lab assignments intended to teach the basics of reading phylogenetic diagrams and parsimony optimization.

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The first page of the presentation includes photos of 12 animals. I print this page, cut up the photos, and give a set of photos to each group of students. Working in groups of 2 or 3, the students spend ~10 minutes arranging the photos to depict the evolutionary relationships among the animals. This exercise is followed by 4 clicker questions about relationships that students commonly misconstrue due to convergence or shared primitive features. I use the clicker questions to initiate class discussion of group results. Then we discuss the evidence (anatomy, biochemistry) for current thinking about these relationships. Once we have established a consensus, students are asked to place pictures of a subset of the animals at the tips of the branches on a pre-designed cladogram. The activity gives me insight into students' preconceptions regarding vertebrate phylogeny, encourages students to identify their own misconceptions, promotes peer instruction and highlights problems associated with determining relationships based on shared primitive features. Placing the animals on a pre-designed cladogram allows students to translate their hypothesis about relationships into a visual diagram, an exercise that I hope will help students to extract the phylogenetic hypotheses depicted on cladograms in papers and textbooks. Once we have established a consensus cladogram, students must go one step further and add evidence (synapomorphies) to their cladograms. Students spend ~ 10 minutes brainstorming with their group to place synapormorphies at each node of the diagram. An example is provided for whales and hippos, groups for which the evidence of shared ancestry is difficult to recognize based on the anatomy of living specimens. After adding synapomorphies to their diagrams, students will work together as a class, contributing shared derived features to a group cladogram. If time permits, it would also be possible to complete the exercise with a gallery walk, where each group posts a copy of their cladogram + synapomorphies on the wall for other groups to examine and edit.

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Students observe clams (Mercenaria) in a salt water aquarium, paying attention to siphons and any burrowing. They then remove the clams and describe the external morphology. The clams are then dissected, with special attention made to features (siphons, muscles) that leave observable marks on the shells. They are then provided the shells of a different genus (Mya) and asked to predict the soft tissue morphology and life mode.

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Students in a groups determine which everyday objects are related to each other.

This worksheet walks students through how to use the igneous rock composition chart to identify rock types. Students are shown three different rocks and given the mineral percentages for each. Using the mineral percentages, student build a scale bar using colored segments to show the amount of different minerals. Students can then move their scale bar with the colored mineral segments across the igneous rock composition chart until the boundaries in the scale bar match the mineral field boundaries on the chart. Once the student finds a match, the student can see whether the rock is a granite, diorite, gabbro, or peridotite.

This worksheet allows students to complete this task physically, rather than mentally, and walks them through the process of igneous rock identification based on mineral composition. We find that it also makes the chart more understandable and approachable.

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 the CogSketch website: 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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In this activity students will observe and investigate rocks in order to classify them in terms of color, shape, texture and size.

This activity is a field investigation where students gather leaves from various trees on school property, interpret findings, name tree and leaves, journal activity and develop a new "aha" for nature!

This activity is a classroom and schoolyard investigation where students collect daily temperature and precipitation readings, weather observations, and weekly phenology reports in a phenology binder and in nature journals. Students then analyze this data and compare to recorded values in the Weatherguide calendar.

In this problem-based learning activity, students develop a case study that "puts a human face" on the effects of global climate change (GCC) on a particular community in the United States. Students work in teams to: discover cultural, economic, and natural features of the community; identify challenges presented by GCC; and identify options for responding to these challenges.

This activity is designed to help students visualize and explain the relationships between various terms and concepts related to the science of climate change. After performing this activity students will (hopefully) be able to define various climate change terms and explain the process of climate change.

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Average inquiry level: Guided inquiry
In this laboratory exercise for introductory geology or environmental science courses, students use data to examine climate change in their local environment. They compare local changes to global data over different time scales. As an assessment, students create an infographic to demonstrate their understanding of how local climate change may affect their region and what people can do to be better prepared. This lab was originally designed for online instruction, but may be used in face-to-face instruction as well.

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Students are asked to make a general hypothesis about whether Atlantic hurricane have been changing over time in response to recent climate change. It is expected that at an introductory level with only the most basic background instruction, students will focus on numbers, locations, or intensities of hurricanes. Example hypotheses might be

The numbers of hurricanes are increasing (or decreasing)
Hurricanes are becoming more intense
Hurricanes are forming in new locations
Hurricane season is lengthening

They are then asked to develop more pointed questions that they can test. Some example questions for each hypothesis are given below:

Hypothesis 1 might lead to questions like "More hurricanes (or tropical storms) are forming each year" or "More hurricanes are striking land each year."
Hypothesis 2 might lead to questions such as "The maximum wind speed for hurricanes is increasing" or "The minimum barometric pressure is decreasing."
Hypothesis 3 might lead to questions like "Hurricanes are forming further north."
Hypothesis 4 might lead to questions such as "Hurricanes are forming earlier and later."

To answer these questions would require students to understand some background about hurricanes, like how many typically occur in the past (which leads to questions about data collection and observing hurricanes), how hurricane intensity is measured, or at what latitudes hurricanes typically form.

Then they are given a table or map data (derived from NOAA GIS data of hurricane tracks and intensity) to test their hypotheses.

The results of their inquiries and data collection will be shared with the class as parts of small groups initially, and will culminate as a small group presentation.

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Students will learn how species shift along environmental gradients (temperature, precipitation, and vegetation) in response to climate change over the last 20,000 years, from the time of the Last Glacial Maximum through deglaciation and the Holocene. The activity involves making maps of species distribution using the Neotoma database. Students will develop skills in data analysis and interpretation over a two-to-four class arc.

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In this 50-minute guided lecture, students learn the peculiar threats to migratory animals, given the projected spatial variability of climate change on the planet. This activity uses a climate departure analysis to assess threat to the monarch butterfly.

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Students will learn about the physical changes occurring in the Arctic and the local and global physical, climatic, and human impacts of these changes.

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Students engage in a discussion about climate change by both watching videos and reading an article to learn about the science behind climate change and some of the impacts of our warming climate. They then post their reflections, including at least one question, to a class discussion board. They also respond to at least two of the posts from their peers, citing evidence in their responses.

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In this activity, students explore connections between climate change and the cryosphere. In Part A, they learn about how scientists study past climate records using ice cores. In Part B, students examine the role ice melt might play in future sea level rise due to climate change.

Introduction:
Groundwater is key to Texas future and economy. The resource has long been a focus of legislative and economic interest. In the earliest days, the resource was viewed as 'occult and hidden.' That sense of mystery remains even as groundwater becomes more critical to the water resource picture for the state.
Since 1951, the state conducts regional water planning with the involvement of citizen stakeholders. Let's use your science-based knowledge of groundwater flow to see if you can find the right balance for both protecting and planning for groundwater use.
Our Case:
This week we will evaluate a historic court case from June 13, 1904. The case of East versus Texas Central Railroad Company is the Texas Supreme Ruling that provides the foundation for Texas groundwater law -- Rule of Capture.
In the appendix, you will find the following figures to help you determine whether or not Mr. East's well was impacted by the railroad company's pumping:

Platt map showing well locations and possible distances
Schematics of the well dimensions, along with simplified subsurface geology in the area.

In addition, you will be interested in knowing that the Geologic Atlas of Texas shows that the wells were likely completed in the Pawpaw Formation, which is a thick calcareous clay unit in the lower sections and cemented sand in the upper part. Lithologies in the area are reported to yield limited to moderate amounts of water in shallow wells. You can expect that the formation was an unconfined unit and assume that the East well is down-gradient from the Railroad well.
Assignment Part One:

1. Using the information from our last lecture, what do you think a reasonable transmissivity rate might be for the Pawpaw formation?

a. Estimate a transmissvity for a cemented sand unit.
b. Use this value as your first estimate in calculations to calculate the potential drawdown with Jacob's equation. This calculates the drawdown in an nonleaky artesian aquifer, sa, given the observed water table drawdowns.

sa = swt -- (s2st/2m)

c. Calculate swt using a correction equation.

Swt = m-(m2-2msa)1/2

Where m is the initial saturated thickness, which you may estimate at 30 ft.

2. How much water do you estimate that the railroad can extract before the well is impacted? Complete a diagram showing estimated drawdown (ft) on the y-axis and distances from the Railroad well (ft) using different transmissivity values and different distances. What do you discover about the case?
3. With your hydrogeologic analysis, do you believe that the East well was impacted by the railroad well? Can you explain how significant the impact may or may not have been?

Climate Considerations:
Is it possible that climate conditions could have impacted conditions in the well? Visit the Greenleaf website ([greenleaf.unl.edu/downloads/scPDSI.zip]) and access data for Palmer Drought Severity Indices. Looking at this data, complete the next questions.
Assignment Part 2:

4. Looking at the drought severity index maps of Texas from October 1900 to September 1902. What kind of implications might climate conditions have had on the groundwater conditions?
5. If climate conditions worsened, what do you think would happen to the wells?

Reference:
Mace, R.E., Ridgeway, C., and Sharp, J.M., 2004, Groundwater is no longer secret and occult - A historical and hydrogeologic analysis of the East case, 100 Years of Rule of Capture: From East to Groundwater Management, ed. Mullican, W.F. and Schwarz, S., Report 361, Texas Water Development Board, 63-86 pp.
Appendix -- support documents:
Figure 1 shows that Mr. East lived in Denison County, TX. The inset is a plan view map showing the potential locations of the wells in the town.
(in supporting documents)
Figure 2: Schematic of well dimensions and simplified geology.
(In supporting documents)

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Students will study how temp and concentration affect reaction rates and then design a procedure to get the reaction to occur in a specified amount of time.

This flash animation for the song "Closer to Free" describes the Economic Freedom of the World index, provides a summary of countries with high and low values of the index, and highlights the importance of economic freedom in a country's standard of living.