Students analyze the global temperature record from 1867 to the present. Long-term trends and shorter-term fluctuations are both evaluated.

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The goal of this activity is to investigate global topographic and tectonic features, especially the tectonic plates and their boundaries. Using a double-page size digital topographic map of the Earth that includes both land and sea floor topography, students are asked to draw plate boundaries, deduce plate motions and interactions, and explore the connections between topography and tectonic processes at the global scale.

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This is a teaching module, directed to undergraduate students in applied mathematics, that presents a Zonal Energy Balance Model to describe the evolution of the latitudinal distribution of Earth's surface temperature subject to incremental levels of cumulative carbon emissions in the atmosphere. A strategy to avert "dangerous levels" of global warming is imbedded in the model. Students working with the module will write a computer code, using a software such as MATLAB or Mathematica, to obtain numerical solutions of the model and simulate strategies that guarantee controlled levels of global warming.

Detailed, annotated example of Socratic questioning for topics of climate change, global warming, and greenhouse gases in the atmosphere.

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Brian Fagan is an emeritus professor of anthropology at University of California, Santa Barbara who has written several books about past climate change and its effect on the course of European history. His latest book, "The Great Warming," focuses on the Medieval Warm Period (circa 10th to 14th centuries) during which the North Atlantic region experienced an unusually warm climate, and discusses historical events and trends that can be correlated with this climatic change. This assignment uses this book, along with student-retrieved newspaper articles, as the basis for a research paper that addresses the issue of global warming, its effect on past civilizations and its anticipated effect on the future of the citizens of New York City.

Based primarily on "The Great Warming", students address the following questions in a 5 page paper:

What methods and data sources do scientists use to determine climates of the past? How reliable are these various approaches?
How was European climate different during the Medieval Warm Period, and how did this climate affect the lives of people in Europe?
How was climate different during the Medieval Warm Period for one other region of personal interest, and how did this climate affect the lives of people who lived in that region?

Using information from "The Great Warming" and three to six articles from past issues of a major newspaper, such as the New York Times, students determine probable effects of global warming to the future populations of either their home city, or of the region for which they documented past climate change.

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In the first part of this activity, students think about their personal carbon emissions and driving habits. They reflect on what might be done to reduce our carbon emissions, as individuals and as a society as a whole. In the second part of the activity, students calculate how much sea level would rise if a range of ice melting scenarios occur. They then examine topographic maps of local coastlines to see how different regions would be affected under the range of scenarios.

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Possible pre-course reading of the Introduction of:
"Smart Solutions to Climate Change: Comparing Costs and Benefits" Ed. BjÃrn Lomborg
Global Warming and You--handout (Microsoft Word 44kB Oct27 10)

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Scientists say the planet is warming because of human activities, namely the greenhouse effect from carbon dioxide released to the atmosphere when burning fossil fuels. But, how do we know? How do scientists know?
Students are presented with the following questions:
1) What makes a greenhouse gas a greenhouse gas?
2) Is carbon dioxide a greenhouse gas? [Instructor: How do we know?]
3) Is the amount of carbon dioxide in the atmosphere increasing? How do we know?
4) Is carbon dioxide [in the atmosphere] increasing because of human activities? [Instructor: How do we know?]
---- Discussion of results and prediction of what students expect will happen to global average temperature...
5) Is global average temperature increasing? How do we know?

Separate groups of students research just one question each on the internet and submit a brief summary to the instructor. The instructor and class go over results for just the first four questions. The instructor addresses "How do we know" for questions 2 and 4. Then, students are asked what they think will happen to global average temperature based on results of the first four questions (i.e. make an hypothesis). Finally, the results from the last group are presented and students are asked to discuss how observed global temperature changes compare with their hypothesis.

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Field trip handout (Microsoft Word 52kB Oct27 10)

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This activity is an interactive lecture, where students will learn that fresh water is a limited resource. They will also see that drinkable water is not distributed evenly over the earth.

This activity gives kindergartners the chance to get outside collect, observe and sort leaves. They will also try to differentiate between MN native leaves and non-native leaves to MN.

This activity is an investigation of the Earths Moon phases and its position in the sky.

In this activity, students explore the relationship between developmental biology and macroevolution by focusing on how evolutionary changes in ontogeny can produce small-scale (within species) and large-scale (between species or major lineages) evolution of morphology.

In Part A, students begin the activity by measuring skull length vs. braincase width in an ontogenetic sequence of an "ancestral" wolf species. They graph the resulting data then determine whether the relationship between the two is isometric or allometric.

In part B, they choose three skulls of adult domestic dog breeds (available via online sources such as Skulls Unlimited). Measure the same two variables and compare these "descendent" data to the wolf "ancestral" data. In this way, they determine which dog breeds (e.g., pugs, bulldogs) appear to be paedomorphic and which (e.g., greyhounds) appear to be peramorphic.

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This case study places students in professional roles in organizations dealing with resource issues where they perform typical tasks. Whereas background content is provided via the Web, activities are done on paper. This case consists of three modules completed in successive lab sessions, focusing on gold mining in South Africa and its economic, political and social ramifications.
geology: Student groups, representing gold mining companies, are given company directives, topographic maps and sample analysis reporting forms. The directives instruct them to assess their map regions for gold deposits. Groups report on the results of a geochemical survey they conducted to identify potential gold deposits.
economics: Groups are given new company directives and geologic maps of the area previously studied. They perform an economic assessment of the gold deposit(s) in their area and recommend whether the company should proceed to production. Groups design and implement an exploratory drilling program, i.e. select drilling sites, methods and depth, and give the map to their instructor for coring. They are provided corresponding cores which they use to select stratigraphic intervals for geochemical analysis. Using deposit grade, volume and recovery factor, students calculate the market value of the deposit's recoverable gold. Comparing this value to projected production costs, groups recommend whether their company should proceed to production.
social: Groups are assigned new unique roles, e.g. mining company, miner's union, worker's rights NGO, to investigate the social consequences of mining, i.e., the role of mining technology on safety, job security and environmental impact.. In this scenario, the mining company is considering new technologies to offset the increasing cost of deeper mining. Based on their perspective, groups identify externalized costs; evaluate potential impacts on their group and establish a starting position for negotiations between stakeholders. The various groups then negotiate an agreement about which technology(ies) to adopt.

This site provides a comprehensive overview of all aspects of the Gold Rush including general and specific historical information, as well as people and historical societies involved in the Gold Rush.

Students collect protein electrophoresis data comparing goldenrod gall flies, analyze class data, and write a lab report in the format of a scientific paper.

In this life science field investigation students will study golden rod gall populations within a patch of goldenrods.

We use these Google Earth Exercises (GEE) in the undergraduate structural geology course. Students construct a complete geologic map of each 'field area' outside of class; in class, the students display their map and discuss their observations, interpretations, assumptions, and reasoning. This exercise promotes discussion among the students, and also provides students with the opportunity to develop speaking skills, as well as 'on-your feet' reasoning and analysis. Mapping can be done digitally using graphic software such as Adobe IllustratorTM or using hard copy images and overhead transparencies. (Digital mapping requires that the students have knowledge of working with, and access, to a graphics program such as Adobe IllustratorTM). Students also draw stratigraphic columns and cross-sections as needed; and they determine a relative sequence of events for each 'field' area. Cross section lines are included in the .kmz (Google Earth) file (not on the map images). This allows the instructor to move cross-section locations as needed. We have 3-4 students display and discuss maps for each exercise (usually takes about 30-45 min.); we encourage student to question their classmates; with time, our encouragement becomes less necessary. We have students construct geologic maps on transparencies and display the maps via an overhear projector keeping the LCD projector free to run Google Earth. Students can use Google Earth (flying to specific locations, or zooming in and out, or viewing specific locations from different perspectives) during their presentation to illustrate or support their interpretation, and logic path that lead to that interpretation to the class. This provides the opportunity for students to see how different people interpret the same area; they also learn that although each maps is different, each map tells a similar story; that is first-order relationships emerge from the family of maps constructed by their fellow classmates. After each discussion, all of the students display their maps on a side table in the classroom, providing the students with the opportunity to compare all of the maps of the same area. As a result they clearly see that all maps are different, yet each can be valid, and they also see how others handled both geologic relations, and, at a more basic level, clarity and neatness in presentation. As the semester progresses we see a sharp increase in the quality of the maps, both geologically and in terms of clarity and neatness, likely a direct result of students both viewing their classmates maps, and having their maps viewed by classmates. Peer pressure can be a wonderful learning tool.

Each exercise focuses on a different area. An individual exercise or any combination of exercises maybe used at the instructor's discretion to compliment topics in either lecture or lab. The exercises, as presented, are ordered in such a way that they take the student progressively from relatively straightforward map areas to increasing complicated map areas. We begin the geologic mapping sequence using a Venus mapping exercise available on the SERC site http://serc.carleton.edu/NAGTWorkshops/structure04/activities/3875.html in order to get the students to feel comfortable identifying and delineating patterns; we develop concepts about material units versus structural elements (and in some cases primary verses secondary structures; please see the Venus exercise for the range of students goals, which we do not repeat here). The first Google Earth Exercise, (GEE1) follows the SERC exercise 'Visualizing Inclined Contacts' by Barbara Tewksbury http://serc.carleton.edu/NAGTWorkshops/structure/visualizing_inclined.html . Our GEE1 exercise is included below with all credit to Barbara Tewksbury. Subsequent exercises (GEE2, GEE3, etc.) include: faults and topographic interactions; folds and topographic interactions; faults and crosscutting dikes; refolded folds. These exercises may be used in any order and/or positioning within a course. We find that both the repetition of GEE exercises, and the progression of increasing complexity of the exercises, allow the students the opportunity to develop their individual skill sets. Although mapping can be completed by the students during, or outside of class time, we find that having the students do this outside class allows each student the opportunity to move at their own pace, which seems important for our students and their learning. Discussion during class time is a critical part of the learning process.

These exercises can be easily replicated for your favorite field area or an area your think exemplifies an instructive structural style. We encourage other educators to apply this idea to other areas and submit the new Google Earth Exercises to SERC as well.

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In this activity, students use Google Earth Pro to examine and measure sedimentary and geomorphic structures related to the late Pleistocene draining of glacial Lake Missoula and Lake Bonneville.

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To prepare for this activity, students have been introduced in class and through readings in their textbook to basic crustal deformation processes and landforms including: kinds of stress and strain, surface expressions, and types of faults and folds. Students also have some previous experience navigating in and controlling views in Google Earth. In Lab, students use their personal or lab computers equipped with Google Earth to view a number of specific locations within the United States that have folded or faulted landforms. Each location and landform includes some additional background information and a series of questions that ask the student to 1) review learned knowledge of processes and landforms, 2) identify real topographic expressions of processes and landforms, thus practicing the terminology, and 3) create new understanding of the processes that formed specific landforms. This exercise helps students to move from viewing simple textbook diagrams of crustal deformation processes and landforms to recognizing these elements in real landscape settings.

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