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ST-589: Climate Change and Carbon Sequestration

ST-589: Climate Change and Carbon Sequestration. Final Project Earl Reynolds. Goal. A flexible project that can be adapted to multiple problems and levels of mathematics, ranging from Pre-Algebra to Algebra II, which applies mathematics standards to the problems of CO 2 sequestration.

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ST-589: Climate Change and Carbon Sequestration

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  1. ST-589: Climate Change and Carbon Sequestration Final Project Earl Reynolds

  2. Goal • A flexible project that can be adapted to multiple problems and levels of mathematics, ranging from Pre-Algebra to Algebra II, which applies mathematics standards to the problems of CO2 sequestration.

  3. Basic Premise A coal power plant produces ____ Gt of CO2 each year. This CO2 must be sequestered. Figure out how this can be done at minimum cost.

  4. Pre-Algebra • CO2 transported by pipeline, constructed at fixed cost per mile • Only one site is used • Sites have volumes easily expressed by formulas (e.g. cube, prism, half sphere) • All but one site is too small; one site is more than large enough. • Main question: How much will it cost to sequester the CO2 in the appropriate reservoir? • Extra credit: cheaper to sequester in one site or multiple sites?

  5. Algebra I • Two sequestration sites of adequate size can be used, of variable investment costs (possibly land rights, difficult terrain, etc.). • These costs sum to a total initial cost. The cost of a pipeline varies with each site (e.g., $1000 per mile for site one, $5000 per mile for site two). • Main question: Students must figure out which site to use for a given time period (e.g. 10 years, 50 years). Solutions are found by solving a system of equations. • Decide if one site is always cheaper than the other, if it is worthwhile to build pipelines to both sites, etc.

  6. Algebra II • Students will solve a basic linear programming problem, with the following constraints: • Cost of pipeline construction • Capacity of each reservoir (fixed volume calculated from porosity) • Permeability of each reservoir (if applicable) • Total CO2 to be sequestered • The project must meet all constraints, and must include the optimal solution.

  7. Resources for project expansion • “Carbon Dioxide Capture and Storage: summary for policy makers • http://www.ipcc.ch/pdf/special-reports/srccs/srccs_summaryforpolicymakers.pdf • Provides general information and useful data tables that can be incorporated into the assignments for the sake of authenticity. Numbers include: Coal Plant emission stats, cost of CO2 capture • “Carbon in Underland” • http://www.youtube.com/watch?v=gr9cznZFuIc • Short, cheesy animation explaining the basic processes of geologic CO2 sequestration • “Geologic Sequestration” • http://www.southwestcarbonpartnership.org/GeoSeq.html • SWP’s website illustrating geologic sequestration, including an animated applet demonstrating the sequestration of CO2 from a coal plant over time at varying percentages. • “Simulation and Risk Assessment Focus Area” • http://www.netl.doe.gov/technologies/carbon_seq/corerd/simulation.html • The DOE’s collection of simulation information, useful for student research in more open-ended adaptations of the project

  8. Standards Correlation • All levels: 9-12.A.3.1 Model real-world phenomena using linear equations and linear inequalities interpret resulting solutions, and use estimation to detect errors. • Algebra I: 9-12.A.3.4 Solve systems of linear equations in two variables algebraically and graphically • Algebra II: 9-12.A.1.17 Solve linear equations and inequalities in one variable including those involving the absolute value of a linear function.

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