In order to assist educators with the implementation of the Common Core, the New York State Education Department provides curricular modules in P-12 English Language Arts and Mathematics that schools and districts can adopt or adapt for local purposes. The full year of Grade 7 Mathematics curriculum is available from the module links.

Find the rest of the EngageNY ELA resources at https://archive.org/details/engageny-ela-archive .

In order to assist educators with the implementation of the Common Core, the New York State Education Department provides curricular modules in P-12 English Language Arts and Mathematics that schools and districts can adopt or adapt for local purposes. The full year of Grade 7 Mathematics curriculum is available from the module links.

Find the rest of the EngageNY ELA resources at https://archive.org/details/engageny-ela-archive .

In order to assist educators with the implementation of the Common Core, the New York State Education Department provides curricular modules in P-12 English Language Arts and Mathematics that schools and districts can adopt or adapt for local purposes. The full year of Grade 7 Mathematics curriculum is available from the module links.

Find the rest of the EngageNY ELA resources at https://archive.org/details/engageny-ela-archive .

In order to assist educators with the implementation of the Common Core, the New York State Education Department provides curricular modules in P-12 English Language Arts and Mathematics that schools and districts can adopt or adapt for local purposes. The full year of Grade 7 Mathematics curriculum is available from the module links.

Find the rest of the EngageNY ELA resources at https://archive.org/details/engageny-ela-archive .

In order to assist educators with the implementation of the Common Core, the New York State Education Department provides curricular modules in P-12 English Language Arts and Mathematics that schools and districts can adopt or adapt for local purposes. The full year of Grade 7 Mathematics curriculum is available from the module links.

Find the rest of the EngageNY ELA resources at https://archive.org/details/engageny-ela-archive .

In order to assist educators with the implementation of the Common Core, the New York State Education Department provides curricular modules in P-12 English Language Arts and Mathematics that schools and districts can adopt or adapt for local purposes. The full year of Grade 7 Mathematics curriculum is available from the module links.

Find the rest of the EngageNY ELA resources at https://archive.org/details/engageny-ela-archive .

This is a lab/project in which the students not only name and identify a suite of granitic rocks but try to piece together the tectonic and geologic history of the Idaho batholith. This activity brings together the process of naming rocks, determining the I-, S- and A-type nature of the rocks, estimating magma source and potential assimilants, a nonquantitative depth of intrusion for the suites, and any distinctive textures that might help tell the story of the batholith. It forces students to move outside the rock in a box lab for granites and create a regional geologic history.

I find this project to work well in class for a number of reasons. Group work and counting on your classmates to interpret the rocks is a foundation of the entire project. The students get exposed to more rocks than in a typical lab without having to identify each of the in great detail since they are ultimately only responsible for their own suite. I have removed at least one lecture on granites and replaced it with this project for them to do the interpretation themselves rather than just passively absorb the geology.

The students have just a basic introduction to I-, A- and S-type granites and the models for the generation of these magmas. They have already learned about grain size relating to cooling rate and depth of intrusion, but it usually is awhile since they thought about these concepts.

Obviously this project depends on the exact samples being available, but the theory of the project can be applied to numerous geologic settings.

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The purpose of this gravity/magnetic mapping project is to have the students conduct a research/consulting project from start to finish. They are expected to design the project (submit a proposal), implement (collect data) the proposal, process the data, analyze and interpret the results and report their findings. Working in teams, they have to budget their time, assign tasks and get the job done on time. The process is as important as the science, however they have make quality assessments of the data they have collected and justify their interpretation of the data using accepted scientific/geologic principles.
Uses geophysics to solve problems in other fields

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This course introduces students to basic rain garden design, water cistern development, and bioretention principles. Students will also explore the uses of landform, plants, and structure to shape space. Classes will include slide-illustrated lectures, class discussions, and project critiques. Through a combination of short practicum that includes rain garden design for residential, commercial, and government locations, students will be able to analyze and create a design that applies modern theories to questions of spatial organization, order, and selection of building materials. Students will translate research and case studies by applying building, drawing, and design critiques specific for the site design and present their findings to the community.

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An online German grammar reference, featuring zany post-modern Grimm's fairy tale characters, authoritative grammar explanations, self-correcting exercises, online audio and cartoon images.

Working in teams, the students begin by conducting a vertical resistivty sounding to determine the depth to the water table. This can be checked because the survey is done in the middle of an existing well field. Using the depth determined, the students then conduct the equivalent of horizontal resistivity survey using a fixed "a" spacing. Instead of making a map they collect data at 10-degree intervals rotating the array around a central point. This provides them with information about how the resistivity varies with magnetic bearing and they then have to relate that to an interpretation of the local structure (fracture patterns). Each student has to submit an individual report which includes an interpretation of the data.
Uses geophysics to solve problems in other fields

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In class, instructor provides background on groundwater-surface water interactions, defines the hyporheic zone, and describes why knowledge of the HZ is important for both hydrology and ecology.

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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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POGIL is a research-based instruction strategy comprising peer learning, development of process skills, and activities that are designed around the constructivist theory of learning cycles (pogil.org).

Guided Inquiry Activities for Programming Language Concepts is a collection of activities intended to support the use of POGIL in intermediate-level undergraduate computer science courses on functional programming and the implementation of programming languages.

Disclaimer: These activities have not yet undergone the peer-review process of The POGIL Project and so cannot be labeled "POGIL activities" ; however, they are designed based on the POGIL approach to designing activities.

This is a sequence of assignments for my Structural Geology course that guides students through the process of critically reading and analyzing scientific journal articles. For each article, I outline the general questions they should try to answer as they read any journal article, then give specific versions of each of those questions for the particular article assigned. For the last article, I leave it to the students to figure out what the specific versions of the questions would be for that article. The general questions are:

1. What basic research question are the authors trying to answer?
2. What makes that research question significant? (That is, why try to answer that question? Why does it matter?)
3. What data did the authors collect?
4. What is the authors' interpretation of their data?
5. Do you think that the data they collected supports their conclusions? Why or why not?

While the handouts below are specific to the articles we read in my class, these questions could be re-framed for any scientific journal articles that you would like your students to read and understand.

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In this activity students work in groups to investigate the problem of Gulf of Mexico hypoxia before developing mitigation strategies based on local contriubtions to the problem. The students present their ideas in a public meeting debate format from which a solution must be selected by the entire class.

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Students are presented with a scenario (problem) to recommend whether the Gulf Stream is responsible for keeping Europe warm and the potential effects if polar ice were to continue melting. The students work in small groups and discuss the problem and identify the issue. They then list everything they know about the issue and develop a problem statement. They then ask what they need to know to solve the problem and search the Internet data sites, etc., and analyze the information gathered. They complete the activity by preparing an individual report and PowerPoint presentation where they make a recommendation or other appropriate resolution of the problem based on the data, visualizations, and background information.

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A collection of eight art lessons (puppets, visual arts, music) that integrate social emotional learning for grades K-2. Written lessons provide step-by-step instructions to be done at home. Lessons were created by Arts Corps teaching artists. Lessons are available in English and in Spanish.

Minerals are inorganic chemical compounds with a wide range of physical and chemical properties. Geologists frequently measure and observe properties such as hardness, specific gravity, color, etc. Unfortunately, students usually view these properties simply as tools for identifying unknown mineral specimens. One of the objectives of this exercise is to make students aware of the fact that minerals have many additional properties that can be measured, and that all of the physical and chemical properties of minerals have important applications beyond that of simple mineral identification.
Please do not let the title of this exercise scare you away. Introducing students to thermodynamics is not the primary objective. Getting students to "do" science - to observe, record, and interpret experimental data - is the primary goal. Heat capacity just happens to be a good vehicle for this purpose.

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To prepare for this project, students read the chapter on volcanoes in Grotzinger et al. In class, students receive specific instructions on what to include in their report, presentation as well as a specific volcanic eruption to investigate. Students individually research the volcanic eruption to learn more about a topic of interest to most students as well as to learn how to do research and how to write a paper. In the group project, they learn how to make an effective presentation. This presentation is self-contained and is supposed to be geared to a middle school audience. Some students do a very good job at explain the basic concepts to a student in that age group which means they really understand it.

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