This series of 5 high-quality, standards-aligned, inquiry-based lessons have been field-tested by the 4K students of Wequiock Children's Center for Environmental Science, their teacher and educational assistant. These lessons encourage students to use natural areas around their school as they improve their science and engineering skills as part of a unit on observing changes. Created as a part of a WISELearn OER Innovation project, Connect, Explore, and Engage: Using the Environment as the Context for Science Learning was a collaboration of the Wequiock Children's Center for Environmental Science and the Wisconsin Green Schools Network. One of the goals of the project was to create standards-aligned lessons that utilize the outdoor spaces of the school . These lessons were created to take place during late winter.

This lesson will allow students to explore an important role of environmental engineers: cleaning the environment. Students will learn details about the Exxon Valdez oil spill, which was one of the most publicized and studied environmental tragedies in history. In the accompanying activity, they will try many "engineered" strategies to clean up their own manufactured oil spill and learn the difficulties of dealing with oil released into our waters.

Looking at models and maps, students explore different pathways and consequences of pollutant transport via the weather and water cycles. In an associated literacy activity, students develop skills of observation, recording and reporting as they follow the weather forecast and produce their own weather report for the class.

This curriculum guide contains pacing, instruction, and assessment guidance to accompany the OpenSciEd unit 7.6 Earth Resources & Human Impact. For schools who use Fisher and Frey's The Teacher Clarity Playbook, you'll find student-friendly learning intentions and success criteria for every lesson, drawn from the OSE three dimensional performance expectations. These can be posted on slides or boards in classrooms to make learning visible for students and help design assessment criteria.  

Students are introduced to the fabulous planet on which they live. Even though we spend our entire lives on Earth, we still do not always understand how it fits into the rest of the solar system. Students learn about the Earth's position in the solar system and what makes it unique. They learn how engineers study human interactions with the Earth and design technologies and systems to monitor, use and care for our planet's resources wisely to preserve life on Earth.

From drinking fountains at playgrounds, water systems in homes, and working bathrooms at schools to hydraulic bridges and levee systems, fluid mechanics are an essential part of daily life. Fluid mechanics, the study of how forces are applied to fluids, is outlined in this unit as a sequence of two lessons and three corresponding activities. The first lesson provides a basic introduction to Pascal's law, Archimedes' principle and Bernoulli's principle and presents fundamental definitions, equations and problems to solve with students, as well as engineering applications. The second lesson provides a basic introduction to above-ground storage tanks, their pervasive use in the Houston Ship Channel, and different types of storage tank failure in major storms and hurricanes. The unit concludes with students applying what they have learned to determine the stability of individual above-ground storage tanks given specific storm conditions so they can analyze their stability in changing storm conditions, followed by a project to design their own storage tanks to address the issues of uplift, displacement and buckling in storm conditions.

What do plants need? Students examine the effects of light and air on green plants, learning the processes of photosynthesis and transpiration. Student teams plant seeds, placing some in sunlight and others in darkness. They make predictions about the outcomes and record ongoing observations of the condition of the stems, leaves and roots. Then, several healthy plants are placed in glass jars with lids overnight. Condensation forms, illustrating the process of transpiration, or the release of moisture to the atmosphere by plants.

This series of 5 high-quality, standards-aligned, inquiry-based activities and one STEM challenge have been field-tested by secong grade students and families of Wequiock Children's Center for Environmental Science during Safer At Home orders. These activities encourage students to use natural areas around their homes and in their neigbhorhoods as they improve their science and engineering skils relating to plant and animals interdependence. Created as a part of a WISELearn OER Innovation project, Connect, Explore, and Engage: Using the Environment as the Context for Science Learning was a collaboration of the Wequiock Children's Center for Environmental Science and the Wisconsin Green Schools Network. One of the goals of the project was to create standards-aligned lessons that utilize the outdoor spaces of the school (as well as those of the students' homes).  These lessons were created to take place during the spring. However, some of the lessons could be conducted during the fall. Cut flowers from a florist may be used in place of ones found living outdoors.The title image was used with permission and is courtesy of Joe Riederer. The observation protocol "I Notice, I Wonder, It Reminds Me Of, I Think Maybe" has been adapted from that of the BEETLES Project.

Students gain an understanding of the parts of a plant, plant types and how they produce their own food from sunlight through photosynthesis. They also learn about transpiration, the process by which plants release moisture to the atmosphere. With this understanding, students test the effects of photosynthesis and transpiration by growing a plant from seed. They learn how plants play an important part in maintaining a balanced environment in which the living organisms of the Earth survive. This lesson is part of a series of six lessons in which students use their evolving understanding of various environments and the engineering design process, to design and create their own model biodome ecosystems.

Students learn how a bill becomes law in the U.S. Congress and research legislation related to global warming.

To develop an understanding of modern industrial technologies that clean up and prevent air pollution, students build and observe a variety of simple models of engineering pollutant recovery methods: scrubber, electrostatic precipitator, cyclone and baghouse. In an associated literacy activity, students become more aware of global environmental problems and play a part in their solution by writing environmental action campaign letters.

Students learn about population density within environments and ecosystems. They determine the density of a population and think about why population density and distribution information is useful to engineers for city planning and design as well as for resource allocation.

Why do we care about air? Breathe in, breathe out, breathe in... most, if not all, humans do this automatically. Do we really know what is in the air we breathe? In this activity, students use M&M(TM) candies to create pie graphs that show their understanding of the composition of air. They discuss why knowing this information is important to engineers and how engineers use this information to improve technology to better care for our planet.

For the last century, precepts of scientific management and administrative rationality have concentrated power in the hands of technical specialists, which in recent decades has contributed to widespread disenfranchisement and discontent among stakeholders in natural resources cases. In this seminar we examine the limitations of scientific management as a model both for governance and for gathering and using information, and describe alternative methods for informing and organizing decision-making processes. We feature cases involving large carnivores in the West (mountain lions and grizzly bears), Northeast coastal fisheries, and adaptive management of the Colorado River. There will be nightly readings and a short written assignment.

This course examines joint fact-finding within the context of adaptive and ecosystem-based management. Challenges and obstacles to collaborative approaches for deciding environmental and natural resource policy and the institutional changes within federal agencies necessary to utilize joint fact-finding as a means to link science and societal decisions are discussed and reviewed with scientists and managers. Senior-level federal policymakers participate

Through this activity, students come to understand the environmental design considerations required when generating electricity. The electric power that we use every day at home and work is usually generated by a variety of power plants. Power plants are engineered to utilize the conversion of one form of energy to another. The main components of a power plant are an input source of energy that is used to turn large turbines, and a method to convert the turbine rotation into electricity. The input sources of energy include fossil fuels (coal, natural gas and oil), wind, water, nuclear materials and refuse. This activity focuses on how much energy can be converted to electricity from many of these input sources. It also considers the impact of the by-products associated with using these natural resources, and looks at electricity requirements. To do this, students research and evaluate the electricity needs of their community, the available local resources for generating electricity, and the impact of using those resources.

Students embark on a scavenger hunt around the school looking for indoor air pollution and mapping source locations.

Examines different types of historical writing: political, social, cultural, demographic, biographical, and comparative. Includes discussion of historical films, fiction, memoirs, and conventional history. Particular attention given to works which have broken new ground in terms of their methodology and approach. Required writing includes brief weekly response papers and a substantial research paper (including proposal, first draft, and final draft), in conjunction with a formal oral presentation. Weekly discussion of readings include periodic student-led discussion and/or presentations. Open to all students, but required of history majors and minors in junior year. This course is designed to acquaint students with a variety of approaches to the past used by historians writing in the twentieth century. The books we read have all made significant contributions to their respective sub-fields and have been selected to give as wide a coverage in both field and methodology as possible in one semester's worth of reading. We examine how historians conceive of their object of study, how they use primary sources as a basis for their accounts, how they structure the narrative and analytic discussion of their topic, and what are the advantages and drawbacks of their various approaches.

The history of settlement around the Mississippi River is often depicted as a struggle of humankind against Nature. Yet the very richness and fertility of the soil in the Midwest and South is the direct result of the regular flooding of the Mississippi River and its tributaries. In April 1927, after more than a month of rain, the river overflowed its banks in a flood which inundated more than 16 million acres of land in seven states, destroyed 40,000 buildings, washed away over $100 million in crops, and claimed between 250 and 500 lives. For his book about the flood Deep'n as it Come, historian Pete Daniel interviewed Herman Caillouet, an Army Corps of Engineers employee who used his twenty-two-foot boat to rescue 175 people stranded by the rising waters. Here Caillouet told of his futile attempt to rescue a family of seven.

Over the course of three sessions, students act as agricultural engineers and learn about the sustainable pest control technique known as soil biosolarization in which organic waste is used to help eliminate pests during soil solarization instead of using toxic compounds like pesticides and fumigants. Student teams prepare seed starter pots using a source of microorganisms (soil or compost) and “organic waste” (such as oatmeal, a source of carbon for the microorganisms). They plant seeds (representing weed seeds) in the pots, add water and cover them with plastic wrap. At experiment end, students count the weed seedlings and assess the efficacy of the soil biosolarization technique in inactivating the weed seeds. An experiment-guiding handout and pre/post quizzes are provided.