1. The Science of Stream Buffers Lake George Stream Corridor Management Stakeholder Meeting May 28, 2008

2. About the Center for WatershedProtection About the Center for Watershed Protection Non-profit 501(c)3, non-advocacy organizationNon-profit 501(c)3, non-advocacy organization Work with watershed groups, local, state, and federal governmentsWork with watershed groups, local, state, and federal governments Provide tools communities need to protect streams, lakes, and riversProvide tools communities need to protect streams, lakes, and rivers 20 staff in Ellicott City, MD and satellite Offices20 staff in Ellicott City, MD and satellite Officeswww.cwp.orgwww.stormwatercenter.net

3. Small Streams 1 st and 2 nd order 73% of our stream miles (Leopold, 1964)1 st and 2 nd order 73% of our stream miles (Leopold, 1964) Drain the majority of the landscapeDrain the majority of the landscape Connected to a high percentage of our wetlandsConnected to a high percentage of our wetlands 1 st and 2 nd order 73% of our stream miles (Leopold, 1964)1 st and 2 nd order 73% of our stream miles (Leopold, 1964) Drain the majority of the landscapeDrain the majority of the landscape Connected to a high percentage of our wetlandsConnected to a high percentage of our wetlands Effective at processing nutrientsEffective at processing nutrients Most frequently disturbed during the development processMost frequently disturbed during the development process Effective at processing nutrientsEffective at processing nutrients Most frequently disturbed during the development processMost frequently disturbed during the development process Juniper Inlet, FL: NOAA 1997

5. Organic matter Shading Nutrient and sediment retention Bank stability Habitat for wildlife Forested Stream Services

6. Forested Streams Fallen leaves are the base of the food chain in small streams, and provide as much as 75% of the energy input to the food chain Woody debris enhances organic matter and nutrient retention, dissipates energy and reduces downcutting (Meyer and Wallace, 2001) An average nutrient molecule travels less than 20m downstream before being removed in a high quality small shallow stream (Webster et al, 2002)

7. Basics of Stream Buffers Stream buffers are more than a line on a map It is more than a setback The floodplain is the core of the buffer Management is just as important as width Should be continuous –Gaps can introduce additional surface flow

8. Water quickly runs off a shoreline cleared of natural vegetation, washing nutrients and pesticides into the water. A natural shoreline holds rainfall, which soaks into the soil; less water, soil and chemicals run into the lake or river. Shoreline and aquatic plants anchor shoreline areas, helping to protect them from erosion due to runoff and waves (Source:MN DNR) Source: Minnesota Department of Natural Resources

9. Benefits of Stream Buffers Environmental Economic / Community How many can you name?

10. Environmental Benefits Provides room for streams to safely adjust laterally over time Provides additional streambank erosion protection Provides distance from impervious cover Helps prevent steep slope erosion and disturbance Helps keep stream temperatures down Pollutant removal Sediment Phosphorus and nitrogen Bacteria Source: Wenger, 1999

11. Temperature Many coldwater fish species have limited temperature range tolerance (e.g., trout) Stream warming from is caused by a variety of factors: –Loss of riparian cover (air temp in headwater streams) –Impervious surfaces –Stormwater ponds 60% riparian forest cover retains temperature 80% riparian forest lowers temperature

12. Sediment Sources - stream bank erosion - poor forestry, agriculture or mining practices - construction sites Impacts - reduced habitat for macroinvertebrates and fish - increased pollutants attached to sediment - increased cost to remove and dispose of sediment - potential for direct fish kill with high concentrations of fine, deposited sediment

13. Phosphorus Sources - generally accumulates attached to sediment particles - application of fertilizers on lawns and ag fields - animal waste and septic Impacts -Eutrophication of lakes -Shift in biota of stream systems

14. Economic/Community Benefits Reduce public investment in stormwater management, flood control, and pollutant removal Increase property values Provide habitat for wildlife Reduce watershed impervious cover Help minimize flooding and associated property damage Reduce time and expense of land maintenance, as compared to managed turf Reduce small drainage problems and complaints

15. Stream Buffer Design Preferred widths –Sediment removal –Phosphorus/Nitrogen removal Special resource/protection areas Three-zone buffer design Allowable uses

16. Modified from: Emmons & Olivier Resources, 2001 Critical Buffer Widths

17. (EOR, 2001)

18. Buffer Widths and Pollutant Removal Source: Wenger, 1999 PollutantRemoval RateNecessary Width* Sediment (as TSS) 66-93%90 ft 78%70 ft 94%190 ft Phosphorus (as TP) See above 84%164 ft 81%92 ft TempN/A30 ft of forest * Depends on slope, soils, infiltration rates, etc.

19. Special Resource/Protection Areas Base width should be expanded to include: –Ultimate 100 year floodplain –Very steep slopes greater than 25% Wetlands, critical habitats and forest conservation areas should have larger buffers

21. Three-Zone Buffer Design Each zone has different function, width, vegetative target, and management: –Streamside zone: 25 feet of undisturbed forest cover –Middle zone:50 feet or more of managed forest –Outer zone: 25 feet of grass or forest setback from structures

23. Stream Buffer Crossings To minimize fish blockages, all crossings should follow these guidelines: –Width: minimum right of way needed for access –Angle: perpendicular to stream –Frequency: no more than one crossing/1000 feet –Depth: utilities three feet below streambed –Capacity: convey 100 year storm –Culverts: bottomless, slab, arch or box designs preferred

24. Buffer Crossings Buffer xing photo

25. Stream xing photo Minimize clearing required to create a buffer crossing.

26. Riparian Buffer Management

29. Recommended Reading Emmons and Olivier Resources. Benefits of Wetland Buffers: A Study of Functions, Values and Sizes. http://www.minnehahacreek.org/documents/MCWD_Buffer_Study.pdf http://www.minnehahacreek.org/documents/MCWD_Buffer_Study.pdf Meyer, J.L. and J.B. Wallace. 2001. Lost linkages and lotic ecology: rediscovering small streams. http://cwt33.ecology.uga.edu/publications/1444.pdf http://cwt33.ecology.uga.edu/publications/1444.pdf Sweeney, B.W., T.L. Bott, J.K. Jackson, L.A. Kaplan, J.D. Newbold, L.J. Standley, W.C. Hession, and R.J. Horwitz. 2004. Riparian Deforestation, Stream Narrowing, and Loss of Stream Ecosystem Services. Proceedings of the National Academy of Sciences 101(39):14132-14137. http://www.stroudcenter.org/about/pdfs/bs_PNAS092804.pdf http://www.stroudcenter.org/about/pdfs/bs_PNAS092804.pdf Wenger, S. 1999. A review of the scientific literature on riparian buffer width, extent, and vegetation. Publication of the Office of Public Service and Outreach, Institute of Ecology, University of Georgia. 58pp.