Response of a Newly Created Marsh-Wetland Affected by Tidal Forcing, Upland Discharge, and Groundwater Interaction Mouth of Columbia River, Cape Disappointment State Park, Washington 12 Hans R. Moritz 1, Rachel Hanna 1, James Burton 1, Barbara 11 Cisneros 1, 10 Chris Humphries 1, Brian Abel 2 1 US Army Corps of Engineers-Portland District, Portland, OR 2 Harbor Consulting Engineers, Inc, Seattle, WA Water Surface Elevation, NAVD88 (ft) 2016 Columbia River Estuary Conference THEME: Recent Anomalous Environmental Conditions Drivers and Consequences Astoria, Oregon 24 MAY 2016 14 13 9 8 7 6 5 4 3 2 1 0 McKenzie Lake - Headwater Culvert - DS, @ New Wetland, inv@7.7 ft NAVD Culve New -1 New Wetland - Outlet at Jetty, weir at 3-6 ft NAVD Ocea Groundwater Well #3-2 1-Nov 3-Nov 5-Nov 7-Nov 9-Nov 11-Nov 13-Nov 15-Nov 17-Nov
Response of a Newly Created Marsh-Wetland Area Affected by Tidal Forcing, Upland Discharge, and Groundwater Interaction PRESENTATION OUTLINE 1) Highlight rationale for creating a new 3-acre intertidal marsh-wetland along the landward base of the MCR North Jetty 2) Illustrate how the newly created wetland is inundated by tides passing through a porous rock weir control structure 3) Examine how the newly created wetland hydrology interacts with adjacent groundwater and pre-existing wetland drainage during summer and winter
Newly Created Intertidal Wetland Feature Created FEB-APR 2015 - Near MCR North Jetty (River Mile 1) Pacific Washington Mouth of Columbia River (MCR) O Columbia River Estuary Astoria River Mile 52 Ocean Oregon
Pacific N Wetland Feature Project Area* * Part of the MCR Jetty Rehabilitation Project North Head Peacock Spit MCR Navigation Long Beach North Jetty Channel Ilwaco Jetty A Clatsop Spit South Jetty Baker Bay Mouth of Columbia River 3 Jetties Constructed 1885-1939 Navigation Channel = 2,260 ft wide x 5 miles long 48-55 ft deep Sand Island Sand Island Pile Dikes 12.9 million tons of stone $1.7 Billion invested > $20 Billion Annual Commerce Chinook Washington Ocean Lower Columbia River Nav Channel Hammond Oregon Columbia River Estuary Astoria
Damage along Root of MCR North Jetty Channel Side of Jetty Progressive Lagoon Damage along Root of North Jetty was being Formed Driven by: 1) Direct Wave By Action along Channel Side 2) Hydraulic Flow Surge through Jetty Through Jetty Severely Damaged Jetty Root Flow Erodes Backside USCG photo & Destabilizes Foundation Severely Damaged Jetty Root Flow Channel Side of Jetty During typical winter storm USCG photo USCG photo
Continued Jetty Degradation Can Lead to a Jetty Breach Allowing Significant Volume of Sediment to Enter the Inlet and Navigation Channel
Cape Disappointment State Park, WA McKenzie Lake Pre-existing wetland Lagoon Erosion Area De-Stabilizing Root of North Jetty Pacific Ocean Mouth of Columbia River 18 NOV 14 Cape Disappointment State Park, WA McKenzie Lake Pacific Lagoon Erosion Area Filled to Stabilize Root of North Jetty New Intertidal Wetland 3 acre Pre-existing wetland Ocean Mouth of Columbia River 16 APR 15
Pre-existing wetland and interior area drainage GMW #3 * Degraded Culvert 18 NOV 14 Higher tide Pre-project New Intertidal Wetland 3 acre Pre-existing wetland and interior area drainage Culvert Replacement GMW #3* Outlet Control (porous rock sill) 13 16 JUN APR 15 15 Lower Higher tide tide Post-project
Pre-Existing GMW_3 Culvert-US Jetty Road culvert Wetland Culvert-DS New West Intertidal Wetland East Parking Lot MCR North Jetty Pacific Ocean Mouth of Columbia River Scale 100 feet Elevations in ft NAVD88 1 ft = 0.3048 meter
View to south North Jetty View to west Pre-Existing Wetland Discharging into New Wetland via Rebuilt Culvert Panorama of New Intertidal Wetland Culvert Invert @ 8.9 ft NAVD View to southwest Jetty Road Pre-Existing Wetland: Hydrology Charged by Upland (McKenzie Lake) and Tidal Flow from New Wetland View to west Vegetation for New Wetland New Intertidal Wetland North Jetty Rock Sill Outlet Structure Rock Sill (crest at 6 ft NAVD) 150 ft long 25 ft wide 3 ft high (3-6 ft NAVD) North Jetty View to southwest View to west Rock Sill All Photos MAR-APR 2015 New Intertidal Wetland Tide at 6.3 ft (Rock Sill submerged)
Elevation (ft NAVD88) 13.0 12.5 12.0 11.5 11.0 10.5 10.0 9.5 9.0 8.5 8.0 7.5 7.0 6.5 6.0 5.5 5.0 4.5 4.0 3.5 3.0 Nov-14 Dec-14 Jan-15 Feb-15 Mar-15 Apr-15 May-15 Jun-15 FALL MW-3 Ground Water Elevations (NOV 2014 - FEB 2016) Ground water elevation recorded 16 ft below "ground surface" of 15 ft NAVD, 100 ft North of New Wetland New Wetland Creation Well cover elevation (ft NAVD88) = 14.021 Distance from well cover to top of casing (ft) = 0.66 Top of casing elevation (ft NAVD88) = 13.361 Elevation of pressure transducer = -1.379 ft NAVD Seasonal Surcharge of Ground Water likely associated with creation of New Wetland First Fall Storm Tidal Exchange Effects First Big Winter Storm Jul-15 Aug-15 Sep-15 Oct-15 Nov-15 Dec-15 Jan-16 Feb-16 WINTER SPRING Date SUMMER FALL WINTER
2015 14 McKenzie Lake - Headwater Culvert - US, @ pre-exsting wetland, inv@8.9 ft NAVD 13 New Wetland - Outlet at Jetty, weir at 3-6 ft NAVD 12 Ocean Tide-NOAA Groundwater Well #3 Water Surface Elevation, NAVD88 (ft) 11 10 First Fall Storm 9 Tidal Exchange Effects 8 7 6 5 4 3 2 1 0-1 5-Jul 15-Jul 25-Jul 4-Aug 14-Aug 24-Aug 3-Sep 13-Sep 23-Sep 3-Oct
Water Surface Elevation, NAVD88 (ft) 14 13 12 11 Tidal Exchange Effects McKenzie Lake - Headwater Culvert - US, @ pre-exsting wetland, inv@8.9 ft NAVD New Wetland - Outlet at Jetty, weir at 3-6 ft NAVD Ocean Tide-NOAA Groundwater Well #3 10 9 8 WSE in Pre-Existing Wetland 7 6 5 4 3 2 1 0-1 5-Sep 10-Sep 15-Sep 20-Sep 25-Sep 30-Sep 5-Oct 2015
Tidal Response of New Intertidal Wetland Feature Minimum water surface elevation (WSE) within New Wetland is limited by base elevation of Outlet Structure (Porous Rock Sill). Minimum WSE within new intertidal wetland >= 4.8 ft NAVD near outlet (4.3 ft NAVD at west end). New Wetland Tides are affected by daily amplitude and monthly phasing of ocean tide. When Ocean daily-high tide amplitude < 7 ft NAVD, tidal response within New Wetland LAGS ocean tide by 1 hour. As Ocean daily-high tide amplitude < 5.5 ft NAVD, tidal response within New Wetland diminishes. When Ocean daily high tide amplitude > 7.8 ft NAVD, phasing of tidal response within New Wetland becomes coincident with ocean tide. When successive Ocean diurnal high tides >8 ft NAVD, high tide water level within New Wetland can become elevated above ocean high tide (groundwater & outlet effects) Ground water response LAGS New Wetland WSE variation by 3.5 hours (within 100 ft).
Groundwater Transport in Saturated Granular Soils COMPARE Darcy Equation versus Observations Seepage Velocity = (hydraulic conductivity) * (hydraulic gradient) = K * (Head Differential / Path Length) [Darcy Equation] K = 0.01 cm/sec (medium sand) to 10 cm/sec (medium gravel), assume course sand to medium gravel. K = 1 to 7 cm/sec Head Differential = Tidal Elevation in New Wetland - Ground Water Elevation at point of Interest MAX Transport Velocity of Groundwater between New Wetland and GMW #3 occurs when difference in GW elevation and Tide in New Wetland is MAX. MAX Head Differential = 2 ft Path Length = 100 ft, Distance between New Wetland (shore) and GM Well #3 assumes stead- state conditions Max Seepage Velocity = 1 cm/sec * (2 ft*30.5 cm per ft / 100 ft*30.5 cm/ft) = 0.02 cm/sec (sand) = 0.14 cm/sec (gravel) Time for Tide in Wetland to affect Ground Water at GMW #3 = 100 ft*30.5 cm per ft / 0.02 cm/sec) = 42 hours (sand) = 6 hours (gravel) Monitoring indicates that WSE within New Wetland affects groundwater at GMW #3 within 3.5 hours Observed Seepage Velocity > Darcy Velocity (likely due to transient conditions or varied substrate)
Water Surface Elevation, NAVD88 (ft) 14 13 12 11 10 9 8 7 McKenzie Lake - Headwater New Wetland - Outlet at Jetty, weir@ 3-6 ft NAVD Ground Water Well #3 WSE in Pre-Existing Wetland Groundwater Well #3 First Fall Storm Culvert-US, @ pre-existing wetland, inv@8.9 ft NAVD Ocean Tide-NOAA 0.15 inches 0.15 inches 1.3 inches Rainfall during 28-30 Aug surcharging McKenzie Lake Tidal Flow into existing wetland from New Wetland 6 5 4 3 2 1 0-1 27-Aug 28-Aug 29-Aug 30-Aug 31-Aug 2015
First Fall Storm 0.15 inches 0.15 inches 1.3 inches Rainfall during 28-30 Aug surcharging McKenzie Lake WSE in Pre-Existing Wetland Groundwater Well #3 Storm Surge 2015
14 13 Water Surface Elevation, NAVD88 (ft) 12 First Big Winter Storm 11 10 9 8 7 6 5 4 3 2 1 0-1 McKenzie Lake - Headwater Culvert - US, @ pre-exsting wetland, inv@8.9 ft NAVD New Wetland - Outlet at Jetty, weir at 3-6 ft NAVD Ocean Tide-NOAA Groundwater Well #3-2 16-Oct 26-Oct FALL 5-Nov 15-Nov 2015 25-Nov 5-Dec 15-Dec WINTER 25-Dec 4-Jan 14-Jan 2016 24-Jan 3-Feb
Water Surface Elevation, NAVD88 (ft) 14 13 12 11 10 9 8 7 6 5 4 3 2 First Big Winter Storm 2.5 0.8 0.1 0.2 0.5 Rainfall during 1-19 NOV surcharging McKenzie Lake WSE in Pre-Existing Wetland 1.3 0.6 0.4 0.1 McKenzie Lake Headwater 1.3 3.5 2.5 0.4 2.3 1.3 0.6 Groundwater Well #3 1 0-1 -2 McKenzie Lake - Headwater Culvert - US, @ pre-exsting wetland, inv@8.9 ft NAVD New Wetland - Outlet at Jetty, weir at 3-6 ft NAVD Ocean Tide-NOAA Groundwater Well #3 1-Nov 3-Nov 5-Nov 7-Nov 9-Nov 11-Nov 13-Nov 15-Nov 17-Nov 19-Nov 21-Nov 23-Nov 25-Nov 27-Nov 29-Nov 2015
Water Surface Elevation, NAVD88 (ft) 14 13 12 11 10 9 8 7 6 5 4 3 2 First Big Winter Storm 2.5 0.8 0.1 0.2 0.5 McKenzie Lake - Headwater New Wetland - Outlet at Jetty, weir at 3-6 ft NAVD Groundwater Well #3 1.3 0.6 0.4 0.1 Culvert US, within pre-existing wetland invert @ 8.9 ft NAVD McKenzie Lake Headwater 1.3 3.5 2.5 0.6 0.4 2.3 1.3 Rainfall during 1-19 NOV surcharging McKenzie Lake Culvert - US, @ pre-exsting wetland, inv@8.9 ft NAVD Ocean Tide-NOAA Non-Tidal Resdual Groundwater Well #3 1 0-1 Storm Surge -2 1-Nov 3-Nov 5-Nov 7-Nov 9-Nov 11-Nov 13-Nov 15-Nov 17-Nov 19-Nov 21-Nov 23-Nov 25-Nov 27-Nov 29-Nov 2015
Interaction of New Wetland With Groundwater Groundwater Elevation is affected by the monthly phasing and daily amplitude of WSE within New Wetland. Daily Variation of GW WSE: 0.4 ft during spring diurnal tide & 0.2 ft during neap tide. Bi-Weekly Variation of GW WSE : 0.7 ft from spring to neap phase. During periods of sustained Storm Surge, Groundwater Elevation can be elevated accordingly without the upland or precipitation effects. The combination of Upland Surcharging of the Existing Wetland, Precipitation, and Elevated Ocean WSE can increase Groundwater Elevation near the New Wetland such that GWE exceeds WSE with the New and Existing Wetlands (GWE is super-elevated) When GWE is super-elevated, it can have a feed-back effect on sustaining an elevated WSE within the New Wetland.In winter GWE > 11 ft NAVD Groundwater Exchange with Wetland Features is complex, unsteady, and seasonal. Monitoring is needed to resolve site-specific hydrologic complexities to understand wetland function.
Interaction of New Wetland With Pre-Existing Wetland Water Surface Elevation (Hydrology) within Pre-Existing Wetland is affected primarily by surcharging from upland flow (McKenzie Lake), and not by the New Wetland. This effect diminishes during summer, when regular precipitation stops. The New wetland feature maintains similar hydraulic connectivity to the Pre-Existing wetland as compared to pre-construction conditions.culvert replacement was implemented according previous culvert aspects. Terminal drainage through North Jetty is similar as for the previous Lagoon Condition. When WSE within New Wetland > 8.9 ft NAVD, direct tidal surcharging can be imposed on the Pre-existing Wetland (by inland flow though reconstructed culvert). This process can occur during annual-spring tide conditions or when storm surge affects high tide. Hydrology of the Pre-Existing Wetland can significantly Affect the New Wetland though direct discharge of surface water (via culvert when WSE >8.9 ft NAVD) or by Elevated groundwater elevation. The Two Wetlands are intrinsically linked as a dynamic Freshwater-Saltwater System