1. A Modeling Approach to Restoring Pool – Riffle Structure in an Incised, Straightened Channel of an Urban Stream University of Tennessee Department of Civil and Environmental Engineering Keil J. Neff Dr. John Schwartz Knox County Stormwater Management Andrew B. Dodson Michael S. Hamrick

2. Pool-Riffle Structure in Natural Channels Riffle-Pool Sequence: The development of alternating deeps (pools) and shallows (riffles) is characteristic of both straight and meandering channels with heterogeneous bed materials, containing gravel, in the size range of 2 to 256 mm. In general, riffle-pool sequences occur with bed slopes < 2%.

3. Pool-Riffle Structure in Urban Streams Pool-riffle structure, capable of supporting diverse biological ecosystems, is frequently degraded in urban streams because of channel incision and the loss of channel-scale helical flow patterns, which are responsible for initiating pool-riffle sequences. Knighton 1988

4. Stream Impairment Anthropogenic Impacts to the Stream System Watershed land use changes (e.g., urbanization, deforestation) Channelization reduces habitat complexity and flood refugia for fish Habitat loss or modification Introduction of exotic species Water withdrawals; Pollutant Discharges Over exploitation of fish and wildlife Urbanization impacts watershed hydrology resulting in hydromodification of in- stream hydraulics and rapid adjustment of channel morphology thereby disturbing natural geomorphic and ecological processes in stream systems. Embrass River, IL; Schwartz, 2002.

5. Beaver Creek, Knox County, Tennessee 303d listed (TDEC) Habitat loss due to alteration in stream side Loss of biological integrity due to siltation One pollutant source: Channelization Other studies: Dworak, Mallison, Cantrell

6. Study Reach on Beaver Creek Beaver Creek, TN, 2009. Historically re-located Channelized Lack of pool-riffle sequences Velocity homogeniety Urbanization Impacts Undersized channel 40 square km 270 m length Channel evolution stage III

7. Beaver Creek Stream Rehabilitation Objectives Design stable and sustainable self-regulating pool- riffle sequences using River2D hydrodynamic model and triangulated irregular network (TIN) editor in AutoCAD Civil 3D. Support maintenance of velocity acceleration/deceleration sequencing. Enhance habitat and biotic diversity. Stabilize failing banks. Provide cost-effective method for stream rehabilitation.

8. Limitations Laterally confined Undersized channel Very mild slope Sediment starved Monetary budget Beaver Creek, TN, 2009.

9. Low flow concept Acceleration/deceleration Riffle crest Minor sinuosity Design Framework Work with existing channel Minor expansion (bank erosion/failure; absence of trees) Minor constriction (large trees on banks; minor scour) Bank stabilization Substrate placement

10. Design Framework High flow concept Acceleration/deceleration Submerged riffles Hydraulic refugia Scour/deposition Energy losses Q=VA; V1*A1=V2*A2; A2>A1  V2<V1 121

11. Additional Design Criteria No reference reach Spacing of pool-riffles sequences Defining riffle and runs Hydraulic diversity Substrate Iterative Design Approach Survey AutoCAD Civil 3DRiver2D Design Channel

12. Initial Assessment Trimble Total Station Survey Initial benchmarks set with Real Time Kinematic GPS (0.05 ft accuracy) Breaklines – survey the dominant breaks in slope across the cross section Approximately at a 2 meter resolution Establish control reach Benthic Macroinvertebrate Survey Index of Biotic Integrity Survey Global Water Continuous Level Logger Installation Bedload Sediment Collection Rapid Geomorphic Assessment 3D Acoustic Doppler Velocity Measurements

13. River2D Modeling Evaluate hydraulics High/Low flow regimes Placement of in-stream structures Evaluate bank shear stresses Placement of bank stabilization structures Evaluate bed shear stresses Size substrate Assess available fish habitat

14. River2D Modeling R2D Model User Manual (Peter Steffler – University of Alberta) Two dimensional, Depth Averaged, Finite Element Model Basic mass conservation equation and 2 (horizontal) components of momentum conservation Modeling Steps Create a preliminary bed topography file from survey data using R2D_Bed program. Define boundary polygon of area to be modeled. Define boundary conditions (discharge and downstream water surface elevation) and define roughness. Create, triangulate, and smooth mesh. Define breaklines at toe and top of bank. Add additional nodes at critical positions. Run River2D to solve for velocity and depth. Model outputs: 2 (horizontal) velocity components and a depth at each node. The fish habitat module is based on the PHABSIM weighted usable area approach, adapted for a triangular irregular network geometrical description. http://www.river2d.ualberta.ca/

15. River2D: Current Condition - Hydraulics Channelized, uniform hydraulic regime, devoid of riffles, 1 minor pool (local scour from in-stream tree).

16. River2D: Current Condition – Habitat at Low Flow Poor/fair combined (depth, velocity, channel index) suitability. Green Side Darter - low flow Northern Hogsucker - low flow

17. Combined (depth, velocity, channel index) suitability. Northern Hogsucker - high flow Green Side Darter - high flow River2D: Current Condition – Habitat at High Flow

18. Creating Design Channel utilizing Civil3D Interactive TIN Editing to create riffles, riffle/runs, pools, bank stabilization features, and log vanes. TIN modified by adding hard and soft breaklines, modifying the underlying nodes, and eventually transforming the surface to represent multiple stream rehabilitation channel designs.

19. Longitudinal Profile of Design Reach

20. Visualizing Design in ArcScene

21. Design Features Removal of trees Excavation of the banks Addition of hydraulic structures Addition of bank protection Addition of habitat features/substrate material

22. Design Channel River2D Output Refining the mesh with the design bed modifications Interpreting and using the output High flow

23. Improved combined (depth, velocity, channel index) suitability. Northern Hogsucker - low flow Green Side Darter - low flow River2D: Design Condition – Habitat at Low Flow

24. Improved combined (depth, velocity, channel index) suitability. Northern Hogsucker - high flow Green Side Darter - high flow River2D: Design Condition – Habitat at High Flow

25. Low Flow ExistingDesign Greenside Darter7101 Northern Hogsucker207446 High Flow ExistingDesign Greenside Darter11196 Northern Hogsucker7711023 River2D: Weighted Usable Area

26. Construction Spring/Summer 2011 Weather dependent Construction reports Project agent on-site or available at all times High degree of accuracy required Sediment sizing Paint substrate in each riffle/run Invert elevations Placement of structures

27. Measurements of Success Stability of bed form and stream bank Survey (reach and cross-sections) Visual assessment of structures Improved habitat Benthic macroinvertebrate survey Index of biotic integrity Increased leaf litter (organic carbon cycling) Stability of riffle/run substrate Bed load sampling Diverse hydraulic patterns Velocity measurements

28. Beaver Creek Task Force Knox County Stormwater University of Tennessee – CEE Roy Arthur Tim Gangaware Americorps CAC Water Quality Team Ecological Engineering for Stream Rehabilitation Class (Schwartz) Knox County Parks and Recreation Project Partners