Abstract
Perdido Bay is a shallow bay with narrow inlets connecting with Gulf of Mexico. It is affected by severe hypoxia problem due to its narrow tidal range of around 0.4 m. An existing calibrated eutrophication model, as described in Xia et al. (J Coastal Res 719: 73–86, 2011a), was used to simulate the bottom hypoxia of Perdido Bay in response to the changing local wind and river discharge. In addition, the response of nutrient dynamics and algae distribution to these physical forces was also discussed, in order to understand the hypoxia dynamics. Compared to a no wind case, we found that southerly (onshore) and westerly favorable winds with speed of 3 m/s or less inhibited the nutrient and algae transport, while easterly favorable winds and northerly (offshore) winds favored nutrient and algae transport. Onshore and westerly winds were most effective at inducing significantly broader and thicker hypoxic/anoxic conditions. Increasing wind speed could limit the nutrient-rich freshwater to the upper bay. On the other hand, a 5-m/s southerly wind or above was sufficient to make vertical distribution of nutrients uniform, significantly reducing areal coverage of hypoxia/anoxia. We also discovered that increasing river discharge drove the nutrient-rich, high algae waters down to the bay mouth. Under a high-volume river discharge (100 m3/s, henceforth denoted as cms), the freshwater could reach the bottom in shallow areas (e.g., depth < 1 m), whereby the severity of anoxia and hypoxia was reduced, while increasing river discharge had little effect on the bottom hypoxia and nutrient variation in deepwater.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Bianchi TS, Pennock JR, Twilley RR (eds) (1999) Biogeochemistry of Gulf of Mexico estuaries. Wiley, New York
Blumberg AF, and Mellor GL (1987) A description of a three-dimensional coastal ocean circulation model. In: Heaps NS (ed) Three-dimensional coastal ocean models. American Geophysical Union, Washington, D.C., pp 1–16
Bowman MJ (1977) Nutrient distributions and transport in Long Island Sound. Estuar Coast Mar Sci 5(4):531–548
Breitburg DL (1990) Near-shore hypoxia in the Chesapeake Bay, Patterns and relationships among physical factors. Estuar Coastal Shelf Sci 30(6):593–609
Breitburg DL (2002) Effects of hypoxia, and the balance between hypoxia and enrichment, on coastal fishes and fisheries. Estuaries 25(4b):767–781
Bricker SB, Longstaff B, Dennison W, Jones A, Boicourt K, Wicks C, Woerner J (2008) Effects of nutrient enrichment in the nation’s estuaries: a decade of change. Harmful Algae 8(1):21–32
Caffrey JM, Day JW (1986) Control of the variability of nutrients and suspended sediments in a Gulf Coast estuary by climatic forcing and spring discharge of the Atchafalaya River. Estuaries 9(4):295–300
Cerco CF, Cole T (1993) Three-dimensional eutrophication model of Chesapeake Bay. J Environ Eng 119(6):1006–1025
Cerco CF and Cole T (Eds.) (1995) User’s guide to the CE-QUAL-I three dimensional eutrophication model, release version 1.0, US Army Eng. Waterways Experiment Station, Vicksburg, MS
Di Toro D, Fitzpatrick J (eds) (1993) Chesapeake Bay sediment flux model. U.S. Army Corps of Engineers Experiment Station, Vicksburg, MS
Diaz RJ (2001) Overview of hypoxia around the world. J Environ Qual 30:275–281
Diaz RJ, Rosenberg R (2008) Spreading dead zones and consequences for marine ecosystems. Science 321(5891):926–929
Dynamis Solutions LLC (DSLLC) (2007) Perdido Bay hydrodynamic and water quality model. Reports to Florida Department of Environmental Protection, edited by F. D. o. E. Protection, Tallahassee, FL
Florida Department of Environmental Protection (FDEP) (2012) Site-specific information in support of establishing numeric nutrient criteria for Perdido Bay, edited by F. D. o. E. Protection, Tallahassee, FL
Fujiwara T, Takahashi T, Kasai A, Sugiyama Y, Kuno M (2002) The role of circulation in the development of hypoxia in Ise Bay, Japan. Estuar Coastal Shelf Sci 54(1):19–31
Geyer WR (1997) Influence of wind on dynamics and flushing of shallow estuaries. Estuar Coastal and Shelf Sci 44(6):713–722
Grubbs JW and Pittman JR (1997) Application of acoustical methods for estimating water flow and constituent loads in Perdido Bay, Florida, edited by U. S. G. Survey, Tallahassee, Florida
Holmer M (1999) The effect of oxygen depletion on anaerobic organic matter degradation in marine sediments. Estuar Coast Shelf Sci 48:383–390
Jensen HS, Mortensen PB, Andersen FO, Rasmussen E, Jensen A (1995) Phosphorus cycling in a coastal marine sediment, Aarhus Bay, Denmark. Limnol Oceanogr 40(5):908–917
Keister JE, Houde ED, Breitburg DL (2000) Effects of bottom-layer hypoxia on abundances and depth distributions of organisms in Patuxent River. Chesapeake Bay, Mar Ecol Progress Ser 205:43–59
Kennedy VS (ed) (1984) The estuary as a filter. Academic Press, Orlando
Kim T, Peter Sheng Y, Park K (2010) Modeling water quality and hypoxia dynamics in Upper Charlotte Harbor, Florida, U.S.A. during 2000. Estuarine, Coastal and Shelf Science 90(4):250–263
Kuo AY, Park K, Moustafa MZ (1991) Spatial and temporal variabilities of hypoxia in the Rappahannock River, Virginia. Estuaries 14(2):113–121
Lee YJ, Boynton WR, Li M and Li Y (2013) Role of late winter–spring wind influencing summer hypoxia in Chesapeake Bay. Estuar Coasts 36:683–696
Livingston RJ (ed) (2001) Eutrophication processes in coastal systems: origin and succession of plankton blooms and effects on secondary production in Gulf Coast estuaries. CRC Press, Washington DC
Livingston RJ (2007) Phytoplankton bloom effects on a Gulf estuary: water quality changes and biological response. Ecol Appl 17(5):S110–S128
Livingston RJ (2010) Long-term (1988–2007) response of trophic organization of an estuary (Perdido Bay) to physical alterations and plankton blooms: cumulative impacts and food web resilience, edited by F. D. o. E. Protection, Tallahassee, FL
Loesch H (1960) Sporadic mass shoreward migrations of demersal fish and crustaceans in Mobile Bay, Alabama. Ecology 41(2):292–298
Macauley JM, Engle VD, Summers JK, Clark JR, Flemer DA (1995) An assessment of water quality and primary productivity in Perdido Bay, a northern Gulf of Mexico estuary. Environ Monit Assess 36:191–205
Nakayama K, Sivapalan M, Sato C, and Furukawa K (2010) Stochastic characterization of the onset of and recovery from hypoxia in Tokyo Bay, Japan: Derived distribution analysis based on “strong wind” events. Water Resources Res. 46(12)
Nestlerode JA, Diaz RJ (1998) Effects of periodic environmental hypoxia on predation of a tethered polychaete, Glycera americana, Implications for trophic dynamics. Mar Ecol Prog Ser 172:185–195
Paerl HW, Pinckney JL, Fear JM, Peierls BL (1998) Ecosystem responses to internal and watershed organic matter loading: consequences for hypoxia in the eutrophying Neuse River Estuary, NC, USA. Mar Ecol Prog Ser 166:17–25
Park K, Kuoand AY, Neilson BJ (1996) A numerical model study of hypoxia in the tidal Rappahannock River of Chesapeake Bay. Estuar Coast Shelf Sci 42:563–581
Pena MA, Katsev S, Oguz T, Gilbert D (2010) Modeling dissolved oxygen dynamics and hypoxia. Biogeosciences 7:933–957
Perez BC, Day JW, Rouse LJ, Shaw RF, Wang M (2000) Influence of Atchafalaya River discharge and winter frontal passage on suspended sediment concentration and flux in Fourleague Bay, Louisiana. Estuar Coastal Shelf Sci 50(2):271–290
Rabalais NN, Turner ER, Sen Gupta BK, Boesch DF, Chapman P, Murrell MC (2007) Hypoxia in the northern Gulf of Mexico: does the science support the plan to reduce, mitigate, and control hypoxia. Estuar Coasts 30(5):753–772
Rabalais NN, Diaz RJ, Levin LA, Turner ER, Gilbert D, Zhang J (2010) Dynamics and distribution of natural and human-caused hypoxia. Biogeosciences 7:585–619
Sato C, Nakayama K, Furukawa K (2012) Contributions of wind and river effects on DO concentration in Tokyo Bay. Estuar Coast Shelf Sci 109:91–97
Scully ME (2010a) The importance of climate variability to wind-driven modulation of hypoxia in Chesapeake Bay. J Phys Oceanogr 40(6):1435–1440
Scully ME (2010b) Wind modulation of dissolved oxygen in Chesapeake Bay. Estuar Coasts 33(5):1164–1175
Sin Y, Wetzel RL, Anderson IC (1999) Spatial and temporal characteristics of nutrient and phytoplankton dynamics in the York River estuary, Virginia—analyses of long-term data. Estuaries 22(2):260–275
Stern MK, Day JW, Teague KG (1991) Nutrient transport in a riverine-influenced, tidal freshwater bayou in Louisiana. Estuaries 14(4):382–394
Takahashi T, Nakata H, Hirano K, Matsuoka K, Iwataki M, Yamaguchi H, Kasuya T (2009) Westerly of oxygen-depleted water (Sumishio) in Omura Bay, Japan. J Oceanogr 65(1):113–120
Verity PG, Alber M, Bricker SB (2006) Development of hypoxia in well-mixed subtropical estuaries in the southeastern USA. Estuar Coasts 29(4):665–673
Walker ND, Rabalais NN (2006) Relationships among satellite chlorophylla, river inputs, and hypoxia on the Louisiana Continental shelf, Gulf of Mexico. Estuar Coasts 29(6B):1081–1093
Whitney FA, Crawford WR, Harrison PJ (2005) Physical processes that enhance nutrient transport and primary productivity in the coastal and open ocean of the subarctic NE Pacific. Deep-Sea Res II Top Stud Oceanogr 52(5–6):681–706
Wilson RE, Swanson RL, Crowley HA (2008) Perspectives on long-term variations in hypoxic conditions in western Long Island Sound. J Geophys Res 113(C12)
Wiseman WJ, Rabalais NN, Turner ER, Dinnel SP, MacNaughton A (1997) Seasonal and interannual variability within the Louisiana coastal current: stratification and hypoxia. J Mar Syst 12:237–248
Work PA, Kaihatu JM (1997) Wave transformation at Pensacola Pass, Florida. J Waterway, Port, Coastal Ocean Eng 123(6):314–321
Xia M, Xie L, Pietrafesa LJ (2007) Modeling of the Cape Fear River estuary plume. Estuar Coasts 30(4):698–709
Xia M, Craig PM, Schaeffer B, Stoddard A, Liu Z, Peng M, Zhang H, Wallen CM, Bailey N, Mandrup-Poulsen J (2010) The numerical modeling of dissolved oxygen dynamics and its susceptibility for Caloosahatchee River Estuary and adjacent bay. J Environ Eng 136(10):1032–1044
Xia M, Craig PM, Wallen CM, Stoddard A, Mandrup-Poulsen J, Peng M, Schaeffer B, Liu Z (2011a) Numerical simulation of salinity and dissolved oxygen at Perdido Bay and adjacent coastal ocean. J Coast Res 27:73–86
Xia M, Xie L, Pietrafesa LJ, and Whitney MM (2011) The ideal response of a Gulf of Mexico estuary plume to wind forcing: its connection with salt flux and a Lagrangian view. J Geophys Res 116(C8), C08035
Acknowledgements
Previous discussion and insightful comments from Dr. Blake Schaeffer (US EPA National Health and Environmental Effects Research Laboratory) are highly appreciated. Dr. Margaret A Sexton helped improve the overall presentation of this paper, and her valuable input is acknowledged here. The authors also thank for the comments from two anonymous reviewers.
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible Editor: Tal Ezer
Rights and permissions
About this article
Cite this article
Xia, M., Jiang, L. Influence of wind and river discharge on the hypoxia in a shallow bay. Ocean Dynamics 65, 665–678 (2015). https://doi.org/10.1007/s10236-015-0826-x
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10236-015-0826-x