Cs382: Difference between revisions

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=== Brad and Nate ===
=== Brad and Nate ===


Our goal is an incremental approach towards illustrating groundwater contamination in a confined aquifer.  The confined aquifer, viewed between wells 1 and 8, offers an environment within the groundwater simulator with the fewest variables.  The first 3 experiments are an effort to illustrate the behavior and underlying science that must be understood and demonstrated in the final experiment.
Our goal is an incremental approach towards illustrating groundwater contamination in a confined aquifer.  The confined aquifer, viewed between wells 1 and 8, offers an environment within the groundwater simulator with the fewest variables.  The first 4 experiments are an effort to illustrate the behavior and underlying science that must be understood and demonstrated in the final experiment.


*Experiments
*Experiments
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** Contaminant Plume Length
** Contaminant Plume Length
*** Determine whether contaminant plume length is affected by flow rate for a given amount of dye
*** Determine whether contaminant plume length is affected by flow rate for a given amount of dye
** Soil Density
*** Use displacement method and measurements of aquifer component to determine the density of the soil. We can use this value in silico.
** Illustrate laminar flow in a confined aquifer (Activity 7-1)
** Illustrate laminar flow in a confined aquifer (Activity 7-1)
*** Show laminar flow between wells 1 and 8.
*** Show laminar flow between wells 1 and 8.
** Soil Density
 
*** Use displacement method and measurements of aquifer component to determine the density of the soil. We can use this value in silico.


* Computational Tools
* Computational Tools

Revision as of 15:38, 1 November 2007

This page documents the work of CS382 - Scientific Computing, Fall 2007


enVision Tabletop Groundwater Simulator

General Instructions

  • Setup
  • Teardown and cleaning
  • Packing and travelling

Instructions for Demonstrations

  • First one
  • Second one
  • etc.

Computational Groundwater Simulations

Fitz and Bryan

  • Experiments
    • Demonstrating porosity
      • model water flow unconfined aquifier
    • Illustrating groundwater flow in a confined aquifer
      • modeling the behaviors of plumes moving thru confined aquifier
    • Describing recharge, transition and discharge areas
      • modeling behavior of water recharge, discharge in wells, lake, etc
  • Computational Tools
    • C
      • +Very fast
      • +Libraries are available
      • +Good distributed Libraries
      • -Potentially difficult to use
      • -no graphics libraries
    • Netlogo
      • +Fancy Graphics
      • +Fun to use
      • +Available examples/code
      • -Slow
      • -Small problem size
      • -No Distributed processing

Peter and Mikio

  • Replace this with the first experiment
  • Replace this with the second experiment
  • Replace this with the third experiment

Brad and Nate

Our goal is an incremental approach towards illustrating groundwater contamination in a confined aquifer. The confined aquifer, viewed between wells 1 and 8, offers an environment within the groundwater simulator with the fewest variables. The first 4 experiments are an effort to illustrate the behavior and underlying science that must be understood and demonstrated in the final experiment.

  • Experiments
    • Diffusion
      • Show diffusion without groundwater movement.
    • Flow Rate
      • Show the leading edge of groundwater contamination as a indicator of flow rate (related to section 5 and 13 in manual)
    • Contaminant Plume Length
      • Determine whether contaminant plume length is affected by flow rate for a given amount of dye
    • Soil Density
      • Use displacement method and measurements of aquifer component to determine the density of the soil. We can use this value in silico.
    • Illustrate laminar flow in a confined aquifer (Activity 7-1)
      • Show laminar flow between wells 1 and 8.


  • Computational Tools
    • NetLogo
      • + Visualization built in
      • + Agent and cell based simulation structure built in
      • - Possible limitation on world size / agent count in RAM
      • - Possible run time slower than groundwater simulator at higher flow rates
      • - Not parallel
    • Python and MYMPI
      • + Parallelizable
      • + Faster than NetLogo in serial code ?
      • + Visualization software exists
      • - Visualization software must be integrated
      • - MYMPI is untested

Activities in Manual

  • Level I: Teaching Basic Groundwater Facts and Concepts with the Model
    • 2-1: Demonstrating porosity
    • 2-2: Porosity demonstrations
    • 3-1: Illustrating the water table (groundwater not flowing)
    • 3-2: Illustrating the water table (groundwater flowing)
    • 3-3: Raising and lowering the water table
    • 4-1: Describing recharge, transition and discharge areas
    • 5-1: Describing the slope on the water table (hydraulic gradient)
    • 6-1: Observing water level differences in wells in recharge and discharge areas
    • 6-2: Potentiometric surfaces
    • 7-1: Illustrating groundwater flow in a confined aquifer
    • 7-2: Groundwater flow in an unconfined (water table) aquifer
    • 8-1: Illustrating and describing groundwater contamination
    • 9-1: Pump and Treat, How to operate the syringe system
    • 9-2: In-situ treatment
  • Level II: Using the Groundwater Model (Elementary - Middle School)
    • 10-1: Describing the model
    • 11-1: Illustrating and calculating porosity
    • 12-1: Estimating the permeability of soils
    • 12-2: Graphing the permeability of soils
    • 12-3: Determining the actual permeability (MS)
    • 12-4: Illustrating the water table
    • 12-5: Explaining the water levels in water wells
    • 12-6 Explaining a sloping water table
    • 12-7 Determine the amount of water (discharge) flowing through the model
    • 14-1: Demonstration illustrating what happens when contaminants in groundwater have densities that differ from groundwater
    • 14-2: Illustrating how water wells are contaminated
    • 14-3: Illustrating the effect of pumping wells on contaminated aquifers
    • 14-4: Illustrating how contaminant concentrations can be changed in groundwater