1 / 46

General Lecture 1. Modeling and Sustainability

CE5504 Surface Water Quality Modeling. General Lecture 1. Modeling and Sustainability. Sustainability.  In our every deliberation we must consider the impact of our decisions on the next seven generations. Iroquois Confederacy.

Download Presentation

General Lecture 1. Modeling and Sustainability

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. CE5504 Surface Water Quality Modeling General Lecture 1. Modeling and Sustainability

  2. Sustainability  In our every deliberation we must consider the impact of our decisions on the next seven generations. Iroquois Confederacy Meeting the needs of the present without compromising the ability of future generations to meet their own needs. World Commission on Environment and Development, 1987 http://www.interspecies.com/pages/7th_gen.html http://www.bathtram.org/tfb/tE04.htm

  3. Modeling …a mathematical model is an idealized formulation that represents the response of a physical system to external stimuli. Chapra 1997, p. 10

  4. Toward Sustainability Decisions supporting a sustainable future require: 1) a knowledge of the way a system works. We might think of this as a research model. To provide a better understanding of the mechanisms and interactions that give rise to various types of water quality behavior, such understanding to be sharpened by the formulation and testing of hypotheses of the cause-effect relationships between residual inputs and resulting water quality. Thomann and Mueller 1987)

  5. Toward Sustainability Decisions supporting a sustainable future require: 2) a manner of predicting cause and effect. We might think of this as a management model. To provide a more rational basis for making water quality control decisions, such a basis to include a defensible, credible, predictive framework, within the larger framework of cost-benefit analysis. Thomann and Mueller 1987)

  6. The Regulatory Basis for Water Quality Management Everybody lives downstream.

  7. The Regulatory Basis for Water Quality Management Historically …

  8. The Regulatory Basis for Water Quality Management The Clean Water Act Objective: restore and maintain the chemical, physical and biological integrity of the Nation’s waters. • Goals: • elimination of the discharge of pollutants into navigable waters by 1985 (zero discharge) • achieving an interim water quality level that would protect fish, shellfish and wildlife while providing for recreation in and on the water wherever attainable (fishable, swimmable).

  9. The Regulatory Basis for Water Quality Management • The Clean Water Act • Technology-Based Approach • existing dischargers: best practicable control technologies • new dischargers: best available control technologies (including ‘green’) • indirect dischargers: pre-treatment standards • POTWs: biological or 2° treatment; BOD/SS/coliform bacteria • $60 billion in construction grants; $74 billion in lost interest loans

  10. The Regulatory Basis for Water Quality Management • The Clean Water Act • Water Quality-Based Approach • water quality standards (conventional and toxic pollutants) • permits (National Pollutant Discharge Elimination System, NPDES) • penalties ($32,500 per day per violation) • antidegradation (where WQ standards are attained) • protect existing uses • maintain high quality waters • protect outstanding waters • Total Maximum Daily Loads (TMDLs, where WQ standards are not attained)

  11. The Role of Modeling in Water Quality Management • Implementing the Water Quality-Based Approach • NPDES) • TMDLs • Antidegradation • What provides guidance for the decision-making process?

  12. The Role of Modeling in Water Quality Management • A Water Quality Management Plan • Identify beneficial use • Set water quality standards • Determine cause and effect • Evaluate control options • Consider economic conditions • Consider stakeholder response

  13. The Role of Modeling in Water Quality Management • A Water Quality Management Plan • Determine cause and effect

  14. The Role of Modeling in Water Quality Management • A Water Quality Management Plan • Evaluate control options … avoiding Build and Measure

  15. The Role of Modeling in Water Quality Management • A Water Quality Management Plan • Evaluate control options underdesign - …the environmental engineering equivalent of building a bridge that falls down. www.civil.columbia.edu/ce4210/bridgecollapse.html (Thomann and Mueller 1987, p. ix)

  16. The Role of Modeling in Water Quality Management • A Water Quality Management Plan • Evaluate control options overdesign - …the environmental engineering equivalent of building a bridge to nowhere. http://www.zen39641.zen.co.uk/ps/ (Thomann and Mueller 1987, p. ix)

  17. The Role of Modeling in Water Quality Management • A Water Quality Management Plan • Consider economic conditions

  18. The Role of Modeling in Water Quality Management • A Water Quality Management Plan • Consider stakeholder response ohioej.org

  19. The Role of Modeling in Water Quality Management • A Water Quality Management Plan • Identify beneficial use • Set water quality standards • Determine cause and effect • Evaluate control options • Consider economic conditions • Consider stakeholder response models

  20. The Water Quality Modeling Process

  21. The Water Quality Modeling Process • Problem Specification • client objectives • data • stormwater discharges • tributaries (nonpoint runoff) • WPCP outfall • coastal marshes • beachfront recreation sites • drinking water intake • power plant water intake

  22. The Water Quality Modeling Process • Model Selection • empirical • mechanistic Secchi disk - chlorophyll

  23. The Water Quality Modeling Process • Model Selection • empirical • mechanistic Mass Balance

  24. The Water Quality Modeling Process • Model Selection • off-the-shelf • de novo

  25. The Water Quality Modeling Process De novo theoretical development Segmentation

  26. The Water Quality Modeling Process De novo theoretical development Resolution Spatiotemporal

  27. The Water Quality Modeling Process De novo theoretical development Resolution Spatiotemporal

  28. The Water Quality Modeling Process De novo theoretical development Resolution Kinetic

  29. The Water Quality Modeling Process De novo theoretical development Resolution Kinetic

  30. The Water Quality Modeling Process De novo theoretical development Complexity and Reliability Things should be made as simple as possible -- but no simpler. Albert Einstein image source: www.physik.uni-frankfurt.de/~jr/physpiceinstein.html

  31. unlimited cost desired reliability Model Reliability cost + $ cost Model Complexity The Water Quality Modeling Process De novo theoretical development Complexity and Reliability

  32. The Water Quality Modeling Process De novo theoretical development Complexity and Reliability Model Complexity Screening  Management  Research

  33. The Water Quality Modeling Process De novo theoretical development Numerical specification and testing • identify state variables • write equations of state (mass balances) • numerical approach • analytical solution • numerical solution • validation of numerical approach

  34. The Water Quality Modeling Process De novo theoretical development Preliminary application • data deficiencies • theoretical gaps (missing sources/sinks) • important parameters (monitoring, experiments • sensitivity analysis

  35. The Water Quality Modeling Process De novo theoretical development Calibration • forcing conditions and physical parameters • initial conditions • boundary conditions • loads • environmental conditions • kinetics • calibration parameters

  36. The Water Quality Modeling Process De novo theoretical development Calibration (continued) • calibration • Adjustment of kinetic coefficients within statistically defined bounds seeking the best fit of model to field data.

  37. The Water Quality Modeling Process De novo theoretical development Calibration (continued) • testing model • performance

  38. The Water Quality Modeling Process De novo theoretical development Confirmation and Robustness • Evaluation of the performance of the model for a new set of forcing conditions and/or physical parameters with no further adjustment of model coefficients. • The greater the number and diversity of confirming observations, the more probable it is that the conceptualization embodied in the model is not flawed,” Oreskes et al. 1994 as cited by Chapra 1997.

  39. The Water Quality Modeling Process De novo theoretical development Management Applications outfall length → • test control options ← treatment

  40. The Water Quality Modeling Process De novo theoretical development Post Audit

  41. Historical Development of Models • 1925-1960 (Streeter-Phelps) • Problems: untreated and primary effluent • Pollutants: BOD • Systems: streams and estuaries (1D) • Kinetics: linear, feed forward • Solutions: analytical

  42. Historical Development of Models • 1960-1970 (Computerization) • Problems: primary and secondary effluent • Pollutants: BOD • Systems: streams and estuaries (1D/2D) • Kinetics: linear, feed forward • Solutions: analytical and numerical

  43. Historical Development of Models • 1970-1977 (Biology) • Problems: eutrophication • Pollutants: nutrients • Systems: streams, lakes and estuaries (1D/2D/3D) • Kinetics: nonlinear, feedback • Solutions: numerical

  44. Historical Development of Models • 1977- 2000 (Toxics) • Problems: toxics • Pollutants: organics, metals • Systems: sediment-water interactions • food chain interations, streams, lakes and estuaries • Kinetics: linear, feed forward • Solutions: analytical

  45. Whitefish Benthic Invertebrates Phytoplankton Historical Development of Models • 2000 - 2010 (Ecosytems) • Problems: ecosystem change, climate, invasives • Pollutants: natural components – carbon, nutrients, organisms • Systems: primary production, food web interactions • Kinetics: nonlinear, feedback • Solutions: numerical

  46. Historical Development of Models 2010 – present (Linked Hydrodynamic – Water Quality)

More Related