This activity is a field trip investigation where students gather stream flow, volume, depth & height (area) data on Ramsey County dams (Keller and Round lake), interpret their findings and make in-depth observations in order to assess the effectiveness of dams through the season and estimate the life-span of the dams in years.

This activity is an in class lab where students will compare different acid solutions on seed germination and growth.

The goal of this exercise is to have students gain an understanding of how fractures affect groundwater flow patterns. In order for them to complete the activity, they need some background on characteristic fracture patterns in different rock types. This background could be provided in a variety of ways depending on geographic location and outcrop availability. If outcrops of crystalline and sedimentary sequences are available, you could take students in the field and have them observe (and perhaps sketch) the differing fracture patterns. If geology (and or weather) preclude this option, the students could observe fracture patterns from slides of outcrops (see slides in accompanying PowerPoint Presentation).

The classroom portion of the exercise uses a simple 2D numerical model (TopoDrive, available from USGS) to simulate flow in three aquifers: 1) homogeneous isotropic, 2) fractured crystalline, and 3) fractured sedimentary sequences. The task is to observe how the fracture patterns alter the flow patterns as compared to the homogeneous, isotropic simulation. The activity gives students practice in integrating geologic data into numerical models, describing flow patterns, and using computer technology. The activity also integrates knowledge from structural geology with hydrogeology.

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In this video produced by ThinkTV, explore the effects of land masses on local climate conditions, and learn about regional impacts of land-atmosphere interactions.

In this video segment adapted from NOVA scienceNOW, scientists examine the link between rising sea surface temperature and more intense hurricanes.

This video shows 15 years of data obtained via Polar-orbiting satellites that are able to detect subtle differences in ocean color, allowing scientists to see where there are higher concentrations of phytoplankton - a proxy for the concentration of chlorophyll in the ocean.

In this media-rich lesson, students learn how global warming is changing the Alaskan environment and examine the consequences of climate change on the region's human and wildlife inhabitants.

This worksheet helps students think about the cause and effect of pressure/temperature changes in subsurface and how these changes would affect the state of a solid rock. In this worksheet, students are given 6 different scenarios and associated pressure/temperature charts with a solidus line and a starting pressure/temperature point. Scenarios include heating and melting due to a nearby intrusion, diagenesis, decompression melting, cooling of magma at the surface, and adding water to the system. For each scenario, students draw an arrow from the starting point to show how the pressure and temperature would change. For example, students are told that a rock in the subsurface quickly rises towards the surface and melts, so fast that the temperature doesn't change much. A student would then draw a vertical arrow up to show that there is only a change in pressure. There scenarios are chosen to help students better understand the complexities of the subsurface in terms of pressure and temperature.

This worksheet uses the sketch-understanding program with built-in tutor: CogSketch . Therefore, students, instructors, and/or institution computer labs need to download the program from here: http://www.qrg.northwestern.edu/software/cogsketch/. At any point during the worksheet, students can click the FEEDBACK button and their sketch is compared to the solution image. The built-in tutor identifies any discrepancies and reports pre-written feedback to help the student correct their sketch until they are done with the activity. Once worksheets are emailed to the instructor, worksheets can be batch graded and easily evaluated. This program allows instructors to assign sketching activities that require very little time commitment. Instead, the built-in tutor provides feedback whenever the student requests, without the presence of the instructor. More information on using the program and the activity is in the Instructor's Notes.

We have developed approximately two dozen introductory geoscience worksheets using this program. Each worksheet has a background image and instructions for a sketching task. You can find additional worksheets by searching for "CogSketch" using the search box at the top of this page. We expect to have uploaded all of them by the end of the summer of 2016.

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This video addresses the importance of efficiency in providing power to an increasingly large global population.

This video, adapted from NASA, presents rare experimental evidence from the Fermi Gamma-ray Space Telescope supporting Einstein's prediction that space-time is smooth.

This National Geographic video explains the origins of the El NiÃo Southern Oscillation using animations and shows the impacts on humans, wildlife and habitat, particularly in the United States.

This short video illustrates the phenomena of El NiÃo and La NiÃa: their relationships to tradewinds and surface water temperatures, and their effects on precipitation in North America.

This activity investigates the oceanographic and climatic characteristics of El NiÃo/La NiÃa (ENSO) events using observational data from moored ocean buoys in the tropical Pacific Ocean. Data are obtained from NOAA's Tropical Atmosphere Ocean (TAO) project website which provides a web-based interface for accessing and displaying oceanographic data. In addition to providing an introduction to ENSO, this activity is designed to give students practice interpreting real oceanographic observations by emphasizing the description and identification of patterns in large data-sets. Students first describe patterns in sea-surface and cross-sectional transects of ocean temperatures and surface winds associated with "normal", El NiÃo, and La NiÃa years and then use this as a basis for classifying observations from unknown years and interpreting connections between oceanographic and atmospheric processes occurring in the tropical Pacific.

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In late September (of an election year), one class session is devoted to developing a list of issues key to the class and likely to be discussed by the candidates. The list is converted into 3-5 questions all students will research and answer. Each student is assigned a candidate (President, Governor, congress, state legislature). An effort is made to assign each student a candidate who will appear on his/her ballot and to assign third party candidates.

Student research candidates' positions using web resources, news papers, and campaign materials. Students are strongly encouraged to contact the campaign directly and question the candidate, if possible.

Students report back to the class with a 3-5 minute presentation and a poster that may be displayed in a college commons area. Reports are presented a week prior to the election.

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For this experiment, students use a DC motor as a generator and various shaped turbine designs to test which design produces the most electrical power. Using a fan to generate the "wind", students attach different blades made of folded paper or card stock to the motor to see how much power is generated.

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This is a hands-on lab activity about the chemical composition and conductivity of water. Working in groups, learners will: conduct an experiment involving the process of electrolysis, prepare an experiment to better understand the process of ion exchange, discuss and research the "softness" and "hardness" of water, and use the periodic table to identify elements and learn their characteristics. Background information, a glossary and more is included. Materials needed for each student group include a 9-volt battery, two electrodes (e.g. copper strips, or two #2 pencils sharpened at both ends), electrical wire and glass beakers or ceramic saucers. This activity is part of the Aquarius Hands-on Laboratory Activities.

As the core activity of petrology portion of a mineralogy/petrology course, students cooperatively conduct petrographic and electron microprobe analytical studies on suites of Central Blue Ridge metamorphic rocks collected during class field activities. We make use of a remotely operable electron microprobe instrument at the Florida Center for Analytical Electron Microscopy (FCAEM) to conduct all analyses in class.

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Our remote access system permits students to interact with our electron microprobe and obtain visual information about the tasks performed by lab personnel. Students in a petrology class, for instance, can view backscatter-electron images of a particular sample, ask for specific points to be analyzed, and immediately see the resulting spectrum of characteristic X-rays. With this interaction, such an exercise is more much pedagogically effective. Our video streams mean that students do not need to know how to operate the instrumentation -- that is not the point for students in a mineralogy or petrology course. Instead, seeing a live backscatter-electron image or an X-ray spectrum from a point they chose catches the interest of students and allows them to make decisions while they learn about mineral associations. Many classrooms are now equipped with Internet connections and a computer with a projection system. As a result, a lecturer in such a classroom can project our video streams onto a screen or wall so that the entire class can observe the analysis of a sample. Lab rooms also often have internet-capable computers, so a small group of students could, on the phone, ask lab personnel to move to some point on a sample and examine a specific crystal.

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In this electrochemistry activity, learners will explore two examples of electroplating. In Part 1, zinc from a galvanized nail (an iron nail which has been coated with zinc by dipping it in molten zinc) will be plated onto a copper penny. In Part 2, copper from a penny will be plated onto a nickel.

In this activity, learners conduct a simple experiment to see how electrically charged things like plastic attract electrically neutral things like water. The plastic will attract the surface of the water into a visible bump.