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  • Almroth-Rosell, E., A.Tengberg, S.Andersson, A.Apler, and P. O. J.Hall (2012), Effects of simulated natural and massive resuspension on benthic oxygen, nutrient and dissolved inorganic carbon fluxes in Loch Creran, Scotland, J. Sea Res., 72, 3848.
  • Bokuniewicz, H. J. (1992), Analytical descriptions of subaqueous groundwater seepage, Estuaries, 15, 458464.
  • Bokuniewicz, H. J., and M.Zeitlin (1980), Characteristics of ground-water seepage into Great South Bay, Special Rep. 35, State Univ. of New York, Stony Brook Marine Sciences Research Center, Stony Brook, New York.
  • Burnett, W. C., and H.Dulaiova (2003), Estimating the dynamics of groundwater input into the coastal zone via continuous Radon-222 measurements, J. Environ. Radioact., 69, 2135.
  • Burnett, W. C., H. J.Bokuniewicz, M.Huettel, W. S.Moore, and M.Taniguchi (2003), Groundwater and pore water inputs to the coastal zone, Biogeochemistry, 66, 333.
  • Burnett, W. C., et al. (2006), Quantifying submarine groundwater discharge in the coastal zone via multiple methods, Sci. Total Environ., 367, 498543.
  • Cable, J. E., W. C.Burnett, J. P.Chanton, and G. L.Weatherly (1996), Estimating groundwater discharge into the Northeastern Gulf of Mexico using Radon-222, Earth Planet. Sci. Lett., 144, 591604.
  • Charette, M. A., K. O.Buesseler, and J. E.Andrews (2001), Utility of radium isotopes for evaluating the input and transport of groundwater-derived nitrogen to a Cape Cod estuary, Limnol. Oceanogr., 46, 465470.
  • Cooper, H. H., F. A.Kohout, H. R.Henry, and R. E.Glover (1964), Sea water in coastal aquifers, Water Supply Paper 1613-C, U.S. Geological Survey, Fla.
  • Dimova, N. T., W. C.Burnett, and K.Speer (2011), A natural tracer investigation of the hydrological regime of Spring Creek Springs, the largest submarine spring system in Florida, Cont. Shelf Res., 31, 731738.
  • Ellins, K. K., A.Roman-Mas, and R.Lee (1990), Using Rn-222 to examine ground water/surface discharge interaction in the Rio Grande de Manati, Puerto Rico, J. Hydrol., 115, 319341.
  • Grantham, K. N. (1953), Wave runup on sloping structures, Trans. Am. Geophys. Union, 34, 720724.
  • Huettel, M., and G.Gust (1992), Impact of bioroughness on interfacial solute exchange in permeable sediments, Mar. Ecol. Prog. Ser., 89, 253267.
  • Huettel, M., W.Ziebis, and S.Forster (1996), Flow-induced uptake of particulate matter in permeable sediments, Limnol. Oceanogr., 41, 309322.
  • Hughes, S. A. (2004), Estimation of wave run-up on smooth, impermeable slopes using the wave momentum flux parameter, Coastal Eng., 51, 10851104.
  • King, J. N. (2008), Analytical benthic flux model forced by surface-gravity waves: Application to the South Atlantic Bight, in Proceedings of the 20th Saltwater Intrusion Meeting, Naples, Florida, edited by C. D.Langevin, et al., pp. 117120, Inst. of Food and Agricultural Science, Univ. of Florida, Gainesville, Fla.
  • King, J. N. (2012), Analytical characterization of selective benthic flux components in estuarine and coastal waters, in Treatise on Estuarine and Coastal Science, edited by E.Wolanski and D.McLusky, pp. 397423, Academic Press, Waltham, Mass.
  • King, J. N., A. J.Mehta, and R. G.Dean (2009), Generalized analytical model for benthic water flux forced by surface gravity waves, J. Geophys. Res., 114, C04004, doi:10.1029/2008JC005116.
  • King, J. N., A. J.Mehta, and R. G.Dean (2010), Analytical models for the groundwater tidal prism and associated benthic water flux, Hydrogeol. J., 18, 203215.
  • Li, L., D. A.Barry, F.Stagnitti, and J. Y.Parlange (1999), Submarine groundwater discharge and associated chemical input to a coastal sea, Water Resour. Res., 35, 32533259.
  • Longuet-Higgins, F. R. S. (1983), Wave set-up, percolation and undertow in the surf zone, Proc. R. Soc. A, 390, 283291.
  • Marinelli, R. L., R. A.Jahnke, D. B.Craven, J. R.Nelson, and J. E.Eckman (1998), Sediment nutrient dynamics of the South Atlantic Bight continental shelf, Limnol. Oceanogr., 43(6), 13051320.
  • Michael, H. A., M. A.Charette, and C. F.Harvey (2011), Patterns and variability of groundwater flow and radium activity at the coast: A case study from Waquoit Bay, Massachusetts, Mar. Chem., 127, 100114.
  • Moore, W. S. (1996), Large groundwater inputs to coastal waters revealed by Ra-226 enrichments, Nature, 380, 612614.
  • Moore, W. S. (2010a), The effect of submarine groundwater discharge on the ocean, Annu. Rev. Mar. Sci., 2, 5988.
  • Moore, W. S. (2010b), A reevaluation of submarine groundwater discharge along the southeastern coast of North America, Global Biogeochem. Cycles, 24, GB4005, doi:10.1029/2009GB003747.
  • National Geophysical Data Center (2010), Geophysical data system GRD98, http://www.ngdc.noaa.gov/mgg/gdas/gd_designagrid.html, Natl. Geophys. Data Cent., Boulder, Colo.
  • Nielsen, P. (1990), Tidal dynamics of the water-table in beaches, Water Resour. Res., 26, 21272134.
  • Noffke, A., C.Hensen, S.Sommer, F.Scholz, L.Bohlen, T.Mosch, M.Graco, and K.Wallmann (2012), Benthic iron and phosphorus fluxes across the Peruvian oxygen minimum zone, Limnol. Oceanogr., 57(3), 851867.
  • Paytan, A., G. G.Shellenbarger, J. H.Street, M. E.Gonneea, K.Davis, M. B.Young, and W. S.Moore (2006), Submarine groundwater discharge: An important source of new inorganic nitrogen to coral reef ecosystems, Limnol. Oceanogr., 51, 343348.
  • Precht, E., and M.Huettel (2003a), Advective pore-water exchange driven by surface gravity waves and its ecological implications, Limnol. Oceanogr., 48(4), 16741684.
  • Precht, E., and M.Huettel (2003b), Rapid wave-driven advective pore water exchange in a permeable coastal sediment, J. Sea Res., 51, 93107.
  • Reid, R. O., and K.Kajiura (1957), On the damping of gravity waves over a permeable sea bed, Trans. Am. Geophys. Union, 38, 662666.
  • Riedl, R. J., and R.Machan (1972), Hydrodynamic patterns in lotic intertidal sands and their bioclimatological implications, Mar. Biol., 13, 179209.
  • Riedl, R. J., N.Huang, and R.Machan (1972), The subtidal pump: A mechanism of interstitial water exchange by wave action, Mar. Biol., 13, 210221.
  • Santos, I., B.Eyre, and M.Huttel (2012), The driving forces of porewater and groundwater flow in permeable coastal sediments: A review, Estuarine, Coastal Shelf Sci., 98, 115.
  • Santos, I. R., F.Niencheski, W.Burnett, R.Peterson, J.Chanton, C. F. F.Andrade, I. B.Milani, A.Schmidt, and K.Knoeller (2008), Tracing anthropogenically driven groundwater discharge into a coastal lagoon from southern Brazil, J. Hydrol., 353, 275293.
  • Shum, K. T. (1992), Wave-induced advective transport below a rippled water-sediment interface, J. Geophys. Res., 97, 789808.
  • Shum, K. T., and B.Sundby (1996), Organic matter processing in continental shelf sediments—The subtidal pump revisited, Mar. Chem., 53, 8187.
  • Smith, C. G., and P. W.Swarzenski (2012), An investigation of submarine groundwater-borne nutrient fluxes to the West Florida shelf and recurrent harmful algal blooms, Limnol. Oceanogr., 57, 471485.
  • Windom, H. L., W. S.Moore, L. F. H.Niencheski, and R. A.Jahnke (2006), Submarine groundwater discharge: A large, previously unrecognized source of dissolved iron to the South Atlantic Ocean, Mar. Chem., 102, 252266.
  • Xin, P., C.Robinson, L.Li, D. A.Barry, and R.Bakhtyar (2010), Effects of wave forcing on a subterranean estuary, Water Resour. Res., 46, W12505, doi:10.1029/2010WR009632.
  • Zhang, Z., R.Lowe, J.Falter, and G.Ivey (2011), A numerical model of wave- and current-driven nutrient uptake by coral reef communities, Ecol. Modell., 222, 14561470.