Goldfield, CO Mining Town. Western Mining History presents a brief summary of Colorado's Historical Mining Towns with links to additional Colorado resources for a mining town database and mines by county. Western Mining History is an historical site that provides information on mining, mining towns, the gold and silver rush, and Photos and maps of the western United States. This is a strong primary source resource that can be used for a variety of class research projects. Consider becoming a member or making a donation to help further the work of the site.

This exercise takes advantage of student's interest in Google Earth to teach some basic concepts about meandering rivers. Students prepare for class by reading about lowland rivers and/or hearing a lecture on them. They bring their own laptops to class or share with a partner or I take the entire class to the computer lab next door. In class they work through the worksheet and use Google Earth to take quantitative measurements of the rivers. They look at historic migration of meander bends and quantify river sinuousity, wavelength, amplitude, and radius of curvature of meander bends. They explore meandering bedrock rivers in Taiwan as a cool thought exercise in how that can happen. They end with looking at images from an area that they will have a field trip to during their next lab period. To keep people from flying through the exercise and getting bored, we do the whole activity in think-pair-share style. Students work on a location, answer the questions, and then we discuss it as a class.

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Gothic, CO Mining Town. Western Mining History presents a brief summary of Colorado's Historical Mining Towns with links to additional Colorado resources for a mining town database and mines by county. Western Mining History is an historical site that provides information on mining, mining towns, the gold and silver rush, and Photos and maps of the western United States. This is a strong primary source resource that can be used for a variety of class research projects. Consider becoming a member or making a donation to help further the work of the site.

The Museum's Gottesman Hall of Planet Earth allows visitors to explore geologic time and to gain an understanding of the methods scientists use to study vast Earth systems. This comprehensive guide to the hall's resources is designed to help you maximize your trip to the Museum with elementary school students. It includes detailed background information, a map of the hall that shows the five sections of the exhibit and several pre-, during-, and post-visit activities to do with your students. There is a listing of related Museum exhibits and suggestions for how to tie them into your field trip and notes about how the topics featured in the hall address performance standards and curriculum requirements.

The Grand Junction Gem and Mineral Club is a resource for the Grand Valley area of Western Colorado. Club members are available for speaking engagements, or visiting experts at schools. Use the contact form on the website to reach out about specific topics and available guest speakers. The club also sponsors the Grand Junction Gem and Mineral Show each year. They offer a free youth club called Jr Rock Hounds that has monthly meetings with activites and field trips. Visit the main site: https://www.grandjunctionrockclub.org/

Short history of Grand Junction in Grand Valley and historical timeline for Grand Junction with photos and diagrams.

To prepare for this project, students read a journal article about the processes and products of chemical sedimentation and early diagenesis in saline pan environments (Lowenstein and Hardie, 1985). In class, students are given some handouts that tabluate various evaporite minerals and how water chemistry affects their formation and dissolution. A short slide show and video illustrate some different types of saline environments. Photos and samples guide a lecture on the formation of different types of evaporite minerals and how they form. For example, chevron halite crystals are generally large (cm-scale) and grow upward from the floor of a shallow (less than ~0.5 m) surface water body; cumulate halite crystals are smaller (typically mm-scale) and grow on the water-air interface and settle to the bottom, regardless of water depth. Randomly-oriented halite crystals can grow displacively from groundwater in mud or sand. The students learn that the specific sedimentology of halite can be used to trace past surface water depth and groundwater salinity. I also give examples of how past quantitative climate data, past chemical data and even past microbiologial data can be interpreted from evaporites. I emphasize how, in order to understand evaporites, one must think critically about sedimentology and geochemistry.

The students are told, at the end of this lecture, that their next lab period will focus on designing and setting up a research project on growing salt. They are encouraged to start thinking about a research question they can pose about evaporite sedimentology. At this time, I also tell them what materials are available for their use (tap water, distilled water, seawater, various types of saline water I have collected during field trips, various types of store-bought table and road salt (including iodized, non-iodized, sea salt, etc.). A variety of table salts can be purchased cheaply (~$1 - $2/carton) at almost any grocery store. If you live in a cold climate, most grocery stores and hardware stores also sell several types of road salt (~$3-$4/bag). The table salts are mostly Na and Cl; some have lesser amopunts of Ca and SO4. Some road salts have Ca, Mg, Na, and Cl. In my experience, one carton and one bag of each type will provide more than enough salt for a class of 15 students.

When it is time for lab to begin, I gather my students in my research lab (but could also be done in a classroom), where I show them the materials I have available to them: various types of salt, various types of water, and plastic, glass, and metal containers of various shapes (baby food glass jars, plastic take-out food containers, etc). My lab also contains a variety of other miscellaneous materials, such as sand, gravel, clay, morter and pestle, wooden sticks, metal stirring rods, string, plastic tubing, beakers, food coloring (shows fluid inclusion bands well and everyone loves playing with food coloring), etc. I remind the students that they have a microwave oven, a freezer, a lab hood, a windowsill with plenty of sunlight, and a heating vent that can be used, as well. I make available a few thermometers, pH strips (or pH meter), and a hand-held refractometer for measuring salinity. These analytical field instruments are not neccessary for this assignment to work. However, as instructor, I would encourage you to use anything available to you.

I ask each student to tell me informally of their research question/hypothesis and then I try to help them find any materials they need for their experiments. Here are some examples of student research questions that have been tested with this assignment: (1) Does temperature of water affect rate of haite/gypsum growth?: (2) Will evaporite minerals grown from a complex saline fluid form a "bulls eye" pattern as their textbook claims?; (3) Will halite grow preferentially on glass substrates versus wooden and plastic substrates?; (4) Will evaporation of salt water make halite cement equally well in a gravel, a sand, a clay?; (5) What conditions best produce large halite crystals?; (6) Does pH of water influence halite and gypsum precipitation or dissolution?

Students spend most of a lab period (2-3 hours) setting up their experiment. As part of this initial experimental set-up, they start to learn basic research skills such as labelling samples well, documenting starting conditions, and taking detailed notes.

The students are allowed to leave their experiments on a windowsill in my lab or our classroom, on a radiator, in a lab fume hood, or in a lab refridgerator or freezer, depending upon the nature of the particular experiment. I encourage the students to check their samples on a daily basis and remind them to record their observations each time they check their experiment.

I give the students an assignment sheet that details the final lab report requirements. Most students will have results in 2-3 weeks, but some experiments may last up to 4-5 weeks. For this reason, I plan for this lab assignment to be started in the middle of the semester (which works well if your syllabus, like mine, calls for weathering, physical sedimentology, siliciclastics, and carbonates to be covered in the first 6-8 weeks of class; evaporites follow well after carbonates). The final lab report is not due until the end of the semester so that all students have time to bring their expermient to completion, make interpretations, and write their lab report.

At the end of the semester, depending on the number of students and time permitted, I ask the students to informally tell the class about their experiment and show the results. This has worked well for me. However, even in semesters in which we have not done this, the students still become familiar with each other's projects. On the initial experiment day, the students informally share their ideas. As students come to check on their own experiiments periodically, they usually look in on their classmates' experiments as well.

Students tell me that this is one of their favorite lab exercises. It encourages critical thinking and shows the importance of experimentation in science. In addition, I feel as if the students leave my course knowing more about evaporites than the average geologist.

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Guffey, CO Mining Town. Western Mining History presents a brief summary of Colorado's Historical Mining Towns with links to additional Colorado resources for a mining town database and mines by county. Western Mining History is an historical site that provides information on mining, mining towns, the gold and silver rush, and Photos and maps of the western United States. This is a strong primary source resource that can be used for a variety of class research projects. Consider becoming a member or making a donation to help further the work of the site.

Guston, CO Mining Town. Western Mining History presents a brief summary of Colorado's Historical Mining Towns with links to additional Colorado resources for a mining town database and mines by county. Western Mining History is an historical site that provides information on mining, mining towns, the gold and silver rush, and Photos and maps of the western United States. This is a strong primary source resource that can be used for a variety of class research projects. Consider becoming a member or making a donation to help further the work of the site.

Highland Mary, CO Mining Town. Western Mining History presents a brief summary of Colorado's Historical Mining Towns with links to additional Colorado resources for a mining town database and mines by county. Western Mining History is an historical site that provides information on mining, mining towns, the gold and silver rush, and Photos and maps of the western United States. This is a strong primary source resource that can be used for a variety of class research projects. Consider becoming a member or making a donation to help further the work of the site.

Short history of towns and locations in the Grand Valley. Links to more detailed information.

Learn how to build a strong foundation for your Bee Program! Our most successful programs begin with a layer of lessons and curriculum. Here we share exactly how to start a Bee Program and grow from the bottom up! Whether or not you have live bees on your campus, this will help to grow a community around your buzzworthy educational endeavors!

The folders in this Group will provide curriculums, virtual field trips with lessons, suggested Citizen Science Projects, book clubs for kids with lessons, and relevant webinars and recordings to help any educator deliver quality instruction. All of our offerings have teacher guides, are mapped to the standards, and are easily adapted to digital platforms.

We recommend the educator work through each level of the How to Start + Grow Your Bee Program Pyramid by exploring the offerings within each Folder. The resources build on each other as the educator and students move through this learning pathway.

Subject studies how and why machines work, how they are conceived, how they are developed (drawn), and how they are utilized. Students learn from the hands-on experiences of taking things apart mentally and physically, drawing (sketching, 3D CAD) what they envision and observe, taking occasional field trips, and completing an individual term project (concept, creation, and presentation). Emphasis on understanding the physics and history of machines.

Howardsville, CO Mining Town. Western Mining History presents a brief summary of Colorado's Historical Mining Towns with links to additional Colorado resources for a mining town database and mines by county. Western Mining History is an historical site that provides information on mining, mining towns, the gold and silver rush, and Photos and maps of the western United States. This is a strong primary source resource that can be used for a variety of class research projects. Consider becoming a member or making a donation to help further the work of the site.

Getting students to "put on paleontologists' hats" before their first fossil-hunting field trip allows for a more enriching field experience. Rather than handing out an instructor-prepared field guide (that few students read, anyway), the students essentially work up their own geologic/paleontologic interpretation of a site, using a custom toolkit they develop through classroom and homework exercises.
The activity begins with a worksheet that can be completed in groups during class (recommended) or as homework. Students are asked to imagine scenarios of fossil preservation, suggest factors that influence the completeness of the fossil record, and think of ways that fossil assemblages can give clues to the stratigraphic position and paleoenvironment of a rock formation. The instructor is involved as a guide, introducing concepts and terminology as needed. Students will also discuss -- with help from a textbook, specimens, or slide presentation - how the characteristics of major fossil groups might be used to identify a fossil in outcrop (for example, the coil of a gastropod, the pinnules of a crinoid).
Next, each student is assigned to be an expert on one taxon or faunal group that they will encounter on the trip. This requires reading a fossil identification guide or instructor-prepared handout. They will make an "expert's notecard" to bring along on the field trip, and will be expected to find and present examples of their fossil(s) on the field trip. The taxonomic level or groups assigned will vary depending on the fossil assemblage and the class size.
The activity culminates with the field experience, during which students keep a detailed field notebook (bringing along their in-class worksheets for reference). In the field, students will identify modes of preservation, assist one another as "experts" in fossil identification, and discuss the paleoecological and paleoenvironmental setting of the geologic section. After the field trip, the class compiles a faunal list for the site. Each student writes up an interpretation based on their individual observations and those made as a class.
This set of activities can be streamlined if, for instance, the field trip is only a small unit of a general geology course. Rather than using open-ended discussion questions on the preliminary worksheet, the instructor can assign reading or give a lecture that covers modes of preservation and other concepts that students will use to complete the worksheet. The goal remains, however, for students to think about what they will observe at the outcrop BEFORE they are on the rocks.

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Analyzing an outcrop for the first time is challenging for many students. In an effort to prepare students for their field trip, this exercise gives students practice with basic outcrop analysis before going into the field. Although this exercise is not a substitute for a field experience, it requires students to think about what they should be observing and noting at an outcrop before visiting an actual field site. First, students watch a short video tutorial on analyzing an outcrop. Then, they are given a color photograph of an outcrop and a hand sample and complete a field notebook entry for the outcrop.

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This assignment is designed to expose students in my undergraduate 3 credit non lab elective geohydrology course to a variety of hydrogeological environments and groundwater issues/problems that exist in the United States. Much of the course (field trip and local groundwater contamination case study) highlights and emphasizes understanding of the shallow unconsolidated aquifers in Michigan. Students use as their main source of information the data and illustration rich professional USGS Groundwater Atlases. Using this resource, in this activity students learn about the structure of aquifers in volcanic rock, karst and permafrost regions. They teach their fellow students about groundwater problems that result due due to overpumping, subsidence, sinkholes, saltwater intrusion and coal mining.

Key words:
hydrogeologic environments, water supply and water quality problems, aquifers

(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.)

Idaho Springs, CO Mining Town. Western Mining History presents a brief summary of Colorado's Historical Mining Towns with links to additional Colorado resources for a mining town database and mines by county. Western Mining History is an historical site that provides information on mining, mining towns, the gold and silver rush, and Photos and maps of the western United States. This is a strong primary source resource that can be used for a variety of class research projects. Consider becoming a member or making a donation to help further the work of the site.

In this project, students work in small groups to formally characterize an aspect of a local igneous rock, based on petrography, hand sample descriptions, and SEM and/or CL analyses. Students have two lab sessions and a field trip dedicated to working on this suite of rocks: one for detailed petrographic analyses and another SEM or CL imaging and analysis. The field trip is the field component of the project. The individual labs are ungraded, but all are required for completion of the project.

Papers must include the following sections:
Introduction, Geologic History, Petrography, Chemical Analysis, Discussion, References, Appendix (contains copies of ALL notes, calculations, drafts and revisions)

(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.)

Western Mining History presents Historical|Photographs of Colorado mining towns and mines. Western Mining History is an historical site that provides databases, information on mining, mining towns, gold and Photos and maps of the western United States. This photo gallery provide an excellent collection of primary sources for historical analysis in the classroom. Consider becoming a member or making a donation to help further the work of the site. Suggested use: Students might do a "then/now" comparison of well known towns, analyze the photos for historical details, consider the working conditions for the miners and/or environmental impact of early mines.