In Unit 2, students apply and evaluate foundational concepts about storm hazards and risk in the context of two cases studies: Superstorm Sandy (2012) and the Storm of the Century (1993). Through different activities and assignments, students develop skills for finding, evaluating, and relating data to case studies and build an understanding of preparedness, response, and resilience. The activities include: an analysis of hazard mitigation plans for their local community, examination of storm-related geophysical processes in the context of societal risks, preparation of a press release for community preparedness, and a peer review and revision opportunity for the press releases. Instructors may also end this unit by having students revise their concept maps from Unit 1, applying lessons learned in Units 1 and 2.

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In this unit, students work in small groups to examine and analyze spatial data relevant to soils to identify patterns. They use their analyses to add detail to their Earth systems concept maps and describe how these data are relevant to interdisciplinary societal issues.

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Students will collect and analyze relevant social data on individual and community knowledge, risk perception and preparedness within their local social networks.

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This unit includes an opportunity for students to move from definitions into reading and creating a diagram of a complex system relevant to their course, and then to exploring the connections between the components in the system. An exercise is provided to help students identify complex systems and their component parts from the world around them. Students will draw and revise a systems diagram, including identifying measurable quantities in the system, and participate in a gallery walk. The unit ends with students constructing a system diagram from photographs they take, and reflecting on their process. Note that to carry out the activities described in this unit, groups of students will need large sheets of paper and markers, or whiteboard/chalkboard space, to create a diagram.

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How do geologic, hydrologic, biologic, and built-landscape features manifest themselves on maps? In this unit, students will use topographic maps, hillshade maps, and aerial imagery to learn to recognize a variety of landscape features and subsequently identify as many of these features as they can on a map of a new study area. They will also construct a topographic profile from their map data and use their profiles to understand the concepts of slope, aspect, and relief and how these landscape characteristics are important in hazard assessment and land-use planning.

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Online-adaptable: Part 1 (lecture) and Part 3 (individual or small-group exercise) are particularly straight forward to adapt to online. The landscape scavenger hunt exercise, Part 2, is typically done with printed maps but can be successfully adapted to online by having synchronous groups of students work together to annotate digital map files using: 1) PDF annotation tools in Adobe or 2) putting the map images into a Google Slides file and using the scribble tool. Google Earth files are also provided as an additional option.

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In this unit, students will keep a log of immediate, personal sensory experiences by pausing once each hour over a period of ten hours and recording the sights, sounds, smells, tastes, and tactile experiences they are sensing at that moment. The log (or journaling activity) will occur outside of class and will be shared in a subsequent class meeting.
In class, students will exchange their logs, respond and discuss, and then form larger groups which will discuss disparate ways of paying attention to sensory experiences. Students will develop a deeper understanding of their own perceptions and how those perceptions can be recorded and used to evaluate an environmental setting. This activity is qualitative; it requires students to create an informal, subjective journal of their sensory experiences once each hour for a ten-hour time period prior to class.
When students share their individual qualitative experiences in pairs and small groups, they will begin to see patterns emerge that will enable them to develop quantitative observations for future use. They will also begin to relate their sensory experiences to the social, biological, and geophysical aspects of their personal environment; students will begin to explore how these system components are interrelated and how exposure to them may impact human experience and well-being. After the group discussion, students will reflect on the interstices between qualitative and quantitative analysis by way of their sensory logs and mutual discussion.

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This unit applies a flipped classroom model. Students complete a self-study tutorial prior to attending class. Students are then asked work independently or in pairs to generate a time-aware climate change Web map application using ArcGIS Online. Returning to the theme of cocoa production introduced in Unit 1, students identify climatic conditions conducive for cacao production around the world, especially West Africa where the majority of cacao is grown. Students then use a web application in ArcGIS Online to create a time aware map showing biomes in the KÃppen Climate Classification System and determine how projected climate changes will impact the suitable production regions for cacao in West Africa. Using a jigsaw model, students collect into groups of 4, with a representative from each of the IPCC scenarios, and they compare the the impact of the 4 scenarios in specified cocoa production regions. At the end of the class they will be assigned to one of three regional areas for group work in Units 4-6.

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Over the course of one week, students will apply and evaluate concepts in the context of their local community, culminating in the formulation and evaluation of Hazard Mitigation Plan recommendations presented in stakeholder position papers. These position papers, which will also serve as the summative assessment of the Major Storms and Community Resilience Module, will be presented and assessed during a Town Hall Meeting. In this role-playing activity, students apply and evaluate concepts in the context of assigned stakeholder positions from their local community. Over the course of the week, students formulate and evaluate Hazard Mitigation Plan recommendations for major storms, and then present those recommendations in a town hall-style meeting. These assignments demonstrate students' ability to develop strategies and recommendations to mitigate local community vulnerabilities to storms with specific emphasis on different sectors and/or stakeholders in that community. Instructors will assess student achievement of the learning goals through a formal oral presentation and a team policy position paper. As such, the culmination of Unit 3 in the Town Hall Meeting serves as the summative assessment for the Major Storms module.

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In this unit students will explore surface water and its relationship to the water cycle via watersheds and drainage divides. These topics will inform their analysis of the social and environmental impacts of the planned increase of hydroelectric dams in the Amazon. Case studies include the Ene River and the MaraÃÃn River in Peru.

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In this unit, students will develop protocols for the collection of sensory data (scents and/or sounds), plan and execute the field collection of sensory data using developed protocols, analyze collected data, and create a map that communicates findings and impacts on the local population.
The advantage of using sensory data is that students are equipped with the analytical equipment (ears and nose) and are familiar with its use. However, students may not have taken the time to consider the variety of perceptions that occur within a group of people who are sharing a sensory experience and the impact that variation can have when collecting and analyzing data and subsequently communicating the results.
In this unit, as in the entire module, sensory data is considered in two contexts: First, as an indicator of environmental conditions, and, in some instances, environmental disruption. Second, as a proxy for data that is not as easily collected or as readily analyzed such as air or water samples. One of the challenges of developing these protocols will be discerning individual components from a complex system and developing an approach for systematically recording these data. This, though, gives students important exposure to the challenges of understanding and characterizing today's societal problems, which tend to include many interrelated dynamic causes.

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Unit 3 communicates the critical need for management of fresh water and ways in which citizens may take part in its conservation and restoration. Students explore the relationships between watersheds, drainage divides and the hydrologic cycle using a case study from the Hawaiian Islands involving surface water diversions from a region inhabited by indigenous people to a region comprised of large-scale agricultural fields.

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Students will identify potential stakeholders and assess the importance of communication and interaction among these groups to make recommendations on how to define and develop prepared communities.

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Landslides can have profound societal consequences, such as did the slide that occurred near Oso, Washington in 2014. Forty-three people were killed and entire rural neighborhood was destroyed. In this unit, students consider the larger-scale tectonic and climatic setting for the landslide and subsequently use lidar and SRTM (Shuttle Radar Topography Mission) hillshade images, topographic maps, and InSAR (interferometric synthetic aperture radar) to determine relationships between landscape characteristics and different types of mass-wasting events. They conclude by considering the societal costs of such a disaster and ways that communities in similar situations may mitigate their risk.

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Online-adaptable: The exercises in unit are completely digital and thus at a logistical level it can be switched to online fairly easily. However, due to the relative complexity of the data investigations and group discussions, there will still be a fair bit of instructor support needed and/or extended small group that should be arranged.

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In this unit, student groups will evaluate different environmental case studies to critically investigate qualitative and quantitative data analysis, collection, and inquiry. Students will begin to consider different forms of sensory-related data collection and how experiential knowledge informs the ways in which one forms analytical, evaluative questions. Student expert groups are provided one case study (different expert groups will examine at least two different cases) that has a number of different kinds of resources that students will examine (e.g. journalistic, scientific, narrative, visual, auditory). Students will use cooperative learning methods to engage with problem-based inquiry rather than have the case study information delivered via instructor-based lecture. Given that students across disciplinary contexts may not have been exposed to scientific methods of investigation, this unit encourages systems thinking alongside other methods of investigation. As students consider the variety of perceptions that occur within a group of people sharing an environmental experience, students are able to consider the impact that different types of data have on one's perception of data collection and its analysis. This exercise also demonstrates the utility of interdisciplinary thinking -- by examining data sets from multiple academic disciplines, students gain a more complete understanding of the case study compared to what they would have understood by examining data from a single research approach. The activity also provides students with an opportunity to practice interdisciplinary thinking and collaboration skills. The cases address several key environmental challenges: soil contamination, water resources, and the impacts of industrial agriculture.
A collaborative learning method is used in conjunction with guided class and group discussion to critically examine different types of data and encourage consistency of data analysis between student groups. This unit uses a group exploration and presentation activity to ensure equal distribution of materials and accountability among class participants. In essence, the students teach each other about the case studies with the instructor providing questions to elicit depth and synthesis between groups as well as to ensure that critical data analysis is undertaken.

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Units 4, 5, and 6 provide the opportunity for students to delve into a greater examination of food security at a regional level in small teams selecting one of the following locations (Caribbean, New York City, or Nebraska) OR a new location of their choice (provided that information and datasets are easily available and students will work with the instructor prior to the start of the unit) to apply skills and concepts taught in Units 1-3. Unit 4 materials are designed to provide a place-based overview for students to prepare them for the summative assessment, to be submitted in Unit 6, a community-based action plan of how the selected community can increase food security and lessen vulnerability.

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In this unit, students construct and present a standards-based, K -- 8 Soils, Systems, and Society Kit that consists of lessons and supporting materials around a locally and broadly relevant societal issue that involves soils. After learning about the Kit assignment and choosing their societal issue, students have at least two weeks outside of classwork time to develop a kit that integrates soils content with interdisciplinary systems taught through scientific practices. After completing their Kits, students present them to the class for review and final summative assessments.

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In this unit, students explore water privatization and freshwater access issues within the geophysical and cultural context of Cochabamba, Bolivia. Students identify topographical features that create rain shadows and their relationship to the water cycle. As they discuss several alternative models for supplying water to the residents of Cochabamba, they link concepts of environmental justice to the Cochabamba Water Wars of 2000.

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Students explore water quality and freshwater access issues around the globe. The activities require students to investigate region-specific water problems in different parts of the world and analyze how those issues are sometimes remedied. The materials in this unit may be used as a stand-alone day of instruction or as part of the complete Environmental Justice and Freshwater Resources InTeGrate Module.

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Unit 5 will delve more into an examination of food security using online ArcGIS. The class begins with a GIS-based exploration of data available for the three regions. The rest of the class period is provided for group work creating an action plan for a food insecurity issue teams have identified for their region. Students will utilize their maps from ArcGIS Online within their action plan. One component of the summative assessment, to be submitted in Unit 6, is a community-based action plan of how the selected community can increase food security and lessen vulnerability.

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