we examine how you can use the new science standards and your community to understand and address real world environmental problems and explore together how to integrate NGSS into your district’s classroom science units.Would you like to learn more about how urban water systems actually work? Are you curious how water systems, the impacts of climate change, and related conservation issues can interest your students and integrate with NGSS? Join us to learn about wastewater and stormwater systems (may include tours of facilities, depending on the site) and then workshop how you might use this content in your classroom. Appropriate for all 4th-12th grade teachers.

Students analyze the natural disaster threat and potential mitigation techniques of their (family) home.

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Students apply their understanding of the natural water cycle and the urban "stormwater" water cycle, as well as the processes involved in both cycles to hypothesize how the flow of water is affected by altering precipitation. Student groups consider different precipitation scenarios based on both intensity and duration. Once hypotheses and specific experimental steps are developed, students use both a natural water cycle model and an urban water cycle model to test their hypotheses. To conclude, students explain their results, tapping their knowledge of both cycles and the importance of using models to predict water flow in civil and environmental engineering designs. The natural water cycle model is made in advance by the teacher, using simple supplies; a minor adjustment to the model easily turns it into the urban water cycle model.

Through an overview of the components of the hydrologic cycle and the important roles they play in the design of engineered systems, students' awareness of the world's limited fresh water resources is heightened. The hydrologic cycle affects everyone and is the single most critical component to life on Earth. Students examine in detail the water cycle components and phase transitions, and then learn how water moves through the human-made urban environment. This urban "stormwater" water cycle is influenced by the pervasive existence of impervious surfaces that limit the amount of infiltration, resulting in high levels of stormwater runoff, limited groundwater replenishment and reduced groundwater flow. Students show their understanding of the process by writing a description of the path of a water droplet through the urban water cycle, from the droplet's point of view. The lesson lays the groundwork for rest of the unit, so students can begin to think about what they might do to modify the urban "stormwater" water cycle so that it functions more like the natural water cycle. A PowerPoint® presentation and handout are provided.

Reduced flows and increased demand for Colorado River water represent a real and present danger in the West. To address the threat, water managers and modelers initiated a study to understand the system, consider options, and take action.

Background:
In my experience, I have discovered many common roadblocks to non-traditional and under-represented student participation in hydrogeology:
Time constraints -- many students have complicated schedules and demands on their time that a traditional undergraduate does not have. For example, many of these students are working full time, and required experiences outside of the classroom often pose scheduling conflicts for students.

Communication skills -- many under-represented students arrive in the classroom with communication skills that are not fully developed. Students are often learning English as they are learning the complex vocabulary of hydrogeology.

Math skills -- many students are under prepared in math and/or have math phobias

Funding -- many students are unable to pay laboratory and field trip fees.

I currently teach at minority serving institution. Here, I find that hands-on practice is the most successful learning experience for students. Students grasp concepts such as discharge, flux, and residence time more effectively when they are active participants in the learning process. The most effective method I have found for addressing these issues and encouraging under represented student participation in hydrogeology is to create student-designed group research projects. I used this strategy three quarters in a row, and the same students (as well as new students they recruit) continue to sign up for these courses. This trend, in addition to students' growing confidence in engaging in the scientific method, is my primary evidence for success.

Resources are very limited at my institution, so here are a couple of suggestions that work well.
Borrow equipment -- from other universities, from consulting companies, from colleagues.

Simplify analyses -- many interesting conclusions can be drawn from simply pH, conductivity, and temperature data. But, there are also relatively inexpensive test kits on the market that are sufficient for class purposes (ex. LaMotte urban water test kit ~$30).

Description
Everyone will have different class sizes, student preparation levels, and goals when attempting an exercise like this, so I will provide general information, which others can modify to meet their needs. Below I briefly outline the steps I take the students through during the project and highlight ideas for improving success for the targeted groups.

Form groups -- depending on class size, 2-4 students per group (I try to ensure the groups are balanced based on skills and student interests)
Choose topic -- I usually provide a list of possible topics and have students adapt a topic from the list that interests them. Students require a lot of guidance at this stage to assure selection of a manageable topic for a quarter-long project. This is the most important step - guiding students into a topic they are passionate about and where they can be successful is key. Students usually have no shortage of questions they want to answer about water in an urban environment! Since most of the students have spent their whole lives in an urban situation, they are deeply passionate about these issues.
Research literature -- students perform a background search for previous work on their topic to help guide them. I provide a laboratory session on how to search the library and databases for related information, as well as provide a list of recommended journals and websites. In addition, students locate supporting data (discharge, well levels, precipitation)
Plan study -- we discuss study design, sample types, sampling location, frequency. During this phase, students use maps, study weather patterns, and determine site accessibility.
Collect data -- we set aside lab periods for collecting data together. These are the sessions where you should be prepared to answer all sort of questions. Once the students begin implementing their study, many new questions come up.
Analyze and interpret results -- multiple lab periods are used to analyze data; student data are the basis of the remainder of labs. Techniques discussed are applied to their group projects.
Present findings -- students assemble posters and present results to their classmates.

Urban topics
Below is a short list of topics to stimulate ideas. Equipment required includes pH meter, conductivity meter, flow meter, Lamotte test kits.
Sources of N and P to the Los Angeles River
Contribution of golf courses to urban runoff
Extent of tidal influence on Ballona Creek
Metal fluxes from storm drains to the ocean
Relationship of land use to water quality
Relationship of population demographics to water quality

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Hands-on outdoor lesson plan for students to understand the meaning and components of climate change, and engineer and model how greenhouse gases cause heat trapping.

This activity develops students' understanding of climate by having them make in-depth examinations of historical climate patterns using both graphical and map image formats rather than presenting a general definition of climate. Students explore local climate in order to inform a pen pal what type of weather to expect during an upcoming visit. Students generate and explore a variety of graphs, charts, and map images and interpret them to develop an understanding of climate.

Before class, I prepare several "Darcy columns". These are plastic water bottles with a hole in the bottom that is covered with mesh and a rubber stopper. The bottles are filled with soil and water and are capped. One bottle is the reference bottle, with sand of height hs, and water of height hw, and a standard bottle diameter. Each of the remaining bottles are filled with one of the parameters varied: e.g., gravel instead of sand, silt instead of sand, sand of height 2hs instead of hs, water of height 2hw instead of hw, larger diameter bottle, etc. In class, student split into groups and each group is given a bottle, flexible ruler, funnel, graduated cylinder, and a large cup of water. As a group, they note the material type, measure the flow area, measure the height of porous material, and measure the difference in head across the porous material. Then they measure the flow rate, while maintaining a constant head. They repeat the flow measurement for their column, and then they repeat the process with one or more other columns, depending on the time available. Each group records their results on a table, and the class results are tabulated on the board. As a class, we discuss the whether or not their results follow Darcy's law. We also discuss the measurement errors, repeatability of the results, and the differences in flow rate for sand, gravel, and silt.

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Students learn about the techniques engineers have developed for changing ocean water into drinking water, including thermal and membrane desalination. They begin by reviewing the components of the natural water cycle. They see how filters, evaporation and/or condensation can be components of engineering desalination processes. They learn how processes can be viewed as systems, with unique objects, inputs, components and outputs, and sketch their own system diagrams to describe their own desalination plant designs.

Part 2 of offshore hydromechanics (OE4630) involves the linear theory of calculating 1st order motions of floating structures in waves and all relevant subjects such as the concept of RAOs, response spectra and downtime/workability analysis.

Offshore Hydromechanics includes the following modules:1. Hydrostatics, static floating stability, constant 2-D potential flow of ideal fluids, and flows in real fluids. Introduction to resistance and propulsion of ships. Review of linear regular and irregular wave theory. 2. Analytical and numerical means to determine the flow around, forces on, and motions of floating bodies in waves. 3. Higher order potential theory and inclusion of non-linear effects in ship motions. Applications to motion of moored ships and to the determination of workability. 4. Interaction between the sea and sea bottom as well as the hydrodynamic forces and especially survival loads on slender structures.

Volcanic debris flows (lahars) flow long distances, bury and aggrade river valleys, and cause long-term stream disturbances and dramatic landscape changes. Students will evaluate the nature, scale, and history of past lahars from Mount Rainier in a river valley and interpret the past and potential future impact on humans of lahars.

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This Ology website for kids focuses on Water. It includes activities, things to make, quizzes, interviews with working scientists, and more to help kids learn about Water.