Weather and climate analyzed in terms of their physical basis and historical, economic and human consequences. Emphasis on impacts of extreme weather: hurricanes, severe thunderstorms, winter storms and floods.
(3 lecture, 2 laboratory) The basic course in meteorology. The atmosphere, its structure and composition. Radiation, temperature, pressure, wind, humidity, precipitation, clouds, air masses and fronts. Measurements. Weather maps.
(4 laboratory) Meteorological instruments and weather data; weather maps and upper air charts; plotting of charts and basic analysis techniques. An introduction to numerical weather prediction results is included.
The practice of weather forecasting is introduced through weather briefings and participation in a forecast contest. Effective weather dissemination practices, interpersonal communication skills, and use of numerical guidance are emphasized.
Develops quantitative problem solving skills and introductory computer skills using applications specific to meteorology; atmospheric composition and gas laws, atmospheric thermodynamics and stability.
(
MET 205 and
MATH 131 and Concurrent Prerequisite PHYS 240 with a minimum grade of D-)
Physical processes in the atmosphere and advanced applications in atmospheric thermodynamics; radiation laws and balance, cloud microphysics, precipitation processes, and atmospheric electricity.
Credit given for participation in cooperative work/study program with National Weather Service, NOAA and/or other agencies. Summary paper required for work and/or research activities.
The physical laws governing planetary and synoptic-scale atmospheric motions are developed mathematically based on conversion of mass, momentum, and energy.
(3 lecture, 2 laboratory) Use of weather data, manual analyses, and meteorological software tools in weather forecasting and case studies. Practice includes review of theory, student weather briefing, daily forecast, and statistical forecast verification.
(3 lecture, 2 lab) Describes the principles of numerical weather prediction, modern forecast models, and their uses. Emphasis is placed on weather analysis, the advantages and limitations of numerical models, and advanced forecasting applications.
Individualized investigation under the direct supervision of a faculty member. (Minimum of 37.5 clock hours required per credit hour.)
Special Notes
Maximum concurrent enrollment is two times.
Factors affecting climate; analytical methods used to study climatology, general circulation of the atmosphere, oceans, and the global energy balance. Introduction to global climate models, projections of climate change.
Survey of climate history and methods of interpreting geological, paleontological, and paleobotanical climate proxies. Introduction to modeling, utility of using models to reconstruct past climate, and current research in paleoclimate.
(3 lecture, 2 laboratory) Study of atmospheric phenomena on medium time and space scales. Topics include frontogenesis, mountain/valley winds, sea breeze circulations, gravity currents and waves, thunderstorms, hurricanes, and problems in mesoscale forecasting.
Principles of extreme weather over complex terrain, Rocky Mountains, and Colorado Front Range. Fire weather, windstorms, air pollution, blizzards and snow avalanches, monsoon circulations, and forecast application.
Principles of remote sensing techniques, including radar and satellite instrumentation and operation. Types of radar and satellite instrumentation and interpretation of imagery used to understand the atmosphere and forecast weather.
Explore topics in meteorology beyond regular departmental offerings. Specific topics determined by student interest and instructor.