This course is the capstone of the business major, because it incorporates elements from all of the core courses you should have already completed. Almost every topic should be familiar to you to some degree; however, Strategic Management ties them all together. This course begins with an introduction to the field and the definition of some important terms and concepts. You will then move on to identifying goals and formulating strategies before addressing implementation topics. This course will conclude with strategies for the 21st century. This course should be taken after all core courses have been completed and, ideally, near the end of your completion of the elective courses.

A free online simulation that demonstrated the bull-whip effect, and the complexities of supply chain management, responding to changes in customer demand.

In microeconomics, supply and demand is an economic model of price determination in a market. It postulates that, holding all else equal, in a competitive market, the unit price for a particular good, or other traded item such as labor or liquid financial assets, will vary until it settles at a point where the quantity demanded (at the current price) will equal the quantity supplied (at the current price), resulting in an economic equilibrium for price and quantity transacted.

Project Description (Microsoft Word 14kB Jan26 10)
Water collection and usage in the Sustainable SW Japanese Garden

The Albuquerque Water Authority has several activities on their web site to help with making a personal water audit, selecting xeriscape plants, designing garden areas as well as forms for rebates. We used the ABQ Water Authority design format to calculate which plants to install. Students start with a personal water audit and then move to the design of the garden.
Personal water audit http://www.abcwua.org/Understanding_Your_Bill.aspx
Techniques to consevere water outdoors http://www.abcwua.org/Save_Water_Outdoors.aspx
Planning Xeriscape - students create their own personal garden and we transfer the concepts to the Japanese Garden. We are looking at Japanese design elements with a SW flare and thereby modeling what the internees did when they were limited to the surrounding rock, vegetation and water collection. http://www.abcwua.org/Xeriscaping.aspx

Calculating roof area using a Google satellite image

We use a measurable square on the pathway for the scale and then we calculate the square feet of the roof area. A transparency is used to overlay the image and calculate the water harvest.

Calculating the capacity of the 1500 gallon cistern in terms of water needed per plant

Students experiment with buckets to see ascertain the best collection site. The water is measured after rainfalls and compared to the weather data collected by the NOAA.

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To prepare to view the TCE animation, students could view the 'A Civil Action' movie and the instructor could read to them excerpts from the trial testimony and images from Woburn, wells G and H, geologic materials, geologic cross sections, the trial participants, and the federal courtroom in Boston (available as a attachment to this activity and at a website listed below). The discussion in Bair (2001) about scientists in the courtroom, the specific (excerpted) testimony presented by the three expert witnesses in the 'A Civil Action' trial, a chart summarizing the differences in their testimony, and the views of a federal judge on the goal of science versus the goal of a civil trial may also be worthwhile reading by the class prior to the assignment.

The instructor could also show students the large plates included in the USGS report by Myette and others (1987) that display potentiometric data and contours before and after the famous aquifer test performed in December 1985 and January 1986, just before the trial, and discuss the ramifications of having only two sets of water-level measurements to characterize all the changes in the flow system between 1964 and 1979, when wells G and H periodically operated. This makes students consider the substantial differences in making predictions based on a steady-state conceptualization of the flow system or a transient conceptualization.

The instructor could also show the animation of induced infiltration from the Aberjona River to wells G and H that also was created by Martin van Oort (M.S., 2005) and based on the research of Maura Metheny (M.S., 1998; Ph.D., 2004) at Ohio State University. Viewing both animations enables students to see that the water produced by wells G and H is a highly transient mixture derived from many different source areas within the valley.

The article by Bair and Metheny (2002) concerning the remediation activities at the Wells G & H Superfund Site could be used to show how groundwater contamination is cleaned up, why different remediation schemes needed to be used in different hydrogeologic settings, and why cleanup to U.S. EPA standards can take decades.

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For farmers, growing crops is just one step in running a successful farm—making the farm or market garden economically viable requires another suite of skills, including finding land, planning what crops to grow, marketing the crops, and managing income and expenses. This resource builds on our experience educating hundreds of apprentice growers in organic production, farm and business planning, direct marketing at a roadside farm stand, and Community Supported Agriculture (CSA) management through hands-on training in the running of our 100-member CSA program. Teaching Direct Marketing and Small Farm Viability: Resources for Instructors is organized into six units, three focusing on marketing and three covering other topics related to making a small farm economically viable. Included are lessons and resources for running a CSA project, selling at farmers' markets, forming collaborative marketing groups and grower cooperatives, and selling to restaurants. Also covered are strategies to improve small farm planning, including enterprise visioning and market assessment; creating a business plan, including marketing and crop plans; and managing cash flow. Land tenure options such as cash-rent leases from non-profits, shared ownership models, conservation easements, and community land trusts are reviewed as additional mechanisms for addressing the complex issue of the economic viability of small-scale agriculture. This resource also reviews the trends and factors that influence small-scale agriculture's economics, and provides an overview of produce marketing in the U.S. The training manual is designed for – •Instructors at college and universities, agriculture organizations, farm-training programs, apprenticeship programs •Agricultural extension personnel •Farmers with interns •Growers, teachers, and organizers at urban farms, community gardens, and food projects with direct-marketing outlets This instructor's resource features class and field demonstration outlines, trainee exercises, and resource materials, with a focus on CSA. The manual can be used in a classroom setting or adapted for other training formats, such as short courses, conferences, and field days.

This course uses Lean Launchpad for creating entrepreneurial ventures that start small but can be scaled up fairly quickly. You should you take this class only IF you are interested in creating such ventures. This course provides real world, hands-on learning on what it's like to actually start a high-tech company. This class is not about how to write a business plan. It's not an exercise on how smart you arein a classroom, or how well you use the research library to size markets. This is a practical class essentially a lab, not a theory or "book" class. Our goal, within the constraints of a classroom and a limited amount of time, is to create an entrepreneurial experience for you with all of the pressures and demands of the real world in an early stage start up.

Technology has changed dramatically over the last couple of decades. Currently, virtually all business industries are powered by large quantities of data. The potential as well as actual uses of business data, which oftentimes includes personal user data, raise complex issues of informed consent and data protection. This course will explore many of these complex issues, with the goal of guiding students into thinking about tech policy from a broad ethical perspective as well as preparing students to responsibly conduct themselves in different areas and industries in a world growingly dominated by technology.

This single instrumental qualitative case study explores and thickly describes job performance outcomes based upon the manner in which self-directed learning activities of a purposefully selected sample of 3 construction managers are conducted, mediated by the use of Web 2.0 technology. The data collected revealed that construction managers are concerned with the performance expected of them, in addition to how well they perform their work-related activities (orientation to learning), indicating that organizations should provide guidelines on the use and expected outcomes of self-directed learning in addition to providing the tools, resources, and time (environmental factors) to match performance needs; construction managers feel that work-related activities expected of them, how well the work-related activities are performed, and consequences for poor performance at work are determining factors in selecting Web 2.0 technologies; while construction managers understand the need for rules restricting the use of Web 2.0 technologies in performing their jobs, they feel these rules do hinder their performance because access to specific information they need to answer a question, solve a problem, or research to learn something new is sometimes restricted; and successful performance outcomes are determined by compliance to expected performance behaviors of others, such as answering a question or solving a problem an architect or superintendent have presented, as well as expectations construction managers have set for themselves. The following are appended: (1) Call for Participation--Web 2.0 Technology Project; (2) Informed Consent Letter and Form/Template; (3) Semistructured Interview Guide; and (4) Permission to Conduct Research Study.

This unit introduces the hydrological cycle to provide context for the module as a whole. It particularly focuses on those portions of the hydrological cycle that take place on land and that form the basis for water that is used by society. Students conduct a stakeholder analysis to better understand societal issues around water. Then the scientific exercise of the unit emphasizes quantitative approaches to describing the critical portions that humans have access to: surface water and shallow ground water. Students calculate residence times and fluxes between reservoirs and track water particles on an annual basis. They also explore available data sets for specific reservoirs such as snowpack and rivers.

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Online-adaptable: This exercise could be converted to online whole-class discussions/lectures and a breakout group activity. Would be best done synchronously.

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In this three to four class unit, students will:

Assess the case for a global water crisis and its relevance in America.
Expand their understanding of sustainability as a contestable concept and movement.
Consider water resource-management objectives through the lens of sustainability.
Analyze region-specific examples of unsustainable use of water for agriculture.

This is largely achieved via student discussion and evaluation of texts and statistics provided to them. The text and statistics are derived from a variety of disciplines, mostly not from the geosciences. As such, the unit is very interdisciplinary, requiring students to synthesize disparate information and take a holistic perspective on water issues.

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In Unit 2, students learn how the techniques for water budgeting (covered in Unit 1) can be used to monitor both groundwater (High Plains Aquifer) and surface water (western mountain watershed) systems. Students interpret time-series plots that show the impact of drought years and wet years on underground water storage in the High Plains Aquifer and on snowpack and surface runoff in the western mountain watershed. They also consider the societal implications of water deficits through a series of pre-class readings, questions embedded in the assignments, and small and whole-group discussions. This unit can involve substantial computer time during which students use Excel to view and interpret hydrologic data. An alternative version with hard-copy graphs is also provided.

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Online-adaptable: Both parts of this unit are completely digital and thus at a logistical level it can be switched to online fairly easily. However, due to the relative complexity of the data investigations, there will still be quite a bit of instructor support needed and/or extended small group that should be arranged.

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Unit 2 opens a window into water accounting and reveals intensive water use that few people think about. How much water goes into common commodities? Have you considered how much water it takes to support our modern American lifestyle and agricultural trade? Water that is embedded in products and services is called virtual water. Looking at the world through the lens of virtual water provides a watery focus to thorny discussions about water such as: the pros and cons of globalization and long distance trade; self sufficiency vs. reliance on other nations; ecosystem impacts of exports; and the impacts of relatively cheap imports on indigenous farming. Unit 2 also introduces the concept of a water footprint. A water footprint represents a calculation of the volume of water needed for the production of goods and services consumed by an individual or country. In this unit students will calculate their individual footprints and analyze how the water footprints of countries vary dramatically in terms of gross volumes and their components. As a result of these activities, students will learn of vast disparities in water access and application. They will also be challenged to consider mechanisms or policies that could foster greater equity in water footprints.

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This unit shows how GPS records of surface elevation can be used to monitor groundwater changes. Students calculate secular trends in the GPS time series and then use the original and detrended records to identify sites that are dominated by the elastic response to regional groundwater changes versus those dominated by local subsidence. They then compare the magnitude and timescales of fluctuations in Earth's surface elevation that result from sediment compaction, regional groundwater extraction, and natural climatic variability. This unit provides students with hands-on experience of the challenges and advantages of using geodetic data to study the terrestrial water cycle. The case study area is in California and the GPS records include the period of the profound 2012 -- 2016 drought.

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Note: Although the term GPS (Global Positioning System) is more commonly used in everyday language, it officially refers only to the USA's constellation of satellites. GNSS (Global Navigation Satellite System) is a universal term that refers to all satellite navigation systems including those from the USA (GPS), Russia (GLONASS), European Union (Galileo), China (BeiDou), and others. In this module, we use the term GPS even though, technically, some of the data may be coming from satellites in other systems.

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Online-ready: The exercise is electronic and could be done individually or in small online groups. Lecture is best done synchronously due to the technical nature. Discussion would be better that way too.

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In this unit, students explore water privatization and freshwater access issues within the geophysical and cultural context of Cochabamba, Bolivia. Students identify topographical features that create rain shadows and their relationship to the water cycle. As they discuss several alternative models for supplying water to the residents of Cochabamba, they link concepts of environmental justice to the Cochabamba Water Wars of 2000.

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This module looks at the feasibility of using deeper wells as a source of low As water. The data sets are described in detail by van Geen et al. (van Geen et al., 2003; van Geen et al., 2002).

Students are being introduced to background information about the Arsenic problem in Bangladesh in lecture format. This includes health aspects and the history of the issue. They also have been using the sand tank groundwater model distributed by the University of Wisconsin Stevens Point (https://www.uwsp.edu/cnr-ap/watershed/Pages/GroundwaterModelWorkshop.aspx) to develop an intuitive understanding of groundwater flow and transport and are familiar with basic hydrogeological concepts. They inject a dye into the shallow aquifer of the model and study how pumping effects the migration of the Arsenic plume (Fig 1).

Students get an Excel spreadsheet that contains the longitude, latitude, and depth of 6000 wells and a satellite image that shows the area of investigation. They use Arc GIS software to plot data on the satellite image (Fig. 2), or alternatively plot the data as a function of longitude and latitude as a bubble plot in Excel. They find that the distribution of As in many regions is very heterogeneous. They then select sub-regions and look at the depth distribution and find that often there is a gap in the depth population of wells which turns out to be due to a clay layer varying in thickness that separates the shallow aquifer from the deep aquifer. The depth distribution (Fig. 3) of As also shows a characteristic pattern with most of the elevated As concentrated in the top 30 meters.
Students then discuss remediation options, in particular the possibility of switching to neighboring wells and using deeper groundwater as an alternative source of drinking water. They find that in many regions there are safe wells within a few hundred m of the high As well. However, it is not clear how long these wells will remain low in dissolved As and there are social barriers as well to use the neighbors well. They then determine a depth below which As concentrations are low in their region and elevate the risk of using deeper groundwater for drinking water and irrigation. They find that personal use is resulting in only ~1cm year-1 of water use, while irrigation (~1 m year-1) would considerably lower the water table and potentially could contaminate the deeper aquifer as well. The conclusion is that if deeper groundwater is utilized its use should be limited to personal use.

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To prepare for this project / assignment, students could view the 'A Civil Action' movie, the instructor could read to them excerpts from the book and/or the trial testimony, and show them images from Woburn, wells G and H, the subsurface geologic materials, geologic cross sections, the trial participants, and the federal courtroom in Boston (see below). The materials in Bair (2001) about scientists in the courtroom, specific (excerpted) testimony presented by the three expert witnesses in the 'A Civil Action' trial, a chart summarizing the differences in their testimony, and the views of a federal judge on the goal of science versus the goal of a civil trial may also be worthwhile reading by the class prior to the assignment.

The instructor could show students the large plates included in the USGS report by Myette and others (1987) that display potentiometric data and contours before and after the critically important aquifer test performed in December 1985 and January 1986, just before the trial, and discuss the significance of the stream discharge measurement made by the USGS upstream and downstream of municipal wells G and H to the experts' testimony and the outcome of the trial.

The instructor could also show the animations of TCE movement from 1960 to 1986 from the five known sources of TCE contamination at the Woburn Wells G & H Superfund Site (W.R. Grace, UniFirst dry cleaners, Olympia Trucking, Beatrice Foods, and New England Plastics) and the animation showing temporal changes in induced infiltration from the Aberjona River to wells G and H that were created by Martin van Oort (M.S., 2005) based on the research of Maura Metheny (M.S., 1998; Ph.D., 2004) at Ohio State University.

The article by Bair and Metheny (2002) concerning the remediation activities subsequent to the famous trial at the Wells G & H Superfund Site could be used to show how groundwater contamination is cleaned up, why different remediation schemes needed to be used in different hydrogeologic settings, and why cleanup to U.S. EPA standards can take decades.

(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.)

The Volcanic Hazards Simulation is a complex role-play used to teach upper-level undergraduate students about volcanic forecasting and emergency management through the management of an authentic volcanic scenario.

This virtual field trip takes students to the site of a local groundwater controversy in Gallatin Valley, Montana. Students virtually travel through seven stops which highlight the groundwater hydrology, local geology, geologic history of the valley and local groundwater policy. During the virtual field trip, students are asked to role-play as geologists hired to evaluate the area. Ultimately, they are asked to formulate an argument for or against the development of a nearby subdivision and to support that argument with evidence they gathered on the virtual field trip. Evidence may include observational field notes, hypotheses and questions regarding the geology and geohydrology of the area as well as limited hydrological data. Students must produce a final report discussing the decision they made as a consulting geologist. Reports should include a well-supported argument using the data and information collected during the virtual field trip. This virtual field trip gives students an opportunity to explore a local dispute regarding groundwater and learn how geology, geohydrology and scientific data are involved in policy issues.

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Students use USGS WaterData website to find data on area, average annual discharge and response to high-precip events in small watersheds in southern New England. Data for the class are compiled to generate graphs showing the regional relationships between (1) area and discharge, and (2) area and time-lag between precip and maximum discharge.

terms: discharge, watershed, flood

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