1 / 22

GEOS 697 Special Topics: Watershed Hydrology

GEOS 697 Special Topics: Watershed Hydrology. Instructor: Jim McNamara Boise State University. GEOS 617: Watershed Processes. Instructor: Jim McNamara Boise State University. 8/23 Objectives. Motivation for course Relation to HS Curriculum Course Logistics

bethan
Download Presentation

GEOS 697 Special Topics: Watershed Hydrology

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. GEOS 697 Special Topics: Watershed Hydrology Instructor: Jim McNamara Boise State University

  2. GEOS 617: Watershed Processes Instructor: Jim McNamara Boise State University

  3. 8/23 Objectives Motivation for course Relation to HS Curriculum Course Logistics Assignment 1: Process review introduction

  4. Intro Hydrology Course (GEOS 416/516 Hydrology) Equations for each arrow

  5. Watershed Hydrology Fluxes (arrows) and stores are not independent Hydrologic behavior emerges in response to the integration of arrows that can not be predicted by simply connecting the arrows

  6. Watershed Processes • Watershed receives intermittent input from atmosphere, exports relatively continuous fluxes of water, solutes, sediment, and gasses. • Studying the independent arrows lead to failure when predicting associated fluxes

  7. For Example… “…streamflow responds promptly to rainfall inputs, but fluctuations in passive tracers are often strongly damped. This indicates that storm flow in these catchments is mostly ‘old’ water” Kirchner 2003 HP

  8. For Example… Ammonium Nitrate Electrical Cond. b. c. a. mg/L mS/cm Snowmelt f. d. e. mS/cm Dry Antecedent Conditions mg/L g. h. i. mg/L Wet Antecedent Conditions mS/cm Streamflow (m3/s) Streamflow (m3/s) Streamflow (m3/s) McNamara et al., 2008

  9. Hydrologic Pathways Dictate Solute Delivery Charlie Driscoll, SU

  10. Watershed Hydrology • We will gain deep understanding of the inner mechanics of watersheds • Why? • Improved hydrologic modeling • Biogeochemistry • Water Policy • Reservoir operation rules (US West) • Cascading effects of land use land cover (LULC) change

  11. Watershed Processes • Watersheds are fundamental landscape units that arise from the interaction of climate, water, rock, and vegetation • Water flux pathways are dictated by landscape properties in the short-term, which are dictated by water pathways in the long-term

  12. Watershed Processes • Governing Principle for Course: • Watersheds are fundamental landscape units that transport mass and energy through terrestrial systems, and provide sustenance for ecosystems and human societies. Holistic understanding, and effective management, of watershed processes is predicated on recognizing the interdependencies and feedbacks governing landscape evolution, hydrology, and ecology

  13. Course Logistics See web page: http://earth.boisestate.edu/jmcnamara/watershed-hydrology/

  14. Course Description GEOS 616 Watershed Hydrology. (3-0-3) (F). An integrated study of hydrologic processes operating in watersheds; relationships between hydrologic, biogeochemical, and geomorphologic processes. PREREQ: PERM/INST. In this course we will move beyond the study of individual hydrologic fluxes and stores to investigate the integrating nature of watersheds. We will review basic physics of hydrologic processes and then investigate how these properties interact and manifest as runoff generation, plant-soil water relations, and the coevolution of geomorphology and hydrologic response. Activities to promote learning include lectures, guided readings and discussions, student presentations, and projects. Students will complete approximately 6 projects related to the topics below. Most projects will involve acquisition, analysis and interpretation of data available online from several experimental watersheds throughout the country with an emphasis on Dry Creek and Reynolds Creek in southwest Idaho.

  15. Course Structure • This course requires active participation by all students. The instructor will use lectures to introduce each new topic. Subsequent class periods will be composed of student-led discussions and project work. To get the full experience students must attend all class periods, complete all reading assignments, and stay caught up on class projects. • Course management will occur via the schedule: http://earth.boisestate.edu/jmcnamara/watershed-hydrology-schedule • We will use publicly available data from several research watersheds throughout the US for most projects. • Dry Creek: http://earth.boisestate.edu/drycreek/ • HJ Andrews: http://andrewsforest.oregonstate.edu/ • Reynolds Creek: http://www.nwrc.ars.usda.gov/

  16. Hydrologic Science Curriculum • Mission: To deliver an integrated suite of courses and research opportunities that • facilitate understanding of physical processes and earth properties governing terrestrial water flux and storage • promote understanding of the interactions and feedbacks between the hydrosphere, lithosphere, and biosphere • develop data acquisition and interpretation skills • Computational and analytical skills to model and predict hydrologic processes interactions Motivation: Our program is structured around the Definition of Hydrology: The geoscience that describesand predicts the spatial and temporal variations of water in the terrestrial, oceanic, and atmospheric compartments of the global water system, the movement of water on and under Earths surface, the physical and chemical processes accompanying that movement, and the biological processes that conduct or affect that movement. Water Flux and Storage Hydrosphere, Lithosphere, Biosphere Interactions Data Acquisition, Analysis and Modeling Skills Admission Prerequisites *required,**recommended No credit towards degree. Basis science knowledge, computational and analytical skills, geological principles supporting surface and groundwater systems *Differential and Integral Calculus *Physics I and Physics II *Chemistry I and Chemistry II *Statistics *GIS/ programming **Basic hydrology or water resources *Degree in physical science or engineering with courses in -Introductory geology* -Geomorphology** -Stratigraphy/Sedimentation** *GEOS 5xx: Matlab Primer Introductory Core Basic physical properties and process governing water flux in the terrestrial hydrologic cycle, origin of solutes in water, basic computational skills, hydrologic simulation and prediction GEOS 511 Hydrology 1: Land-Atmosphere Interaction GEOS 5xx: Aqueous Geochemistry GEOS 5xx: Hydrologic Modeling GEOPH 6xx: Geostatistics GEOS 512: Hydrology 2: Flow in Geologic Systems Focus Areas Advanced courses in specific Hydrologic Science sub-disciplines GEOS 623: Advanced Hydrogeology GEOS 5xx: Biogeochemical Methods GEOS 618: Hydrologic Analysis GEOS 5xx: Advanced Geomorphology CE 5xx: Engineering Hydrology CE 6xx: Contaminant Transport UI-CE 5xx: Fluvial Geomorphology ISU-GEOS 5xx: Remote Sensing GEOS 617: Watershed Processes CE 5xx: Hydrometeorology CE 5xx: GIS in Water Resources GEOS 624: Applied Hydrogeology Supplemental Relevant courses from supporting disciplines GEOPH 6xx: Snow and Ice Physics BIOL 5xx: Stream Ecology GEOPH 5xx: Open Channel Flow GEOPH 6xx: Hydrogeophysics

  17. Schedule of Topics • Course introduction-Summary of goals, objectives, and expectations 2. Hydrologic process review-A brief review of the physics governing individual hydrologic processes operating in watersheds including precipitation, snowmelt, infiltration, lateral surface and subsurface flow, groundwater flow, and streamflow. 3. Water Balance-An advanced treatment of mass balance concept operating a hillslope, watershed, basin, and continentental scales 4. Watershed Geomorphology-Quantitative analysis of the shape of watersheds, hillslopes, and channel networks; geomorphologic evolution of watersheds 5. Advanced concepts in watershed hydrology -Integrated hydrologic processes and emergent hydrologic properties in watersheds. -water residence time -Runoff generation -Storage, thresholds, and connectivity 6. Ecohydrology-Relationships between hydrology, vegetation, and geomorphology in catchments 7. Watershed biogeochemistry-An introduction to the role that hydrologic processes play in governing the export of mass from watersheds 8. Hydrologic modeling concepts-A capstone topic reconciling our knowledge of watershed hydrology with current hydrologic modeling approaches 9. Watershed Management/ Idaho watershed issues

  18. Prerequisites • Basic process hydrology • Computational competence • MATLAB, GIS, programming recommended

  19. Learning Outcomes • Upon completing this course, students will be able to: • Conduct comparative hydrologic analyses of watersheds • Conduct geomorphologic analyses of watersheds • Understand the principles governing the coevolution of watershed geomorphology and hydrologic response • Understand basic ecohydrologic principles

  20. CourseResources No required text, but you should all own one or two hydrology books an have access to hydrology journals

  21. Experimental Watersheds Projects and lectures will draw heavily from a national “network” of hydrologic observatories

  22. Assignment 1: Process Review • Each student will prepare a 7 minute presentation consisting of 3-5 slides summarizing one “arrow”. Presentations must cover • Basic governing physics • Essential equations used to describe/model the process • Measurement methods • Other relevant information • Process Assignments • Precipitation formation • Snowmelt • Infiltration and redistribution • Overland flow • Saturated groundwater flow • Streamflow • Evapotranspiration

More Related