2009-2010

Topics include conservation of fluid mass, storage properties of porous media, matrix compressibility, boundary conditions, flow nets, well hydraulics, groundwater chemistry, and solute transport. Design projects and computer applications included. Prerequisites: CEE20; CEE170 or MAE130A; or consent of instructor. Concurrent with CEE 272. (Design units: 2)

Basic principles of hydrologic modeling are practiced in detail. Concepts of watershed, floodplains delineation, hydrologic impact, design studies, and GIS tools are discussed. Focus on the USACE (HEC) software tools (HEC-HMS, and HECRAS) along with their associated GIS interfaces. Prerequisites: CEE176 and CEE170. Concurrent with CEE273

Elements of the hydrologic cycle including precipitation, infiltration, evapotranspiration, ground water, and runoff. Unit Hydrograph theory and routing methods. Introduction to precipitation/runoff relationship and watershed modeling. Statistical methods and flood frequency analysis. Prerequisite: CEE170 or MAE130A. Concurrent with CEE276. (Design units: 2)

Team designs a land development project including infrastructural, environmental, circulation aspects. Focus on traffic impact studies, design of road layouts, geometry, signals, geotechnical and hydrological analysis, design of structural elements, economic analysis. Oral/written interim and final design reports. Laboratory sessions. In-Progress grading. Corequisites: CEE121 and CEE151C. Prerequisites: CEE81A, CEE81B, CEE110, CEE161. CEE181A-B-C must be taken in the same academic year. (Design units: 1-2-2)

Examines the ecological processes of the coastal environment. Investigates the causes of coastal ecosystem degradation and strategies to restore the ecosystem balance or prevent further coastal ecosystem health degradation. Prerequisites: Chemistry 1A-B and Social Ecology E8. Concurrent with CEE267.

Principles governing the analysis and design of water resource systems including pressurized pipelines, pipe networks, channels, and ground water. Coverage of fluid mass, momentum and energy conservation, flow resistance, and related laboratory measurements in different systems. Prerequisites: CEE20 or MAE10; CEE170 or MAE130A. (Design units: 2)

Basic principles, design, and operation of sustainable energy systems including wind, solar photo-voltaic and thermal, hydroelectric, geothermal, oceanic, biomass combustion, advanced coal, and next generation nuclear. Includes power generation, storage, and transmission for stationary power generation. Prerequisite: MAE115.

Lecture, three hours. Examination of current issues related to the atmosphere, including energy usage; toxicology; effects on humans, forest, plants, and ecosystems; particulate matter (PM10); combustion; modeling and meteorology; airborne toxic chemicals and risk assessment; application of science to development of public policies. Prerequisite: One course selected from Chemistry 245, Earth System Science 202, Engineering MAE164, Engineering MAE261, or consent of instructor.

Lecture, three hours. Examination of current issues related to the atmosphere, including energy usage; toxicology; effects on humans, forest, plants, and ecosystems; particulate matter (PM10); combustion; modeling and meteorology; airborne toxic chemicals and risk assessment; application of science to development of public policies. Prerequisite: One course selected from Chemistry 245, Earth System Science 202, Engineering MAE164, Engineering MAE261, or consent of instructor.

Basic principles, design, and operation of sustainable energy systems including wind, solar photo-voltaic and thermal, hydroelectric, geothermal, oceanic, biomass combustion, advanced coal, and next generation nuclear. Includes power generation, storage, and transmission for stationary power generation. Prerequisite: MAE115. Concurrent with MAE218. (Design units: 1)