This unit has students build on a system diagram, to include new knowledge about quantitative values and relationships. They will also write about and discuss what they know about their systems, the questions that still remain, and how to find answers to their questions.

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Unit 5 is a final exercise that can start during a lab period and carry over into work outside of the lab time. The project report will test students' abilities to synthesize and apply knowledge related to LiDAR, InSAR, and infrastructure analysis learned in earlier units of the module. Data are provided for two potential case study sites for the final report -- El Major Cucapah Earthquake (Mexico 2010) and South Napa Earthquake (California 2014). Alternatively, the instructor or students can choose other sites to analyze. Unit 5, along with an exam question, is the summative assessment for the module. Students will be able to use the experience as a means of preparing for a final exam question on a related topic.

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Online-ready: The exercise is a final project that can be done remotely, individually or in small online groups.

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In this unit, student groups will use sensory data (scents and/or sounds) collected in the field to create maps of the sensory environment and relate their findings to larger environmental problems identified in their guiding questions and hypotheses. This unit is designed to build upon prior units in which students develop guiding questions and hypotheses, field data collection protocols, and field investigation plans. The field investigation will require a base map on which to record data and a final map on which to display data and characterize the study area and environmental impact of the mapped data. The base map will be derived from aerial imagery if the investigation site is outside. The base map will be derived from a building schematic or floor map if an interior location is mapped.
Class time will be devoted to developing maps on which students will display the data collected in the field. Students will use Google Earth or other online resources to obtain aerial (or other schematic) imagery of their study area. They may use an aerial image as a base map or they may draw their own maps based on the aerial imagery. If the site is indoors, a blueprint or floor plan can be the base map, or students can draw their own maps based on an existing image or schematic.
Sensory mapping allows students to identify scent plumes as they migrate away from source locations. Odor plumes and sounds are analogous to plumes of contaminants that migrate through groundwater, surface water, and air. In many instances, the presence of unusual odors is an indicator of migrating contaminants and can lead to sampling by environmental professionals (including geoscientists) to confirm and quantify contaminant migration through the environment. These maps serve as representations of the complex odor or sound systems in the students' chosen geographical areas.

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In the final unit of the module, students will synthesize their understanding of climate science and modes of communication. Students are assigned to groups and given a climate change issue that they will use to demonstrate their understanding of ethos, pathos, and logos, when presented with a variety of audiences. The module summative assessment is designed to be administered after this unit.

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In this unit, students will learn about the dynamic movement of nutrients among and within ecosystems primarily through the reading and discussion of scientific literature. This unit is generally subdivided into three sections: (1) allochthonous inputs (2) the role of organisms in biogeochemical cycles and how ecological theory can be applied to biogeochemistry and (3) how biogeochemical processes can assist in creating solutions for humanity's grand challenges. This unit is designed to provide students with the opportunity to develop their reading and interpretation of scientific literature. Students will also become familiar with the utility of isotopic techniques and their use in biogeochemistry through readings and data analysis of carbon and nitrogen isotopic data sets. Chosen scientific articles are provided, each with their own set of reading questions. Additionally, short introductory materials are provided to introduce students to some of the general concepts and processes in the study of biogeochemistry.

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This unit is the module's capstone project: developing a conceptual model of the climatic and societal effects of a catastrophic volcanic eruption occurring in modern times. Through independent research and in-class collaboration, students explore the climatic and societal effects of past volcanic eruption events. Students are then introduced to the large Toba eruption event, review concept maps, concept sketches, and system diagrams, and are are given examples and guidelines for conceptual model design. Students complete their written summary outside of class.

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Students watch a video and read about past evacuations, including a premature or unnecessary evacuation, a late or botched evacuation, and about people determined to stay put no matter what. Students participate in a role-playing exercise about making the decision to evacuate in the face of uncertain predictions.

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Unit 6 provides an opportunity for students to present their action plans and exchange knowledge about what they have learned in their team case study work. This unit builds on food security and Earth system science covered in the first three units. It can be taught in any course discussing food security or it can be modified to fit a variety of courses of in the sciences and social sciences. The activities included in this unit are appropriate for introductory-level college students or as a basis for more in-depth class discussions on food security for upper-level students.

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This in-class exercise is an alternative to standard review sessions and models the systems thinking students need to do when working on complex, interdisciplinary issues. Students quiz each other on course material and then find authentic (and often creative) connections between seemingly disparate topics in the course. This approach challenges students to use holistic thinking when reviewing, and can be readily customized for any course.

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Humans are agents of change in the Critical Zone. This unit focuses on the land/water connection and on how human-induced land use change affects local hydrology. Students will apply what they learned in the previous Hydrology Module about how hydrologists use data (land-cover type, soil texture, and slope) to predict the amount and destination of water as it moves through a built environment. Students will use the Generic Model from the Model My WatershedR application to evaluate the impact of human alterations to the landscape and will also investigate how best-management practices can lesson those impacts. While doing so, students will also be asked to consider impacts to society both from the increased runoff and from some mitigation measures.

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Peer review is an important process in determining priorities for scientific research. Students will participate in a panel review of proposals for new CZOs and as a class decide on the proposal most worthy of funding. Students will read proposals, craft a detailed review of the merits and limitations of the proposal, and then discuss the proposals during an in-class panel review. Proposals will be evaluated on how well the proposed CZO would help address global challenges and advance Critical Zone science and require students to use knowledge gained in previous modules to assess and communicate which proposals meet these goals.

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Unit 7 continues the use of the CME Building Case Study to explore water sustainability in the context of a building. The activity is extended to the catchment level, and a new tool for catchment level storm water management is introduced. Students are exposed in the pre-class assignments to low impact development (LID) and green infrastructure and the EPA National Stormwater Calculator. In class, the central activity is applying the EPA National Stormwater Calculator to evaluate an LID control plan for the CME building case study. The unit brings together concepts from previous units through the use of the calculator. The impact of landscapes, buildings, and other features on storm water runoff is illustrated. And the potential benefit of LID controls is analyzed. The homework assignment engages students in the search for a local green infrastructure site to take a picture and summarize the site in the context of a sustainable site.

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Unit 9 is a group activity that requires students to apply the material they have learned in Units 1 -- 8 in an urban water system design project. Students are presented with a scenario and are required to select options to design a feasible and sustainable urban water system that considers the triple bottom line in their design. The design project requires that students consider hydrologic processes (e.g., evapotranspiration, runoff) in designing outdoor landscaping and amount of pervious and impervious area. Students also consider indoor water use efficiency and other methods (e.g., rain barrels) to reduce water consumption. Students are also asked to consider the connection between urban development and atmospheric processes. Students apply systems thinking by connecting hydrologic and atmospheric processes with the human built system. Student groups present their design to the class and assess each other's designs. These activities can be used as a summative assessment for the entire module.

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Open-ended, field, inquiry projects can be very useful in sedimentary geology courses to explore dynamic relationships in sedimentary systems. I have used this approach to allow students to "do" their own science in a small stream near our campus. These projects generally involve studying relationships between the nature of stream flow, stream dynamics, geometries of the channel, and characteristics and rates of movement of bedforms. The small-group inquiry project begins with students observing a section of the stream (located a couple miles from campus), followed by brainstorming questions about the features observed in the stream and on its bed, then to designing and implementing experiments to answer specific questions that they have formulated, and concluding with data analysis and student presentations of their research. Approximately a dozen steps comprise the complete inquiry approach.

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In this session we will examine how to utilize Dynamic Digital Maps (DDMs) in undergraduate petrology courses to bring inaccessible and exciting volcanic field areas to the students in the classroom and to engage the students in authentic research experiences. A DDM is a stand-alone "presentation manager" computer program that contains interactive maps, analytical data, digital images and movies. They are essentially complete geologic maps in digital format, available on CD-ROM and on line. We have developed two different kinds of exercises that use DDMs to provide field-based context for undergraduate research projects in petrology. In one, the students use the DDM of the Tatara-San Pedro volcanic complex of the Andes Mountains of central Chile to develop a group research poster on part of the volcano's evolution, to present to the class, modeled after what would be presented at a national meeting. The second exercise focuses on the Springville Volcanic field, where the students try to understand the magma evolution using both field relations and quantitative modeling skills.
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Read a complete description of how dynamic digital maps work, with more ideas for the classroom. (from Teaching with Data, Simulations and Models)

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These assignments are adaptations of field labs to incorporate writing. For each field lab, students write a partial geologic report, consisting of a description (or "Structural Data") section, an interpretation section, and appropriate supporting figures (potentially including stereonets, field sketches, maps, cross-sections, etc.).
Handouts given at the beginning of lab list: the goals to be accomplished in the field (measurement of foliations and lineations, measurement of bedding around a fold, description of structures, field sketches, etc.),
the figures expected in the write-up (stereonets, field sketches, etc.),
a list of information to include in the description section, and a list of questions to address in the interpretation section. Depending on the field area, students may be given two or more competing models to test in the field or may be asked to relate descriptive analysis to kinematic or mechanical analysis. This adaptation can be used for field labs at all levels, from labs designed to review field techniques and identify basic types of secondary structures to labs that simulate research experience. This type of write-up improves student writing by giving students practice using terminology and describing spatial relationships, and improves critical thinking skills by requiring written interpretation of structural data.

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Introduces the ethical dimension of finding, using, and sharing images in the context of the undergraduate research assignment. Students will understand the ethical aspects of finding, using, and sharing images; will engage with copyright issues and concepts of intellectual property; and will find and analyze specific images as examples.

Students work in small groups to record interviews capturing public attitudes on various types of waste. Students then edit shorter videos into a larger film that incorporates student analysis and synthetic commentary on waste in our society.

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This is a comprehensive project using the Highland Road Park Observatory camera. This project encompasses the formal portions for both written and spoken communication, and carries 55% of the course credit.

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