estuaries, coasts and our oceans of course notes series for research methods
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Estuaries, Coasts and our Oceans of Course
Notes Series for Research Methods
AtlanticPacific
Southern
Indian
Arctic
Actually there is only 1 ocean as oceans exchange water and are interconnected
Review
From National Geographic
It is measured to be the 2 x the size of Texas
Dr. Carl Safina who works on the effects of the patch displaying an item retrieved
Eleven Major Constituents in seawater
• These make up 99.99% of the salts in the ocean…
• Bicarbonate, Boron, Bromide,
• Calcium, Chloride,
• Fluoride, Magnesium,
• Potassium,
• Sodium, Strontium, Sulfate.
Two most abundant are underlined
Concentrations (mg/l except for pH) of major ionic constituents in sea water [natural or formulated with synthetic sea salts (35 g/l TDS)], dilute sea water (5 g/l TDS) and vertebrate extracellular fluid (ECF) - - adapted from Wurts and Stickney, 1989, Aquaculture, 76: 21-35.Ions Sea water1
(35 g/l TDS)Dilute sea water(5 g/l TDS)
ECF2
(9 g/l TDS)Sodium 10685 1526 3265Potassium 396 57 195Calcium 410 59 100Magnesium 1287 184 36Chloride 19215 2745 3652Bicarbonate 142 20 1708Sulfate 2511 359 48pH 7.8-8.4 7.8-8.4 7.41Gross (1977).2Guyton (1971).
High Productivity Coastal Areas
from NASA (SeaWIFS)
Coastal Types
Rocky Coasts Mountain Coasts Northern Boreal Coasts
Western Coasts U.S. Barrier Island Coast
Coastlines and Productivity
Coastal diagram with the area of nearshore and offshore productivity
oceanworld.tamu.edu
Beaches
http://www.usa-chamber.com/gulf-beaches/home.html
J Wnek
Basic Definition of Estuary – A water body where salt & freshwater mix
Technical Definition - “A standing water body within the coastal region where there is a greater net inflow of freshwater than an influx of sea water”
Estuary Types: Classified by Geology
• Lagoon – parallel to coast (i.e. Indian River Lagoon, Florida) – Bar-Built Estuaries
• Coast Plain Estuary – erosion (i.e. Chesapeake Bay and Delaware Bay)
Estuary Types: by Geology
• Tectonic Estuary – faults (i.e. San Francisco Bay)
• Fjord – glacier formation (i.e. Alaska, British Columbia, Norway, Chile)
• Delta- formed at mouth of a river (i.e. – Mississippi Delta)
Sandy Hook, N.J.
Ocean City, Maryland
Aerial view of Oregon Inlet with highway 12- on Hatteras Island, NC. (Mallison et al. 2009)
Mallison, Riggs, Culver and Ames, East Carolina University, 2009
Geological sequence of sea level rise and the succession of Pamlico Sound
San Francisco Bay Estuary – a tectonic estuary
ONR.NAVY.MIL
Geiranger Fjord, Norway Kejser Franz Joseph Fjord, Greenland
Kenai River Delta, Alaska
Factors influencing an estuary
• Temperature
• Salinity
• Nutrients
Anthropogenic effects (review)
• Increased runoff
• Development causing habitat fragmentation
• Global Climatic Changes
Temperature
• Temperatures may change with shifting tidal regimes
• There can be temperature inversions during the evenings, especially in the fall when cooler temperatures may be at the surface.
Classification of Systems
• Nontidal Fresh 0 ppt, no tidal influence
• Tidal Fresh 0 - 1 ppt, tidal influence
• Oligohaline 2 - 5 ppt (slightly brackish)
• Mesohaline 8 - 15 ppt (brackish)
• Polyhaline 18 ppt and up (salt water)
Salinity
• Salinity can vary in estuaries based upon the amount of salt water inflow and freshwater inputs.
• Estuaries can be classified according to the layering of salt water based on density- well-mixed
- partially-mixed - salt wedge (highly stratified)
Reverse Estuaries
• Some estuaries show an increase in salinity over time, these are considered “reverse estuaries” or “negative estuaries.”
• There is a net increase in salinity over time mostly due to human impacts (i.e. dams and loss of freshwater flow into the system)
Swan River Estuary, W. Australia (Neira et al., 1992)
(Zedler et al. 2001)
Flushing Time?
• Considered the amount of time in which all water is totally exchanged in an estuary
• Varies according to the estuary due to ocean access, freshwater runoff (called inflow) and depth of the estuary
tF = VF / R tF is the flushing time
Vf is the freshwater volume
R is the river discharge rate This equatio
n is n
ot require
d
Flushing Time* ComparisonsEstuary Minimum Maximum Mean
Chesapeake Bay, MD-VA
210 days (Guo)
Delaware Bay, DE-NJ
100 days(Delaware Estuary Program)
Barnegat Bay, NJ
24 days (January 1995)
74 days (June/July 1995)
49 days (Guo)
North River, MA
3 days (Geyer)
9 days
(Geyer)
Not determined
Marsh Zonation
• High Marsh – Not flooded regularly with predominant Spartina patens and Phragmites– Series of marsh pools at higher elevations
• Low Marsh – Floods regularly with Spartina alterniflora– Creeks and ditches with sometimes tidal effects – Support a higher density of finfish than SAV beds
(Sogard and Able 1991).
Marsh Zones (Jones and Strange 2006)
Anthropogenic Effects on Coastlines
Coastal erosion in Norfolk in 1997
Human Impacts and Changes in Estuaries
In the past eighteen thousand years, sea level has risen one hundred meters (three hundred feet), converting freshwater rivers into brackish estuaries (Donn, Farrand, and Ewing 1962). The Delaware River is an Alluvial Plain
Delaware Bay and human impacts
Hull, C.H.J. and J.G.Titus (eds). 1997. Greenhouse Effect, Sea Level Rise, and Salinity in the Delaware Estuary.. Washington, D.C.: U.S. Environmental Protection Agency and Delaware River Basin Commission.
Delaware River Fluxes in Sea Level Rise
Hartig et al. 2002
Davidson-Arnott, R. 2005. Conceptual model of the effects of sea level rise on sandy coasts. Journal of Coastal Research 21 (6): pp. 1166-1172.
Proposed Bruun Model with changing sea level
Shifting of dunes and berms in response to sea level rise
Mallison, Riggs, Culver and Ames, East Carolina University, 2009
ReferencesAble, K, D.A. Witting, R. McBride, R. Rountree, and K.J. Smith. 1996. Fishes of polyhaline estuarine shores in
Great Bay-Little Egg Harbor, New Jersey: a case study of seasonal and habitat influences in Estuarine Shores by K.F. Nordstrom and C.T. Roman (eds.). John Wiley and Sons, England: pp. 335-353.
Candolin, U., T. Salesto, and M. Evers. Changed environmental conditions weaken sexual selection in sticklebacks. 2006. The Authors: Journal Compilation in the European Society for Evolutionary Biology 20: pp. 233- 239.
Carlson, D.M., and R.A. Daniels. 2004. Status of Fishes in New York: Increases, Declines, and Homogenization of Watersheds. American Midland Naturalist 152: pp. 104-139.
Davidson-Arnott, R. 2005. Conceptual model of the effects of sea level rise on sandy coasts. Journal of Coastal Research 21 (6): pp. 1166-1172.
Diffenbaugh, N.S., M.A. Snyder, and L.C. Sloan. 2004. Could CO2- induced land cover feedbacks alter near-shore upwelling regimes. Proceeding of the Natural Academy of Science, 101 (1): pp. 27-32.
Dybas, C.L. 2006. On a Collision Course: Ocean Plankton and Climate Change. BioScience 56 (8): pp. 642-646.
Galbraith, H., R. Jones, J. Clough, S. Herrod-Julius, B. Harrington, and G. Page. 2002. Global Climatic Change and Sea Level Rise: Potential Losses of Intertidal Habitat for Shorebirds. Waterbirds 25 (2): pp. 173-183.
Guo, Q., N. P. Psuty, G.P. Lordi, S. Glenn, and M.R. Mund.1995. Hydrographic Study of Barnegat Bay, Year 1: Volume 1 and 2. Prepared by the Rutgers the State University of New Jersey, New Brunswick, NJ, for the New Jersey Department of Environmental Protection, Division of Science and Research.
Guo, Q. and Valle-Levinson. 2007. Tidal effects on estuarine circulation and outflow plume in the Chesapeake Bay. Continental Shelf Research 27: 20-42.
References (cont’d)Gray, V.R., 1998. "The IPCC future projections: are they plausible". Climate Research 10 pp. 155-162
Green, R., J.E. Maldonado, S. Droege, and M.V. McDonald. 2006. Tidal Marshes: A Global Perspective on the Evolution and Conservation of their Terrestrial Vertebrates. BioScience 56 (8): pp. 675 – 685.
Hartig, E.K., V. Gornitz, A. Kolker, F. Mushacke and D. Fallon. 2002. Athropogenic effects and climate-change impacts on salt marshes of Jamaica Bay, New York City. Wetlands 22 (1): pp. 71 – 89.
Hull, C.H.J. and J.G.Titus (eds). 1997. Greenhouse Effect, Sea Level Rise, and Salinity in the Delaware Estuary.. Washington, D.C.: U.S. Environmental Protection Agency and Delaware River Basin Commission.
Jones, R. and E. Strange. 2006. A Pilot Study of the Ecological Consequences of Human Responses to Sea Level Rise. Stratus Consulting Inc., Boulder Colorado as part of a supporting document for the Barnegat Bay National Estuary Program’s Conservation and Management Plan (item 4.1): pp. 1- 61.
Neira, F.J., I.C. Potter, and J.S. Bradley. 1992. Seasonal and spatial changes in the larval fish fauna within a large, temperate Autralian estuary. Marine Biology 112: 1- 16.
Ogdon, J., S.M. Davis, T.K. Barnes, K.J. Jacobs, and J.H. Gentile. 2005. Total System Conceptual Ecological Model. Wetlands 25 (4): 955-979.
Reed, D.J., D.A. Bishara, D.R. Cahoon, J. Donnelly, M. Kearney, A.S. Kolker, L.L. Leonard, R.A. Orson, and J.C. Stevenson. 2006. Site-specific scenarios for wetlands accretion as sea level rises in Mid-Atlantic Region. Supporting document for CCSP 4.1 to Climatic Change Division U.S. Environmental Protection Agency: pp. 1- 54.
Zedler, J.B. 2005. Restoring wetland plant diversity: a comparison of existing and adaptive approaches. Wetlands Ecology and Management 13: 5-14.