Phytoplankton Spatial Variability in the River-Dominated Estuary, Apalachicola Bay, Florida

  • Natalie L. Geyer
  • Markus Huettel
  • Michael S. Wetz
Article
  • 17 Downloads

Abstract

In shallow estuaries with strong river influence, the short residence time and pronounced gradients generate an environment for plankton that differs substantially in its dynamics from that of the open ocean, and the question arises “How is phytoplankton biomass affected?” This study assesses the small-scale spatial and temporal distribution of phytoplankton in Apalachicola Bay, a shallow bar-built estuary in the Florida Panhandle. Phytoplankton peaks were characterized to gain insights into the processes affecting spatial heterogeneity in biomass. Chlorophyll a (Chl a) distribution at 50-m spatial resolution was mapped using a flow-through sensor array, Dataflow©, operated from a boat that sampled four transects across the bay every 2 weeks for 16 months. Chl a peaks exceeding background concentrations had an average width of 1.3 ± 0.7 km delineated by an average gradient of 3.0 ± 6.0 μg Chl a L−1 km−1. Magnitude of E-W wind, velocity of N-S wind, tidal stage, and temperature affected peak characteristics. Phytoplankton contained in the peaks contributed 7.7 ± 2.7% of the total integrated biomass observed along the transects during the study period. The river plume front was frequently a location of elevated Chl a, which shifted in response to river discharge. The results demonstrate that despite the shallow water column, river flushing, and strong wind and tidal mixing, distinct patchiness develops that should be taken into consideration in ecological studies and when assessing productivity of such ecosystems.

Keywords

Phytoplankton Patchiness Estuaries Chlorophyll Dataflow Spatial variability Apalachicola Bay Florida USA 

Notes

Acknowledgments

We thank the Apalachicola National Estuary Research Reserve (NERR) staff for providing boat time and assistance to conduct transect sampling, Alex Davis (FSU) and Emily Hutchinson (FSU) for helping with field sampling and lab analysis, Chris Madden (SFWMD), Dave Oliff (FSU) and Alan Michaels (FSU) for technical support of the project, as well as Bill Parker (FSU) for helpful feedback about the peak analysis method. We thank the associate editor and two anonymous reviewers for their insightful comments and suggestions that helped to improve this manuscript.

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References

  1. Abraham, E.R. 1998. The generation of plankton patchiness by turbulent stirring. Nature 391 (6667): 577–580.CrossRefGoogle Scholar
  2. Anttila, S., T. Kairesalo, and P. Pellikka. 2008. A feasible method to assess inaccuracy caused by patchiness in water quality monitoring. Environmental Monitoring and Assessment 142 (1-3): 11–22.CrossRefGoogle Scholar
  3. Artigas, M.L., C. Llebot, O.N. Ross, N.Z. Neszi, V. Rodellas, J. Garcia-Orellana, P. Masqué, J. Piera, M. Estrada, and E. Berdalet. 2014. Understanding the spatio-temporal variability of phytoplankton biomass distribution in a microtidal Mediterranean estuary. Deep Sea Research Part II: Topical Studies in Oceanography 101: 180–192.CrossRefGoogle Scholar
  4. Aurin, D.A., and H.M. Dierssen. 2012. Advantages and limitations of ocean color remote sensing in CDOM-dominated, mineral-rich coastal and estuarine waters. Remote Sensing of Environment 125: 181–197.CrossRefGoogle Scholar
  5. Bianchi, T.S. 2006. Biogeochemistry of estuaries. Oxford University Press.Google Scholar
  6. Blondeau-Patissier, D., J.F. Gower, A.G. Dekker, S.R. Phinn, and V.E. Brando. 2014. A review of ocean color remote sensing methods and statistical techniques for the detection, mapping and analysis of phytoplankton blooms in coastal and open oceans. Progress in Oceanography 123: 123–144.CrossRefGoogle Scholar
  7. Blondeau-Patissier, D., V. Brando, K. Oubelkheir, A. Dekker, L. Clementson, and P. Daniel. 2009. Bio-optical variability of the absorption and scattering properties of the Queensland inshore and reef waters, Australia. Journal of Geophysical Research: Oceans 114 (C5).Google Scholar
  8. Camp, E.V., W.E. Pine Iii, K. Havens, A.S. Kane, C.J. Walters, T. Irani, A.B. Lindsey, and J.J.G. Morris. 2015. Collapse of a historic oyster fishery: diagnosing causes and identifying paths toward increased resilience. Ecology and Society 20 (3).Google Scholar
  9. Chanton, J., and F.G. Lewis. 2002. Examination of coupling between primary and secondary production in a river-dominated estuary: Apalachicola Bay, Florida, USA. Limnology and Oceanography 47 (3): 683–697.CrossRefGoogle Scholar
  10. Cloern, J.E. 1991. Tidal stirring and phytoplankton bloom dynamics in an estuary. Journal of Marine Research 49 (1): 203–221.CrossRefGoogle Scholar
  11. Cloern, J.E. 1996. Phytoplankton bloom dynamics in coastal ecosystems: a review with some general lessons from sustained investigation of San Francisco Bay, California. Reviews of Geophysics 34 (2): 127–168.CrossRefGoogle Scholar
  12. Cloern, J.E. 2001. Our evolving conceptual model of the coastal eutrophication problem. Marine Ecology Progress Series 210: 223–253.CrossRefGoogle Scholar
  13. Cloern, J.E., and R. Dufford. 2005. Phytoplankton community ecology: principles applied in San Francisco Bay. Marine Ecology Progress Series 285: 11–28.CrossRefGoogle Scholar
  14. de Kerckhove, D.T., E.A. Blukacz-Richards, B.J. Shuter, L. Cruz-Font, and P.A. Abrams. 2015. Wind on lakes brings predator and prey together in the pelagic zone. Canadian Journal of Fisheries and Aquatic Sciences 72 (11): 1652–1662.CrossRefGoogle Scholar
  15. Denman, K., and A. Gargett. 1983. Time and space scales of vertical mixing and advection of phytoplankton in the upper ocean. Oceanography 28.Google Scholar
  16. Dulaiova, H., and W.C. Burnett. 2008. Evaluation of the flushing rates of Apalachicola Bay, Florida via natural geochemical tracers. Marine Chemistry 109 (3-4): 395–408.CrossRefGoogle Scholar
  17. Dustan, P., and J.L. Pinckney. 1989. Tidally induced estuarine phytoplankton patchiness. Limnology and Oceanography 34 (2): 410–419.CrossRefGoogle Scholar
  18. Edmiston, H.L. 2008. A river meets the bay. The Apalachicola Estuarine System. Apalachicola National Estuarine Research Reserve, Florida Department of Environmental Protection, Tallahassee, Florida: 1–188.Google Scholar
  19. Edmiston, H.L., S.A. Fahrny, M.S. Lamb, L.K. Levi, J.M. Wanat, J.S. Avant, K. Wren, and N.C. Selly. 2008. Tropical storm and hurricane impacts on a Gulf Coast estuary: Apalachicola Bay, Florida. Journal of Coastal Research 10055: 38–49.CrossRefGoogle Scholar
  20. Folt, C.L., and C.W. Burns. 1999. Biological drivers of zooplankton patchiness. Trends in Ecology & Evolution 14 (8): 300–305.CrossRefGoogle Scholar
  21. Franks, P.J. 1992. Phytoplankton blooms at fronts: Patterns, scales, and physical forcing mechanisms. Reviews in Aquatic Sciences 6: 121–137.Google Scholar
  22. Fulmer, J.M. 1997. Nutrient enrichment and nutrient input to Apalachicola Bay, Florida. Masters thesis, Florida State University, Tallahassee, Florida.Google Scholar
  23. Gabrielson, J., and R. Lukatelich. 1985. Wind-related resuspension of sediments in the Peel-Harvey estuarine system. Estuarine, Coastal and Shelf Science 20 (2): 135–145.CrossRefGoogle Scholar
  24. Geyer, W. 1997. Influence of wind on dynamics and flushing of shallow estuaries. Estuarine, Coastal and Shelf Science 44 (6): 713–722.CrossRefGoogle Scholar
  25. Gliwicz, Z.M., and P. Maszczyk. 2015. Heterogeneity in prey distribution allows for higher food intake in planktivorous fish, particularly when hot. Oecologia 180: 383–399.CrossRefGoogle Scholar
  26. Hamner, W.M., and I.R. Hauri. 1981. Effects of island mass: water flow and plankton pattern around a reef in the Great Barrier Reef lagoon, Australia. Limnology and Oceanography 26 (6): 1084–1102.CrossRefGoogle Scholar
  27. Harding, L.W., and E.S. Perry. 1997. Long-term increase of phytoplankton biomass in Chesapeake Bay, 1950-1994. Marine Ecology Progress Series 157: 39–52.CrossRefGoogle Scholar
  28. Harris, G.P. 1986. Phytoplankton ecology: structure, function and fluctuation. London: Chapman and Hall.CrossRefGoogle Scholar
  29. Haury, L., J. McGowan, and P. Wiebe. 1978. Patterns and processes in the time-space scales of plankton distributions. In Spatial pattern in plankton communities, ed. J.H. Steele, 277–327. New York, NY: Plenum Press.CrossRefGoogle Scholar
  30. Hestir, E.L., V.E. Brando, M. Bresciani, C. Giardino, E. Matta, P. Villa, and A.G. Dekker. 2015. Measuring freshwater aquatic ecosystems: the need for a hyperspectral global mapping satellite mission. Remote Sensing of Environment 167: 181–195.CrossRefGoogle Scholar
  31. Huang, W. 2010. Hydrodynamic modeling and ecohydrological analysis of river inflow effects on Apalachicola Bay, Florida, USA. Estuarine, Coastal and Shelf Science 86 (3): 526–534.CrossRefGoogle Scholar
  32. Huang, W., S. Chen, X. Yang, and E. Johnson. 2014. Assessment of chlorophyll-a variations in high- and low-flow seasons in Apalachicola Bay by MODIS 250-m remote sensing. Environmental Monitoring and Assessment 186 (12): 8329–8342.CrossRefGoogle Scholar
  33. Huang, W., W.K. Jones, and T.S. Wu. 2002a. Modelling wind effects on subtidal salinity in Apalachicola Bay, Florida. Estuarine, Coastal and Shelf Science 55 (1): 33–46.CrossRefGoogle Scholar
  34. Huang, W., H. Sun, S. Nnaji, and W.K. Jones. 2002b. Tidal hydrodynamics in a multiple-inlet estuary: Apalachicola Bay, Florida. Journal of Coastal Research 18: 674–684.Google Scholar
  35. Jassby, A.D., B.E. Cole, and J.E. Cloern. 1997. The design of sampling transects for characterizing water quality in estuaries. Estuarine, Coastal and Shelf Science 45 (3): 285–302.CrossRefGoogle Scholar
  36. Jones, W., and G. Rodriguez. 1995. Apalachicola Bay freshwater needs assessment program, geophysical data collection program. Northwest Florida Water Management District. Water Resources Special Reports 95:95.Google Scholar
  37. Joshi, I.D., E.J. D'Sa, C.L. Osburn, T.S. Bianchi, D.S. Ko, D. Oviedo-Vargas, A.R. Arellano, and N.D. Ward. 2017. Assessing chromophoric dissolved organic matter (CDOM) distribution, stocks, and fluxes in Apalachicola Bay using combined field, VIIRS ocean color, and model observations. Remote Sensing of Environment 191: 359–372.CrossRefGoogle Scholar
  38. Kimmel, D.G., B.D. McGlaughon, J. Leonard, H.W. Paerl, J.C. Taylor, E.K. Cira, and M.S. Wetz. 2015. Mesozooplankton abundance in relation to the chlorophyll maximum in the Neuse River Estuary, North Carolina, USA: implications for trophic dynamics. Estuarine, Coastal and Shelf Science 157: 59–68.CrossRefGoogle Scholar
  39. Koseff, J.R., J.K. Holen, S.G. Monismith, and J.E. Cloern. 1993. Coupled effects of vertical mixing and benthic grazing on phytoplankton populations in shallow, turbid estuaries. Journal of Marine Research 51 (4): 843–868.CrossRefGoogle Scholar
  40. Largier, J.L. 1992. Tidal intrusion fronts. Estuaries and Coasts 15 (1): 26–39.CrossRefGoogle Scholar
  41. Largier, J.L. 1993. Estuarine fronts: how important are they? Estuaries 16 (1): 11.CrossRefGoogle Scholar
  42. Leitman, S., W. Pine III, and G. Kiker. 2016. Management options during the 2011–2012 drought on the Apalachicola River: a systems dynamic model evaluation. Environmental Management: 1–15.Google Scholar
  43. Liu, X., and N.M. Levine. 2016. Enhancement of phytoplankton chlorophyll by submesoscale frontal dynamics in the North Pacific Subtropical Gyre. Geophysical Research Letters.Google Scholar
  44. Livingston, R.J. 2010. Nutrients in the Apalachicola River-Bay System. In Report to the Florida Department of Environmental Protection.Google Scholar
  45. Livingston, R.J., F.G. Lewis, G.C. Woodsum, X.F. Niu, B. Galperin, W. Huang, J.D. Christensen, M.E. Monaco, T.A. Battista, C.J. Klein, R.L. Howell, and G.L. Ray. 2000. Modelling oyster population response to variation in freshwater input. Estuarine, Coastal and Shelf Science 50 (5): 655–672.CrossRefGoogle Scholar
  46. Livingston, R.J., X. Niu, F.G. Lewis, and G.C. Woodsum. 1997. Freshwater input to a gulf estuary: long-term control of trophic organization. Ecological Applications 7 (1): 277–299.CrossRefGoogle Scholar
  47. Llebot, C., F.J. Rueda, J. Solé, M.L. Artigas, and M. Estrada. 2014. Hydrodynamic states in a wind-driven microtidal estuary (Alfacs Bay). Journal of Sea Research 85: 263–276.CrossRefGoogle Scholar
  48. Lucas, L.V., J.R. Koseff, J.E. Cloern, S.G. Monismith, and J.K. Thompson. 1999a. Processes governing phytoplankton blooms in estuaries. I: the local production-loss balance. Marine Ecology Progress Series 187: 1–15.CrossRefGoogle Scholar
  49. Lucas, L.V., J.R. Koseff, S.G. Monismith, J.E. Cloern, and J.K. Thompson. 1999b. Processes governing phytoplankton blooms in estuaries. II: the role of horizontal transport. Marine Ecology Progress Series 187: 17–30.CrossRefGoogle Scholar
  50. Mackas, D.L., K.L. Denman, and M.R. Abbott. 1985. Plankton patchiness: biology in the physical vernacular. Bulletin of Marine Science 37: 652–674.Google Scholar
  51. Madden, C.J., and J.W. Day. 1992. An instrument system for high-speed mapping of chlorophyll a and physico-chemical variables in surface waters. Estuaries 15 (3): 421–427.CrossRefGoogle Scholar
  52. Malthus, T.J., J. Anstee, H. Botha, E. Hestir, and A. Dekker. 2015. Sentinel 3 for Inland Water Quality Monitoring-Advanced in Earth Observation Based Technologies to Assist Algal Management. In Sentinel-3 for Science Workshop, 45.Google Scholar
  53. Martin, A. 2005. The kaleidoscope ocean. Philosophical Transactions of the Royal Society of London A: Mathematical, Physical and Engineering Sciences 363 (1837): 2873–2890.CrossRefGoogle Scholar
  54. Martin, A.P. 2003. Phytoplankton patchiness: the role of lateral stirring and mixing. Progress in Oceanography 57 (2): 125–174.CrossRefGoogle Scholar
  55. Martin, A.P., M. Lévy, S. van Gennip, S. Pardo, M. Srokosz, J. Allen, S.C. Painter, and R. Pidcock. 2015. An observational assessment of the influence of mesoscale and submesoscale heterogeneity on ocean biogeochemical reactions. Global Biogeochemical Cycles 29 (9): 1421–1438.CrossRefGoogle Scholar
  56. McLeod, P., A.P. Martin, and K.J. Richards. 2002. Minimum length scale for growth-limited oceanic plankton distributions. Ecological Modelling 158 (1-2): 111–120.CrossRefGoogle Scholar
  57. McPhee-Shaw, E.E., K.J. Nielsen, J.L. Largier, and B.A. Menge. 2011. Nearshore chlorophyll-a events and wave-driven transport. Geophysical Research Letters 38 (2).Google Scholar
  58. Monbet, Y. 1992. Control of phytoplankton biomass in estuaries: a comparative analysis of microtidal and macrotidal estuaries. Estuaries 15 (4): 563–571.CrossRefGoogle Scholar
  59. Morey, S.L., and D.S. Dukhovskoy. 2012. Analysis methods for characterizing salinity variability from multivariate time series applied to the Apalachicola Bay estuary. Journal of Atmospheric and Oceanic Technology 29 (4): 613–628.CrossRefGoogle Scholar
  60. Morse, R.E., J. Shen, J.L. Blanco-Garcia, W.S. Hunley, S. Fentress, M. Wiggins, and M.R. Mulholland. 2011. Environmental and physical controls on the formation and transport of blooms of the dinoflagellate Cochlodinium polykrikoides Margalef in the lower Chesapeake Bay and its tributaries. Estuaries and Coasts 34 (5): 1006–1025.CrossRefGoogle Scholar
  61. Mortazavi, B., R.L. Iverson, W. Huang, F.G. Lewis, and J.M. Caffrey. 2000a. Nitrogen budget of Apalachicola Bay, a bar-built estuary in the northeastern Gulf of Mexico. Marine Ecology Progress Series 195: 1–14.CrossRefGoogle Scholar
  62. Mortazavi, B., R.L. Iverson, W.M. Landing, and W. Huang. 2000b. Phosphorus budget of Apalachicola Bay: a river-dominated estuary in the northeastern Gulf of Mexico. Marine Ecology Progress Series 198: 33–42.CrossRefGoogle Scholar
  63. Mortazavi, B., R.L. Iverson, W.M. Landing, F.G. Lewis, and W. Huang. 2000c. Control of phytoplankton production and biomass in a river-dominated estuary: Apalachicola Bay, Florida, USA. Marine Ecology Progress Series 198: 19–31.CrossRefGoogle Scholar
  64. Mortazavi, B., A.A. Riggs, J.M. Caffrey, H. Genet, and S.W. Phipps. 2012. The contribution of benthic nutrient regeneration to primary production in a shallow eutrophic estuary, Weeks Bay, Alabama. Estuaries and Coasts 35 (3): 862–877.CrossRefGoogle Scholar
  65. Mouw, C.B., S. Greb, D. Aurin, P.M. DiGiacomo, Z. Lee, M. Twardowski, C. Binding, C. Hu, R. Ma, and T. Moore. 2015. Aquatic color radiometry remote sensing of coastal and inland waters: challenges and recommendations for future satellite missions. Remote Sensing of Environment 160: 15–30.CrossRefGoogle Scholar
  66. Murrell, M.C., J.D. Hagy, E.M. Lores, and R.M. Greene. 2007. Phytoplankton production and nutrient distributions in a subtropical estuary: importance of freshwater flow. Estuaries and Coasts 30 (3): 390–402.CrossRefGoogle Scholar
  67. Myers, V.B. 1977. Nutrient limitation of phytoplankton productivity in north Florida coastal systems: technical considerations, spatial patterns, and wind mixing effects. Dissertation: Florida State University Tallahassee, FL.Google Scholar
  68. Oczkowski, A.J., F.G. Lewis, S.W. Nixon, H.L. Edmiston, R.S. Robinson, and J.P. Chanton. 2011. Fresh water inflow and oyster productivity in Apalachicola Bay, FL (USA). Estuaries and Coasts 34 (5): 993–1005.CrossRefGoogle Scholar
  69. Paerl, H.W., L.M. Valdes-Weaver, A.R. Joyner, and V. Winkelmann. 2007. Phytoplankton indicators of ecological change in the Eutrophying Pamlico Sound system, North Carolina. Ecological Applications 17 (sp5): S88–S101.CrossRefGoogle Scholar
  70. Petersen, J.E., W.M. Kemp, R. Bartleson, W.R. Boynton, C.C. Chen, J.C. Cornwell, R.H. Gardner, D.C. Hinkle, E.D. Houde, and T.C. Malone. 2003. Multiscale experiments in coastal ecology: improving realism and advancing theory. Bioscience 53 (12): 1181–1197.Google Scholar
  71. Petersen, J.E., W.M. Kemp, V.S. Kennedy, W.C. Dennison, and P. Kangas. 2009. Tools for design and analysis of experiments. In Enclosed experimental ecosystems and scale: tools for understanding and managing coastal ecosystems, ed. J.E. Petersen, V.S. Kennedy, W.C. Dennison, and W.M. Kemp, 133–170. New York, NY: Springer US.CrossRefGoogle Scholar
  72. Pinckney, J.L., H.W. Paerl, M.B. Harrington, and K.E. Howe. 1998. Annual cycles of phytoplankton community-structure and bloom dynamics in the Neuse River Estuary, North Carolina. Marine Biology 131 (2): 371–381.CrossRefGoogle Scholar
  73. Pine, W.E., III, C.J. Walters, E.V. Camp, R. Bouchillon, R. Ahrens, L. Sturmer, and M.E. Berrigan. 2015. The curious case of eastern oyster Crassostrea virginica stock status in Apalachicola Bay, Florida. Ecology and Society 20 (3): 46.Google Scholar
  74. Putland, J.N., and R.L. Iverson. 2007a. Ecology of Acartia tonsa in Apalachicola Bay, Florida., and implications of river water diversion. Marine Ecology Progress Series 340: 173–187.CrossRefGoogle Scholar
  75. Putland, J.N., and R.L. Iverson. 2007b. Microzooplankton: major herbivores in an estuarine planktonic food web. Marine Ecology Progress Series 345: 63–73.CrossRefGoogle Scholar
  76. Putland, J.N., B. Mortazavi, R.L. Iverson, and S.W. Wise. 2013. Phytoplankton biomass and composition in a river-dominated estuary during two summers of contrasting river discharge. Estuaries and Coasts 37: 664–679.CrossRefGoogle Scholar
  77. Roman, M., X. Zhang, C. McGilliard, and W. Boicourt. 2005. Seasonal and annual variability in the spatial patterns of plankton biomass in Chesapeake Bay. Limnology and Oceanography 50 (2): 480–492.CrossRefGoogle Scholar
  78. Seuront, L. 2005. Hydrodynamic and tidal controls of small-scale phytoplankton patchiness. Marine Ecology Progress Series 302: 93–101.CrossRefGoogle Scholar
  79. Seuront, L., F. Schmitt, Y. Lagadeuc, D. Schertzer, and S. Lovejoy. 1999. Universal multifractal analysis as a tool to characterize multiscale intermittent patterns: example of phytoplankton distribution in turbulent coastal waters. Journal of Plankton Research 21 (5): 877–922.CrossRefGoogle Scholar
  80. Spall, S., and K. Richards. 2000. A numerical model of mesoscale frontal instabilities and plankton dynamics—I. Model formulation and initial experiments. Deep Sea Research Part I: Oceanographic Research Papers 47 (7): 1261–1301.CrossRefGoogle Scholar
  81. Statham, P.J. 2012. Nutrients in estuaries—an overview and the potential impacts of climate change. Science of the Total Environment 434: 213–227.CrossRefGoogle Scholar
  82. Steele, J.H. 1978. Spatial pattern in plankton communities. New York, NY: Plenum Press.CrossRefGoogle Scholar
  83. Twichell, D., B. Andrews, L. Edmiston, and B. Stevenson. 2007. Geophysical mapping of oyster habitats in a shallow estuary: Apalachicola Bay, Florida. U.S. Geological Survey Open-File Report 2006-1381: 1-13. Google Scholar
  84. Twichell, D., L. Edmiston, B. Andrews, W. Stevenson, J. Donoghue, R. Poore, and L. Osterman. 2010. Geologic controls on the recent evolution of oyster reefs in Apalachicola Bay and St. George Sound, Florida. Estuarine, Coastal and Shelf Science 88 (3): 385–394.CrossRefGoogle Scholar
  85. Tzella, A., and P.H. Haynes. 2006. Small-scale spatial structure in plankton distributions. Biogeosciences Discussions 3 (6): 1791–1808.CrossRefGoogle Scholar
  86. Uncles, R.J., and J.A. Stephens. 2011. The effects of wind, runoff and tides on salinity in a strongly tidal sub-estuary. Estuaries and Coasts 34 (4): 758–774.CrossRefGoogle Scholar
  87. van Gennip, S., A.P. Martin, M.A. Srokosz, J.T. Allen, R. Pidcock, S.C. Painter, and M.C. Stinchcombe. 2016. Plankton patchiness investigated using simultaneous nitrate and chlorophyll observations. Journal of Geophysical Research: Oceans 121 (6): 4149–4156.Google Scholar
  88. Viveros, P.A.B. 2014. Phytoplankton biomass and composition in Apalachicola Bay, a subtropical river dominated estuary in Florida. Dissertation: University of Florida, Florida.Google Scholar
  89. Wang, H., C.M. Hladik, W. Huang, K. Milla, L. Edmiston, M.A. Harwell, and J.F. Schalles. 2010. Detecting the spatial and temporal variability of chlorophyll-aconcentration and total suspended solids in Apalachicola Bay, Florida using MODIS imagery. International Journal of Remote Sensing 31 (2): 439–453.CrossRefGoogle Scholar
  90. Ward, B.A., S. Dutkiewicz, and M.J. Follows. 2013. Modelling spatial and temporal patterns in size-structured marine plankton communities: top-down and bottom-up controls. Journal of Plankton Research 36: 31–47.CrossRefGoogle Scholar
  91. Welschmeyer, N.A. 1994. Fluorometric analysis of chlorophyll a in the presence of chlorophyll b and pheopigments. Limnology and Oceanography 39 (8): 1985–1992.CrossRefGoogle Scholar
  92. Wengrove, M.E., D.L. Foster, L.H. Kalnejais, V. Percuoco, and T.C. Lippmann. 2015. Field and laboratory observations of bed stress and associated nutrient release in a tidal estuary. Estuarine, Coastal and Shelf Science 161: 11–24.CrossRefGoogle Scholar
  93. Wetz, M.S., K.C. Hayes, A.J. Lewitus, J.L. Wolny, and D.L. White. 2006. Variability in phytoplankton pigment biomass and taxonomic composition over tidal cycles in a salt marsh estuary. Marine Ecology Progress Series 320: 109–120.CrossRefGoogle Scholar
  94. Wetz, M.S., E.A. Hutchinson, R.S. Lunetta, H.W. Paerl, and J. Christopher Taylor. 2011. Severe droughts reduce estuarine primary productivity with cascading effects on higher trophic levels. Limnology and Oceanography 56 (2): 627–638.CrossRefGoogle Scholar
  95. Wilber, D.H. 1992. Associations between freshwater inflows and oyster productivity in Apalachicola Bay, Florida. Estuarine, Coastal and Shelf Science 35 (2): 179–190.CrossRefGoogle Scholar
  96. Zhang, X., M. Roman, D. Kimmel, C. McGilliard, and W. Boicourt. 2006. Spatial variability in plankton biomass and hydrographic variables along an axial transect in Chesapeake Bay. Journal of Geophysical Research 111 (C5).Google Scholar

Copyright information

© Coastal and Estuarine Research Federation 2018

Authors and Affiliations

  • Natalie L. Geyer
    • 1
  • Markus Huettel
    • 1
  • Michael S. Wetz
    • 2
  1. 1.Department of Earth, Ocean and Atmospheric ScienceFlorida State UniversityFloridaUSA
  2. 2.Department of Life SciencesTexas A&M University-Corpus ChristiCorpus ChristiUSA

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