This contribution is modified from a published exercise "Directed Discovery of Crystal Structures Using Ball-and-Stick Models" [Mogk, 1997] . While the published exercise is based on student exploration of traditional ball-and-stick models of crystal structures, this modified version uses a similar "discovery-based" approach and the latest online crystallographic information and visualization software to teach the spatial relationships and crystal-chemical rules that govern the crystal structures of common minerals and crystalline solids. A few changes in the content have been made from the published exercise, mainly to accommodate the new digital media.

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In this series of exercises, a kind of reductionist approach is used to direct the students attention to specific characteristics of a variety of ball and stick models. Through a series of leading questions, students must focus on specific relationships and must rationalize these relationships according to the fundamental principles of crystal chemistry and crystallography. In this way, students will simulate and replicate the kinds of questions we would normally ask in our professional careers as mineralogists. This approach also addresses other major recommendations from Project 2061: start with questions about nature, and concentrate on the collection and use of evidence. Other questions ask students to make connections to basic chemistry (e.g. bond types, relative strength of bonds, bond angles), determinative mineralogy (most likely place to develop cleavage), analytical techniques (e.g. preferred orientations for X-ray analysis), and so on. The final reflection questions will allow students to "discover" Pauling's Rules, a much more effective learning strategy than simple memorization of these rules (commonly with little or no understanding on the part of the students).

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DATA: Sea Floor Age, Volcano and Earthquake Distributions. TOOL: My World GIS. SUMMARY: Identify relationships among sea-floor age, earthquakes, and volcanoes to understand how they support the theory of plate tectonics.

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DATA: MODIS Imagery. TOOL: ImageJ. SUMMARY: Examine images of the Aral Sea from 1973 through 2003. Use image analysis software to measure changes in the width and area of the freshwater lake over time.

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DATA: Ocean Buoy Data, MODIS Images TOOLS: GoMOOS Online Graphing Tool SUMMARY: Learn about conditions that influence the spring phytoplankton bloom. Use an online graphing tool to predict the date of the bloom.

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In this activity students explore the Earth's radiation budget using Earth radiation Budget Experiment (ERBE) data archived at the IRI/LDEO Climate Data Library (more info) .

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Electrochemistry has been undergoing significant transformations in the last few decades. It is now the province of academics interested only in measuring thermodynamic properties of solutions and of industrialists using electrolysis or manufacturing batteries, with a huge gap between them. It has become clear that these, apparently distinct subjects, alongside others, have a common ground and that they have grown towards each other, particularly as a result of research into the rates of electrochemical processes. Such evolution is due to a number of factors, and offers the possibility of carrying out reproducible, dynamic experiments under an ever-increasing variety of conditions with reliable and sensitive instrumentation. This has enabled many studies of a fundamental and applied nature, to be carried out.

The interactions of electrons with matter have great explanatory power and are central to many technologies from transistors, diodes, smoke detectors, and dosemeters to sophisticated imaging, lasers, and quantum computing. A conceptual grasp of the interactions of electrons in general allows students to acquire deeper understanding that can be applied to a very broad range of technologies.

Use a series of interactive models and games to explore electrostatics. Learn about the effects positive and negative charges have on one another, and investigate these effects further through games. Learn about Coulomb's law and the concept that both the distance between the charges and the difference in the charges affect the strength of the force. Explore polarization at an atomic level, and learn how a material that does not hold any net charge can be attracted to a charged object. Students will be able to:

Short Description:
Enhanced Introductory College Chemistry is a collaboratively created textbook with Georgian College, Loyalist College and Conestoga College supported by a VLS grant from eCampus Ontario. It is designed to address most chemistry topics covered in an introductory chemistry course in most program areas. Topics include measurement, matter, atomic theory, nomenclature, moles, chemical equations, stoichiometry, chemical bonding, gases, liquids, solutions, acids and bases, equilibrium and oxidation-reduction. Each chapter contains examples, relevant images, embedded videos, exercises and interactive exercises with answers, links to external interactive tools, glossary, and review practice questions with selected answers. A noted effort was made to include Indigenous examples to support chemistry learning as well as highlighting Scientists in Action. Extensive resources to support Indigenization of chemistry and Equity, Diversity and Inclusion in chemistry are provided in the front matter. Accessibility of learning material was addressed through descriptive alt-text and screen reader supported text wherever possible. NewParaAdditional resources of image banks for faculty are also available. Authors of this book will use portions of it for introductory chemistry courses in Biotechnology, Environmental Science, College and Career Preparation and Pre-Health Science programs.NewParaPublication date: February 28, 2023

Word Count: 317204

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Through an analysis of water quality in a nearby lake, students are introduced to basic chemical techniques such as titrations (both acid/base and oxidation/reduction), atomic absorption spectrometry, and uv/vis spectrometry

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This is a inquiry-driven class research project on a local environmental geochemistry question that is accomplished during three-hour laboratory sessions each week. Students are divided into groups that will share the responsibilities of collecting samples and data. Once the data is collected, it is shared among the entire class so that all students have the same data set. The class works on data presentation, preliminary analysis, and statistics together Then each student writes his/her own report separately.

Outcomes:

Laboratory skills -- Students have basic laboratory skills necessary to carry out a supervised geochemical study (e.g. can perform Gram titration of waters in field, can collect water samples using clean methods).

Quantitative methods -- Students can manipulate, sort, and transfer data in Excel and can create simple x-y plots and histograms to bring out trends in data.

Critical thinking -- Students can develop multiple hypotheses to explain trends in data and can design tests of these hypotheses.

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This activity is designed to get non-environmental majors to qualitatively examine their own community for evidence of environmental injustice. Using a mix of evidence from online sources (U.S. Census, EnviroMapper, Toxic Release Inventory, Office of the Superintendent of Public Instruction, etc.) and field observations, student groups describe the population and pollution sources found within an assigned elementary school district in Tacoma.

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Simple budgets may be used to estimate the exchange of water in embayments that capitalize on the concept of steady state and conservation principals. This is especially true for bays that experience a significant exchange of freshwater. This exchange of freshwater may reduce the average salt concentration in the bay compared to seawater if it involves addition of freshwater from rivers, R, and/or precipitation, P. Alternatively, it may increase the average salt concentration in the bay compared to seawater if there is relatively little river input and high evaporation, E. Since freshwater input changes the salt concentration in the bay, and salt is a conservative material, it is possible to combine two steady state budgets for a bay, one for salt and one for water, to solve for the magnitude of the water flows that enter and exit the bay mouth.
Students will make actual calculations for the inflow and outflow of water to Puget Sound, Washington and the Mediterranean Sea and compare them to actual measured values.

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In this computer lab, students use satellite imagery, daylength information, and phytoplankton physiology models to calculate annual primary production for an assigned ocean region.

Satellite data is obtained from the NASA Earth Observation website. Students use the analysis tool to determine chlorophyll concentration and sea surface temperature. They also receive a day-length calculator and are asked to model light transmission through the water column. Using step-by-step instructions and proviede equations relating phytoplankton physiology to irradiance and temperature students calculate carbon uptake at discreet locations in the water column. The second half of the exercise involves scaling up to the entire water column, region, and season. Students present their work to the class and evaluate their result using scientific literature. Differences between regions are then discussed by the class.

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Students use an EPA data set of Nevada mines to evaluate proximity of mine sites to streams to choose priority water sampling sites to evaluate for possible contamination. Students export data to Google Earth to use satellite imagery to narrow the priority sites further. You might also be interested in our Full GIS course with links to all assignments.

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Students do background reading on the atmosphere (see URLs below). The questions in this activity are divided up into atmospheric structure, stratospheric ozone, and acid rain. This activity helps students to understand the basic structure of the atmosphere as well as ozone and acid rain problems.

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The Basics of General, Organic, and Biological Chemistry covers general organic and biological chemistry concepts typically for one-semester chemistry courses.

This module consists of a laboratory exercise and related homework problems on geochemical kinetics of mineral-solution reactions for undergraduate mineralogy. Students measure the grain sizes of equant halite crystals, and the time for complete dissolution of each grain. From these data, students retrieve a rate law, from several possible. Additional homework problems allow various chemical and physical transport processes in mineral-fluid systems to be evaluated.

The lab and homework illustrate several basic principles of chemical kinetics directly relevant to geology, including rate laws of reactions, diffusion, advective transport, and the relationship between rate-limiting mechanisms and crystal-surface morphology.

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In this experiment, students use a solar cooker to model the greenhouse effect. Students collect, track, and compare data including insolation, ambient temperature, and water temperature with various instruments such as a pyranometer, thermometers, and temperature probes. They also develop their own experiments (incorporating set up, controls, data collection and presentation) to examine the strength of ultraviolet radiation from the sun with various protective materials using uv-sensitive beads. They must then analyze the data, finding correlations and conclusions, and determine the best way to present the results (tables, graphs, write-up).

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