This module examines the nature and variability of subduction margins through examination of data sets that document subduction zone inputs, deformation, and resulting morphology in different settings.

In EARTH 801, you will develop skills in a programming language designed for visual arts and visualization while exploring Earth science topics. Specifically, you'll learn and practice digital graphics capabilities in order to render Earth science concepts that are otherwise difficult to visualize due to complicated space and time scales. Here, you will interact with large, open, freely-available data sets by collecting, plotting, and analyzing them using a variety of computational methods. You'll be ready to teach secondary school students a range of Next Generation Science Standard skills involving data collecting, manipulation, analysis, and plotting. You'll also read and discuss current research regarding the teaching, learning, and evaluation of visualization skills, as well as multiple external representations of science concepts.

Think science has all the answers? Think again. This course will use real, authentic data to explore and investigate modern controversies in Earth Sciences. Use tide gauge records to understand how countries around the world attempt to protect themselves from tsunami events. Process seismic data to predict earthquake recurrence in the New Madrid seismic zone, right here in the breadbasket of the US. Sort through the millions of years of the geologic timeline to shed some light on what actually did, and did not, kill the dinosaurs. Finally, use global atmospheric data to understand how misrepresentation of data can be used to paint a distorted view of past, present, and future climate.

The year is 2050 and your once-idyllic beachfront vacation home is now flooded up to the second story. The crab your family has enjoyed every Christmas for as long as you can remember has now become an endangered species. The oceans have changed. In Earth 540, Oceanography for Educators, we explore the mechanisms that lead to sea level rise and ocean acidification. We strive to understand how natural processes such as ocean currents, the gulf-stream, tides, plate tectonics, and the Coriolis Effect, affect our oceans and ocean basins. We then predict how man-made issues such as climate change and overfishing will affect our beloved waters and our livelihoods. Want to see into the future? Then this course is for you!

Students do background reading on the possible origins of intraplate seismicity and also read Nuttli's 1973 paper on the 1811-1812 New Madrid sequence. They construct frequency magnitude diagrams using data they acquire themselves from the openly archived University of Memphis catalog, Southern California Earthquake Center catalog, and USGS global catalog. They use these diagrams to estimate a recurrence interval for large magnitude earthquakes at the NMSZ. They then split into teams to read papers detailing campaign GPS surveys, paleoseismic measurements, and heat flow measurements. Each team is responsible for summarizing their set of papers for the other students. The culminating assignment is to update Gomberg and Schweig's 2002 USGS pamphlet "Earthquake hazard in the heart of the homeland" using scientific results that postdate the original pamphlet (including their own analysis). We also end with a "teaching and learning discussion" in which the students, who are usually high school teachers themselves, trade ideas about how they could repurpose parts of the lesson for use in their own classrooms. This activity gives students practice in data analysis and reading scientific papers, it shows them a few resources where they can find openly available data, and it gives them a chance to participate in the practice of science.
Teaching Tips
Adaptations that allow this activity to be successful in an online environment
This lesson was constructed specifically for an online course and didn't exist beforehand. I think it could work in a face-to-face course, too.
Elements of this activity that are most effective
Students,especially ones who are not as literate with software plotting / analysis programs, find the problem set somewhat difficult because the datasets are large and I am asking them to collect the data themselves, then use it to make a second-order plot and analyze that, instead of just plotting "A" vs. "B" and analyzing it.

That being said, I know that students are excited to be able to produce a plot themselves that exactly mimics one they can find in a published paper, and furthermore they are happy to find resources such as the USGS earthquake catalog that contain available real-time data.

The part where they have to compare and contrast the strengths and weaknesses of each technique used to study the NMSZ (seismology, paleoseismology, GPS, etc) is important because they get a real sense of how different approaches are important to resolve a scientific debate. I know they are learning something when they get frustrated because there isn't an easy answer!
Recommendations for other faculty adapting this activity to their own course:
-Be prepared to help students get through the technical aspects of some of the scientific papers, especially if they are not used to reading scientific papers. When I pick the papers for them to read, I purposely pick ones that aren't too long (Science, Nature, GRL, etc) and I try to pick ones that came with a press release, "news and views" or similar, and then I tell the students to read the press release first and then the paper.

-Be prepared to give students hints about counting and sorting data to make the frequency-magnitude diagrams because you'd rather lead them towards how to make the plots and then let them get on with the analysis as opposed to letting them get so frustrated with their lack of technical skills that they aren't interested in the science anymore. This exercise should be about seismology; it shouldn't be an excel tutorial! I have a little set of screen capture movie how-to hints under a hidden url, and when I can tell that a student is really suffering I reveal them.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

In this activity, students will calculate the index of refraction of water by measuring the angles of incidence and refraction of light as it passes from air to water. They will follow directions to set up the experiment with cheaply available materials, make several measurements, then answer follow-up questions regarding the mathematical relationship between angles of incidence and refraction, experimental error and uncertainty.

In this course we will explore topics from disciplines within the solid Earth sciences. In each lesson, we'll also touch on some ways the topic links to other scientific disciplines. Each unit is designed to present both the cutting-edge science as well as the background a secondary-school student (or her teacher) would need to place the research in context. Gaining an appreciation of how scientists choose the subjects they study is as fundamental to Earth science as the discovery of the facts themselves. You will learn appropriate state-of-the-art scientific content relevant to each topic by performing basic data analysis using publicly available data so that you will be able to use the data and lessons in any courses you teach.

In this activity, students retrieve two short papers from Penn State's library e-reserves, read them, and spend a week discussing them with their classmates and me. They reproduce three plots with graphing software of their choice and submit their plots to an electronic dropbox. They take a quiz housed within Penn State's course management system. As part of this quiz, they use an online drawing tool to sketch a diagram.
Teaching Tips
Adaptations that allow this activity to be successful in an online
environment
This activity was created specifically for an online course. As more and more face-to-face courses incorporate technology for reserved reading and turning in assignments, this kind of activity could be useful an any course.

Elements of this activity that are most effective
This activity is extremely instructive for me to have an early gauge regarding the skill level of my students in terms of general online savviness as well as a bit about their quantitative skills and content knowledge.

Recommendations for other faculty adapting this activity to their
own course:
Make sure you tailor an activity like this one to your own specific course management system. I also recommend making it completely low stakes. I grade only on participation. Log in frequently during this activity to offer help, advice, and encouragement because this is very important at the beginning of an online course when there is the most confusion. I usually make this activity last for the first whole week of courses in case some students register at the last minute.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

Students explore the VEPP website and complete a two-part problem set in which they work through the ideas presented in an EOS paper regarding eruptions at Kilauea and they try to find a deflation-inflation event using the VALVE3 software.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

Introduction to the different types of slip behaviors that can occur on subduction thrust, and comparative analysis of data sets derived from earthquakes and slow slip events to learn to discriminate among events.