Skip to main content Accessibility help
×
Hostname: page-component-586b7cd67f-vdxz6 Total loading time: 0 Render date: 2024-11-25T19:13:03.967Z Has data issue: false hasContentIssue false

References

Published online by Cambridge University Press:  15 September 2022

Ping Wang
Affiliation:
University of South Florida
Tanya M. Beck
Affiliation:
US Army Engineer Research and Development Center
Get access

Summary

Image of the first page of this content. For PDF version, please use the ‘Save PDF’ preceeding this image.'
Type
Chapter
Information
Publisher: Cambridge University Press
Print publication year: 2022

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Ackers, P., 1964. Experiments on small streams in alluvium. Journal of the Hydraulics Division, ASCE, 90, 137.CrossRefGoogle Scholar
Adger, W. N., 2006. Vulnerability. Global Environmental Change, 16, 268281.Google Scholar
Adger, W. N., Hughes, T. P., Folke, C., Carpenter, S. R., and Rockstrom, J., 2005. Social-ecological resilience to coastal disasters. Science, 309, 10361039.Google Scholar
Ashton, A. D., and Lorenzo-Trueba, J., 2018. Morphodynamics of barrier response to sea-level rise. In Moore, L. J. and Murray, A. B. (eds.), Barrier Dynamics and Response to Changing Climate. Cham: Springer, 277304.CrossRefGoogle Scholar
Bagnold, R. A., 1956. Flow of cohesionless grains in fluid. Royal Philosophical Society of London Transactions, 249, 235297.Google Scholar
Bagnold, R. A., 1966. An approach to the sediment transport problem from general physics. US Geological Survey Professional Paper 422-I, Washington, DC, 37pp.Google Scholar
Bailard, J. A., and Inman, D. L., 1981a. An energetics, bedload model for a plane sloping beach: Local transport. Journal of Geophysical Research, 86(C3), 20352043.Google Scholar
Bailard, J. A., and Inman, D. L., 1981b. An energetics total load sediment transport model for a plane sloping beach. Journal of Geophysical Research, 86(C11), 1093810954.Google Scholar
Bamber, J. L., and Aspinall, W. P., 2013. An expert judgement assessment of future sea level rise from the ice sheets. Nature Climate Change, 3, 424427.Google Scholar
Basco, D. A., 2006. Shore protection projects. EM 1110-2-1100 (Part V, Chapter 3). US Army Corps of Engineers Research and Development Center, Vicksburg, MS.Google Scholar
Battjes, J. A., 1975. Modeling of turbulence in the surf zone. Proceedings of Symposium on Modeling Techniques. New York: ASCE Press, 10501061.Google Scholar
Bayram, A., Larson, M., and Hanson, H., 2007. A new formula for the total longshore sediment transport rate. Coastal Engineering, 54, 700710.CrossRefGoogle Scholar
Beck, T. M., and Kraus, N. C., 2011. New ebb-tidal delta at an old inlet, Shark River Inlet, New Jersey. Journal of Coastal Research, SI 59, 98110.Google Scholar
Beck, T. M., and Legault, K. R., 2012. Dredging optimization of an inlet system for adjacent shore protection projects using CMS and GenCade. Proceedings of the International Conference on Coastal Engineering. New York: ASCE Press, 34.Google Scholar
Beck, T. M., and Wang, P., 2009. Influences of channel dredging on flow and sedimentation patterns at microtidal inlets, west-central Florida, USA. Proceedings of Coastal Dynamics 2009. Singapore: World Scientific Publishing Company.Google Scholar
Beck, T. M., and Wang, P., 2019. Morphodynamics of barrier-inlet systems in the context of regional sediment management, with case studies from west-central Florida, USA. Ocean and Coastal Management, 177, 3151.CrossRefGoogle Scholar
Beck, T. M., Wang, P., Li, H., and Wu, W., 2020. Sediment bypassing pathways between tidal inlets and adjacent beaches. Journal of Coastal Research, 36, 897914.Google Scholar
Benedet, L., Finkl, C. W., and Hartog, W. M., 2007. Processes controlling development of erosional hot spots on a beach nourishment project. Journal of Coastal Research, 23, 3348.Google Scholar
Berkowitz, J. F., Beane, N. R., Evans, D. E., Suedel, B., and Corbino, J. M., 2015. Ecological survey of a dredged material-supported wetland in the Atchafalaya River, Louisiana: An Engineering with Nature case study. Wetland Science & Practice, 32, 1418.Google Scholar
Berkowitz, J. F., Kim, S., Beane, N. R., et al., 2017. A multifactor ecosystem assessment of wetlands created using a novel dredged material placement technique in the Atchafalaya River, Louisiana: An engineering with nature demonstration project. ERDC TR17–5. US Army Corps of Engineers Research and Development Center, Vicksburg, MS.Google Scholar
Bijker, E. W., 1996. History of coastal engineering in the Netherlands. In Kraus, N. C. (ed.), History and Heritage of Coastal Engineering. New York: ASCE Press, 390412.Google Scholar
Birkemeier, W. A., 1985. Field data on seaward limit of profile change. Journal of Waterway, Port, Coastal and Ocean Engineering, 111, 598602.CrossRefGoogle Scholar
Bixel, P. B., and Turner, E. H., 2000. Galveston and the 1990 Storm: Catastrophe and Catalyst. Austin: University of Texas Press, 174pp.Google Scholar
Bodge, K. R., 1992. Representing equilibrium beach profiles with an exponential expression. Journal of Coastal Research, 8, 4755.Google Scholar
Bodge, K. R., 1993. Gross transport effects at inlets. Proceedings of the 6th Annual National Conference on Beach Preservation Technology. Florida Shore & Beach Preservation Association, Tallahassee, FL, 112–127.Google Scholar
Bodge, K. R., 1999. Inlet impacts and families of solutions for inlet sediment budgets. Proceedings of Coastal Sediments ’99. New York: ASCE Press, 703718.Google Scholar
Bodge, K. R., and Kraus, N. C., 1991. Critical examination of longshore transport rate amplitude. Proceedings of Coastal Sediments ’91. New York: ASCE Press, 139155.Google Scholar
Bodge, K. R., and Rosati, J. D., 2003. Sediment management at inlets and Harbors. EM 1110-2-1100 (Part V, Chapter 6), US Army Corps of Engineers Research and Development Center, Vicksburg, MS.Google Scholar
Bosman, J., 1982. Concentration measurements under oscillatory motion. Report M1965-II, Delft Hydraulics, Delft, The Netherlands.Google Scholar
Bowen, A. J., 1980. Simple models of nearshore sedimentation: Beach profiles and longshore bars. In McCann, S. B. (ed.), The Coastline of Canada, Paper 80-11. Ottawa, Ontario: Geological Survey of Canada, 111.Google Scholar
Bowen, A. J., and Inman, D. L., 1966. Budget of Littoral Sand in the vicinity of Point Arguello, California. U.S. Army Coastal Engineering Research Center, Technical Memorandum No. 19, 56pp.Google Scholar
Boyd, R., and Penland, S., 1981. Washover of deltaic barriers on the Louisiana coast. Transections of Gulf Coast Association of Geological Society, 31, 243248.Google Scholar
Bridges, T. S., Lillycrop, J., Wilson, J., et al., 2014a. Engineering with nature promotes triple-win outcomes. Terra et Aqua, 135, 1723.Google Scholar
Bridges, T. S., Wagner, P. W., Burks-Copes, K. A., et al., 2014b. Use of natural and nature-based features (NNBF) for coastal resilience. ERDC SR-15-1. US Army Corps of Engineers Research and Development Center, Vicksburg, MS.Google Scholar
Browder, A. E., and Dean, R. G., 2000. Monitoring and comparison to predictive models of the Perdido Key Beach nourishment project, Florida, USA. Coastal Engineering, 39, 173191.CrossRefGoogle Scholar
Brutsche, K. E., and Pollock, C. E., 2017. Strategic placement of mixed sediment in the form of a nearshore berm along Fort Myers Beach, Florida. ERDC TN-EWN-17-1. US Army Corps of Engineers Research and Development Center, Vicksburg, MS.Google Scholar
Brutsche, K. E., Wang, P., Beck, T. M., Rosati, J. D., and Legault, K. R., 2014. Morphological evolution of a submerged artificial nearshore berm along a low-wave microtidal coast, Fort Myers Beach, west-central Florida, USA. Coastal Engineering, 91, 2944.CrossRefGoogle Scholar
Brutsche, K. E., Wang, P., Rosati, J. D., and Beck, T. M., 2015. Influence of berm elevation on the performance of beach-nearshore nourishment: A case study at Perdido Key, Florida, USA. Journal of Coastal Research, 31, 964977.Google Scholar
Bruun, P., 1954. Coastal erosion and the development of beach profiles. Technical Memorandum No.44, US Army Corps of Engineers. Beach Erosion Board.Google Scholar
Bruun, P., 1962. Sea-level rise as a cause of shore erosion. Journal of the Waterways and Harbors Division, ASCE, 88, 117130.Google Scholar
Bruun, P., 1981. Port Engineering. Houston, TX: Gulf.Google Scholar
Bruun, P., 1995. The development of downdrift erosion. Journal of Coastal Research, 11, 12421257.Google Scholar
Bruun, P., 2001. The development of downdrift erosion. An update of paper in JCR, Vol. 11(4). Journal of Coastal Research, 17, 8289.Google Scholar
Bruun, P., and Gerritsen, F., 1959. Natural by-passing of sand at coastal inlets. Journal of Waterways and Harbors Division, ASCE, 85, 75108.Google Scholar
Bruun, P., and Gerritsen, F., 1960. Stability of Coastal Inlets. Amsterdam: North-Holland.Google Scholar
Bruun, P., Mehta, A. J., and Jonsson, I. G., 1978. Stability of Tidal Inlets – Theory and Engineering. Amsterdam: Elsevier Scientific.Google Scholar
Buonaiuto, F. S., and Kraus, N. C., 2003. Limiting slopes and depths at ebb-tidal shoals. Coastal Engineering, 48, 5165.Google Scholar
Burcharth, H. F., and Hughes, S. A., 2006a. Types and functions of coastal structures. EM 1110-2-1100 (Part VI, Chapter 2). US Army Engineer Research and Development Center, Vicksburg, MS.Google Scholar
Burcharth, H. F., and Hughes, S. A., 2006b. Fundamentals of design. EM 1110-2-1100 (Part VI, Chapter 5). US Army Engineer Research and Development Center, Vicksburg, MS.Google Scholar
Buttolph, A. M., Reed, C. W., Kraus, N. C., et al., 2006. Two-dimensional depth-averaged circulation model CMS-M2D: Version 3.0, Report 2, sediment transport and morphology change. ERDC/CHL TR-06-9, US Army Engineer Research and Development Center, Vicksburg, MS, 149pp.Google Scholar
Caldwell, J. M., 1966. Coastal processes and beach erosion. Journal of the Society of Civil Engineers, 53(2), 142157.Google Scholar
Camenen, B., 2009. Estimation of the wave-related ripple characteristics and induced bed shear stress. Estuarine, Coastal and Shelf Science, 84, 553564.Google Scholar
Camenen, B., and Larroude, P., 2003. Comparison of sediment transport formulae for a coastal environment. Coastal Engineering, 48, 111132.Google Scholar
Camenen, B., and Larson, M., 2005. A general formula for noncohesive bed load sediment transport. Estuarine, Coastal, and Shelf Science, 63, 249260.Google Scholar
Camenen, B., and Larson, M., 2006. Phase-lag effects in sheet flow transport. Coastal Engineering, 56, 531542.Google Scholar
Camenen, B., and Larson, M., 2007. A unified sediment transport formulation for inlet application. ERDC/CHL CR-07-1, US Army Engineer Research and Development Center Coastal and Hydraulics Laboratory, Vicksburg, MS.CrossRefGoogle Scholar
Camenen, B., and Larson, M., 2008. A suspended load sediment transport formula for the nearshore. Journal of Coastal Research, 24, 615627.CrossRefGoogle Scholar
Carter, R. W. G., and Orford, J. D., 1993. The morphodynamics of coarse clastic beaches and barriers: A short- and long-term perspective. Journal of Coastal Research, 15(SI), 158179.Google Scholar
Cheng, J., and Wang, P., 2015. Extracting turbulence under breaking waves in the surf zone. ASCE Journal of Waterway, Port, Coastal, and Ocean Engineering, 141(6), 110.Google Scholar
Cheng, J., and Wang, P., 2018. Dynamic equilibrium of sandbar position and height along a low wave energy micro-tidal coast. Continental Shelf Research, 165, 120136.Google Scholar
Cheng, J., and Wang, P., 2019. Unusual beach changes induced by Hurricane Irma with a negative storm surge and post-storm recovery. Journal of Coastal Research, 35, 11851199.CrossRefGoogle Scholar
Cheng, J., Wang, P., and Guo, Q., 2016. Measuring beach profiles along a low-wave energy microtidal coast, west-central Florida, USA. Geosciences, 6(4), 4451.Google Scholar
Cheng, J., Wang, P., and Smith, R. E., 2015. Hydrodynamic conditions associated with an onshore migrating and stable sandbar. Journal of Coastal Research, 32, 153163.Google Scholar
Cialone, M. A., and Kraus, N. C., 2001. Engineering study of inlet entrance hydrodynamics: Grays Harbor, Washington, USA. Proceedings of Coastal Dynamics 01. New York: ASCE Press, 413422.Google Scholar
Cialone, M. A., and Stable, D. K., 1998. Historical findings on ebb shoal mining. Journal of Coastal Research, 14(2), 537563.Google Scholar
Clark, P. U., He, F., Golledge, N. R., et al., 2020. Oceanic forcing of penultimate deglacial and last interglacial sea-level rise. Nature, 577, 660664.Google Scholar
Claudino-Sales, V., Wang, P., and Horwitz, M. H., 2008. Factors controlling the survival of coastal dunes during multiple hurricane impacts in 2004 and 2005: Santa Rosa barrier island, Florida. Geomorphology, 95, 295315.Google Scholar
Claudino-Sales, V., Wang, P., and Horwitz, M. H., 2010. Effect of Hurricane Ivan on coastal dunes of Santa Rosa Barrier Island, Florida: Characterized on the basis of pre- and poststorm LIDAR surveys. Journal of Coastal Research, 26, 470484.Google Scholar
Cleary, W. J., and FitzGerald, D. M., 2003. Tidal inlet response to natural sedimentation processes and dredging-induced tidal prism changes: Mason Inlet, North Carolina. Journal of Coastal Research, 19, 10181025.Google Scholar
Coleman, J. M., 1976. Deltas: Processes of Deposition & Models for Exploration. Champaign, IL: Continuing Education Publication Co., 124pp.Google Scholar
Coleman, J. M., Roberts, H. H., and Stone, G. W., 1998. Mississippi river delta: An overview. Journal of Coastal Research, 14, 698716.Google Scholar
Cooper, J. A. G., and Pilkey, O. H., 2004. Sea-level rise and shoreline retreat: Time to abandon the Bruun Rule. Global and Planetary Change, 43, 157171.Google Scholar
Cowell, P. J., and Kinsela, M. A., 2018. Shoreface controls on barrier evolution and shoreline change. In Moore, L. J. and Murray, A. B. (eds.), Barrier Dynamics and Response to Changing Climate. Cham: Springer, 243275.Google Scholar
CPE (Coastal Planning and Engineering, Inc.), 1992. Blind Pass Inlet Management Plan. Pinellas County, FL: CPE, 68 p.Google Scholar
CTC (Coastal Technology Corporation), 1993. John’s Pass Inlet Management Plan. CTC, Vero Beach, FL: CTC, p. 28.Google Scholar
Cutter, S. L., Ash, K. D., and Emrich, C. T., 2014. The geographies of community disaster resilience. Global Environmental Change, 29, 6577.Google Scholar
Cutter, S. L., Barnes, L., Berry, M., et al., 2008. A place-based model for understanding community resilience to natural disasters. Global Environmental Change, 18(4), 598606.Google Scholar
Cutter, S. L., Burton, C. G., and Emrich, C. T., 2010. Disaster resilience indicators for benchmarking baseline conditions. Journal of Homeland Security and Emergency Management, 7(1), Article 51.Google Scholar
Dabees, M. A., and Kraus, N. C., 2005. General methodology for inlet reservoir model analysis of sand management near tidal inlets. Proceedings of Coastal Dynamics 2005, World Scientific, Inc., CD-ROM, 14 p.Google Scholar
Dabees, M. A., and Kraus, N. C., 2008. Cumulative effects of channel and ebb shoal dredging on inlet evolution in southwest Florida, USA. Proceedings of 31st International Conference on Coastal Engineering. New York: ASCE Press, 23032315.Google Scholar
Dally, W. R., Dean, R. G., and Dalrymple, R. A., 1985. Wave height variation across beaches of arbitrary profile. Journal of Geophysical Research, 90, 1191711927.Google Scholar
Davidson, S. G., Hesp, P. A., and da Silva, G. M., 2020. Controls on dune scarping. Progress in Physical Geography, 44, 923947.Google Scholar
Davidson-Arnott, R. G. D., 2005. A conceptual model of the effects of sea level rise on sandy coasts. Journal of Coastal Research, 21, 11661172.Google Scholar
Davidson-Arnott, R. G. D., and Law, M. N., 1990. Seasonal patterns and controls on sediment supply to coastal foredunes, Long Point, Lake Erie. In Nordstrom, K. F., Psuty, N. P., and Carter, R. W. G. (eds.), Coastal Dunes: Form and Process. Chichester: Wiley, 177200.Google Scholar
Davidson-Arnott, R. G. D., and Law, M. N., 1996. Measurement and prediction of long-term sediment supply to coastal foredunes. Journal of Coastal Research, 12, 654663.Google Scholar
Davis, R. A. (ed.), 1994a. Geology of Holocene Barrier Island Systems. Berlin: Springer-Verlag, 464pp.Google Scholar
Davis, R. A., 1994b. Barrier island systems – A geological overview. In Davis, R. A. (ed.), Geology of Holocene Barrier Island Systems. Berlin: Springer-Verlag, 146.Google Scholar
Davis, R. A., 1994c. Barriers of the Florida gulf peninsula. In Davis, R. A. (ed.), Geology of Holocene Barrier Island Systems. Berlin: Springer-Verlag, 167206.Google Scholar
Davis, R. A., 1994d. Other barrier systems of the world. In Davis, R. A. (ed.), Geology of Holocene Barrier Island Systems. Berlin: Springer-Verlag, 435456.Google Scholar
Davis, R. A., and FitzGerald, D. M., 2004. Beaches and Coasts. Malden, MA: Blackwell Science Ltd., 419pp.Google Scholar
Davis, R. A., Fitzgerald, M. V., and Terry, J., 1999. Turtle nesting on adjacent nourished beaches with different construction styles: Pinellas County, Florida. Journal of Coastal Research, 15, 111120.Google Scholar
Davis, R. A., and Hayes, M. O., 1984. What is a wave-dominated coast? Marine Geology, 60, 313329.Google Scholar
Davis, R. A., Wang, P., and Silverman, B. R., 2000. Comparison of the performance of three adjacent and differently constructed beach nourishment projects on the Gulf peninsula of Florida. Journal of Coastal Research, 16, 396408.Google Scholar
Day, J. W. Jr., Boesch, D. F., Clairain, E. J., et al., 2007. Restoration of the Mississippi Delta: Lessons from Hurricanes Katrina and Rita. Science, 315, 16791684.Google Scholar
Dean, R. G., 1971. Hydraulics of Inlets. COEL/UFL-71/019, Department of Coastal and Oceanographic Engineering, University of Florida, Gainesville.Google Scholar
Dean, R. G., 1977. Equilibrium beach profiles: US Atlantic and Gulf coasts. Ocean Engineering Report No. 12, Department of Civil Engineering, University of Delaware, Newark.Google Scholar
Dean, R. G., 1986. Coastal armory: Effects, principles, and mitigation. Proceedings of 20th International Conference on Coastal Engineering, New York: ASCE Press, 18431857.Google Scholar
Dean, R. G., 1987. Coastal sediment processes: Toward engineering solutions. Proceedings of Coastal Sediments ’87, New York: ASCE Press, 124.Google Scholar
Dean, R. G., 1988. Sediment interaction at modified coastal inlets: Processes and policies. Lecture Notes on Coastal and Estuarine Studies, 29. Berlin: Springer-Verlag, 412439.Google Scholar
Dean, R. G., 1990. Beach response to sea level change. In Le Mehaute, B. and Hanes, D. M. (eds.), Ocean Engineering Science, Vol 9 of The Sea. New York: Wiley, 869887.Google Scholar
Dean, R. G., 1991. Equilibrium beach profiles: Characteristics and applications. Journal of Coastal Research, 7, 5384.Google Scholar
Dean, R. G., 1996. Interaction of littoral barriers shoreline change. Journal of Coastal Research, SI23, 103112.Google Scholar
Dean, R. G., 2002. Beach Nourishment Theory and Practice. Singapore: World Scientific, 399pp.Google Scholar
Dean, R. G., and Dalrymple, R. A., 1991. Water Wave Mechanics for Engineers and Scientists. Singapore: World Scientific, 353pp.Google Scholar
Dean, R. G., and Dalrymple, R. A., 2002. Coastal Processes with Engineering Applications. New York: Cambridge University Press, 475pp.Google Scholar
Dean, R. G., and Yoo, C. H., 1992. Beach-nourishment performance predictions. Journal of Waterway, Port, Coastal and Ocean Engineering, ASCE, 118, 567585.Google Scholar
Deaton, C. D., Hein, C. J., and Kirwan, M. L., 2017. Barrier-island migration dominates ecogeomorphic feedback and drives salt marsh loss along the Virginia Atlantic Coast, USA. Geology, 45, 123126.Google Scholar
Dennis, K. C., Niang-Diop, I., and Nicholls, R. J., 1994a. Sea-level rise and Argentina: Potential impacts and consequences. Journal of Coastal Research, SI14, 205223.Google Scholar
Dennis, K. C., Schnack, E. J., Mouzo, F. H., and Orana, C. R., 1994b. Sea-level rise and Senegal: Potential impacts and consequences. Journal of Coastal Research, SI14, 243261.Google Scholar
Dingler, J. R., and Clifton, H. E., 1994. Barrier systems of California, Oregon, and Washington. In Davis, R. A. (ed.), Geology of Holocene Barrier Island Systems. Berlin: Springer-Verlag, 115165.CrossRefGoogle Scholar
Dolan, R., and Davis, R. E., 1992. An intensity scale for Atlantic Coast northeast storms. Journal of Coastal Research, 8, 840853.Google Scholar
Dolan, R., Hayden, B., and May, S., 1983. Erosion of the United States shorelines. In Komar, P. D. (ed.), Handbook of Coastal Processes and Erosion. Boca Raton, FL: CRC Press, 285299.Google Scholar
Donnelly, C., Kraus, N. C., and Larson, M., 2006. State of knowledge on measurement and modeling of coastal overwash. Journal of Coastal Research, 22, 965991.CrossRefGoogle Scholar
Dunkin, L. M., Coe, L. A., and Ratcliff, J. J., 2018. Corps shoaling analysis tool: Predicting channel shoaling. ERDC/CHL TR-18-16, 19pp.Google Scholar
Duran, O., and Moore, L., 2013. Vegetation controls on the maximum size of coastal dunes. PNAS, 110, 1721717222.Google Scholar
El-Raey, M., Nasr, S., Frihy, O., Desouki, S., and Dewidar, K., 1994. Potential impacts of accelerated sea-level rise on Alexandria Governate, Egypt. Journal of Coastal Research, SI14, 190204.Google Scholar
Elias, E. P. L., Gelfenbaum, G., and van der Westhuysen, A. J., 2012a. Validation of a coupled wave-flow model in a high-energy setting: The mouth of the Columbia River. Journal of Geophysical Research, 131, C09011.Google Scholar
Elias, E. P. L., Van der Spek, A. J. F., Wang, Z. B., and De Ronde, J., 2012b. Morphodynamic development and sediment budget of the Dutch Wadden Sea over the last century. Netherlands Journal of Geosciences, 91(3), 293310.Google Scholar
Elko, N. A., Briggs, T. R., Benedet, L., et al., 2021. A century of U.S. beach nourishment. Ocean and Coastal Management, 199, 105406.Google Scholar
Elko, N. A., Holman, R. A., and Gelfenbaum, G., 2005. Quantifying the rapid evolution of a nourishment project with video imagery. Journal of Coastal Research, 21(4), 633645.Google Scholar
Elko, N. A., and Wang, P., 2007. Immediate profile and planform evolution of a beach nourishment project with hurricane influences. Coastal Engineering, 54, 5479.Google Scholar
Emery, K. O., 1968. Relict sediments on continental shelves of the world. American Association of Petroleum Geologist Bulletin, 52, 445464.Google Scholar
Fisher, B., Turner, R. K., and Morling, P., 2009. Defining and classifying ecosystem services for decision making. Ecological Economics, 68, 643653.Google Scholar
Fisher, J. J., 1968. Barrier island formation: Discussion. Geological Society of America Bulletin, 79, 14211426.Google Scholar
Fisher, J. J., and Simpson, E. J., 1979. Washover and tidal sedimentation rates as environmental factors in development of a transgressive barrier shoreline. In Leatherman, S. P. (ed.), Barrier Islands: From the Gulf of St. Lawrence to the Gulf of Mexico. New York: Academic Press, 127148.Google Scholar
FitzGerald, D. M., 1982. Sediment bypassing at mixed energy tidal inlets. Proceedings of the Eighteenth Coastal Engineering Conference. New York: ASCE Press, 10941118.Google Scholar
FitzGerald, D. M., 1984. Interactions between the ebb-tidal delta and landward shoreline: Price inlet, South Carolina. Journal of Sedimentary Petrology, 54, 13031318.Google Scholar
FitzGerald, D. M., 1988. Shoreline erosional–depositional processes associated with tidal inlets. In Aubrey, D. G. and Weishar, L. (eds.), Hydrodynamics and Sediment Dynamics of Tidal Inlets. Berlin: Springer-Verlag, 186225.Google Scholar
Fitzgerald, D. M., 1996. Geomorphic variability and morphologic and sedimentologic controls on tidal inlets. Journal of Coastal Research, 23(SI), 4771.Google Scholar
FitzGerald, D. M., Buynevich, I. V., Davis, R. A., and Fenster, M. S., 2002. New England tidal inlets with special reference to riverine-associated inlet systems. Geomorphology, 48, 179208.Google Scholar
FitzGerald, D. M., Fenster, M. S., Argow, B. A., and Buynevich, I. V., 2008. Coastal impacts due to sea-level rise. Annual Review of Earth and Planetary Sciences, 36, 601647.Google Scholar
FitzGerald, D. M., Hein, C. J., Hughes, Z., et al., 2018. Runaway barrier island transgression concept: Global case studies. In Moore, L. J. and Murray, A. B. (eds.), Barrier Dynamics and Response to Changing Climate. Cham: Springer, 356.Google Scholar
FitzGerald, D. M., and van Heteren, S., 1999. Classification of paraglacial barrier systems: Coastal New England, USA. Sedimentology, 46, 10831108.Google Scholar
FitzGerald, D. M., Kraus, N. C., and Hands, E. B., 2000. Natural mechanism of sediment bypassing at tidal inlets. ERDC/CHL CHETN-IV-30, US Army Engineer Research and Development Center, Vicksburg, MS, 10pp.Google Scholar
Fitzgerald, D. M., and Levin, D., 1981. Hydraulics, morphology and sediment transport patterns at Pamet river inlet: Truro, Massachusetts. Northeast Geology, 3, 216224.Google Scholar
FitzGerald, D. M., and Pendleton, E., 2002. Inlet formation and evolution of the sediment bypassing system: New Inlet, Cape Cod, Massachusetts. Journal of Coastal Research, SI36, 290299.Google Scholar
FitzGerald, D. M., and Penland, S., 1987. Backbarrier dynamics of the East Friesian Island. Journal of Sedimentary Petrology, 57, 746754.Google Scholar
Fitzgerald, D. M., Penland, P., and Nummedal, D., 1984. Control of barrier island shape by inlet sediment bypassing: East Friesian Islands, West Germany. Marine Geology, 60, 355376.Google Scholar
FitzGerald, D. M., Rosen, P. S., and van Heteren, S., 1994. New England barriers. In Davis, R. A. (ed.), Geology of Holocene Barrier Island Systems. Berlin: Springer-Verlag, 305394.Google Scholar
Fleming, K., Johnston, P., Zwartz, D., et al., 1998. Refining the eustatic sea-level curve since the last glacial maximum using far- and intermediate-field sites. Earth and Planetary Science Letters, 163, 327342.Google Scholar
Franco, L., 1996. History of coastal engineering in Italy. In Kraus, N. C. (ed.), History and Heritage of Coastal Engineering. New York: ASCE Press, 275335.Google Scholar
Fredsoe, J., and Deigaard, R., 1992. Mechanics of Coastal Sediment Transport. Singapore: World Scientific, 369pp.Google Scholar
French, G. T., Awosika, L. F., and Ibe, C. E., 1994. Sea-level rise and Nigeria: Potential impacts and consequences. Journal of Coastal Research, SI14, 224242.Google Scholar
Frey, A., Connell, K., Hanson, H., et al., 2012. GenCade version 1 model theory and user’s guide. ERDC/CHL TR-12-25. US Army Engineer Research and Development Center, Vicksburg, MS.Google Scholar
Frey, R. W., and Howard, J. D., 1988. Beach and beach-related facies, Holocene barrier islands of Georgia. Geology, 125, 621640.Google Scholar
Fussel, H. M., 2007. Vulnerability: A generally applicable conceptual framework for climate change research. Global Environmental Change, 17(2), 155167.Google Scholar
Gallaher, A. A., 2009. The effects of beach nourishment on sea turtle nesting densities in Florida. PhD Dissertation, University of Florida, Gainesville, 153pp.Google Scholar
Galvin, C. J., 1968. Breaker type classifications of three laboratory beaches. Journal of Geophysical Research, 73, 36513659.Google Scholar
Galvin, C. J., 1982. Shoaling with bypassing for channels at tidal inlets. Proceedings of 18th Coastal Engineering Conference. New York: ASCE Press, 14861513.Google Scholar
Gao, J., Kennedy, D. M., and Konlechner, T. M., 2020. Coastal dune mobility over the past century: A global review. Progress in Physical Geography, 44, 814836.Google Scholar
Gibeaut, J. C., 1991. Morphodynamic classification, evolution, and modeling of unstructured inlets in west-central Florida. PhD Dissertation, Department of Marine Science, University of South Florida, Tampa, 192pp.Google Scholar
Gibeaut, J. C., and Davis, R. A., 1988. Morphodynamic classification of tidal inlets. Proceedings of Beach Preservation Technology ‘88, Gainesville, FL, Florida Shore and Beach Preservation Associate, 221229.Google Scholar
Gibeaut, J. C., and Davis, R. A., 1993. Statistical geomorphic classification of ebb-tidal deltas along the west-central Florida coast. Journal of Coastal Research, 18(SI), 165184.Google Scholar
Gladki, H., 1975. Discussion of determination of sand roughness for fixed beds. Journal of Hydraulic Research, 13. 221222.Google Scholar
Glaeser, J. D., 1978. Global distribution of barrier islands in terms of tectonic setting. The Journal of Geology, 86, 283297.Google Scholar
Goda, Y., 2000. Random Seas and Design of Maritime Structures. Singapore: World Scientific, 443pp.Google Scholar
Gravens, M. B., Ebersole, B. A., Walton, T. L., and Wise, R. A., 2006. Beach-fill design. EM 1110-2-1100 (Part V, Chapter 4). US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Guza, R. T., and Thornton, E. B., 1981. Wave set-up on a natural beach. Journal of Geophysical Research, 86(C5), 41334137.Google Scholar
Guza, R. T., and Thornton, E. B., 1982. Swash oscillations on a natural beach. Journal of Geophysical Research, 87(C1), 483490.Google Scholar
Hales, L. Z., and Herbich, J. B., 1972. Tidal inlet current–ocean wave interaction. Proceedings of 13th International Conference on Coastal Engineering. New York: ASCE Press, 679688.Google Scholar
Hallermeier, R. J., 1978. Uses for a calculated limit depth to beach erosion. Proceedings of 16th Conference on Coastal Engineering. New York: ASCE Press, 493512.Google Scholar
Hallermeier, R. J., 1981a. A profile zonation for seasonal sand beaches from wave climate. Coastal Engineering, 4, 253277.Google Scholar
Hallermeier, R. J., 1981b. Terminal settling velocity of commonly occurring sand grains. Sedimentology, 28, 859865.Google Scholar
Hallermeier, R. J., 1983. Sand transport limits in coastal structure design. Proceedings of Coastal Structures ‘83. New York: ASCE Press, 703716.Google Scholar
Halsey, S. D., 1979. Nexus: New model of barrier island development. In Leatherman, S. P. (ed.), Barrier Islands. New York: Academic Press, 185210.Google Scholar
Hamm, L., 1996. History of coastal engineering in France. In Kraus, N. C. (ed.), History and Heritage of Coastal Engineering. New York: ASCE Press, 142168.Google Scholar
Hands, E. B., 1979. Changes in rates of shore retreat, Lake Michigan, 1967–1976. Coastal Engineering Research Center, Technical Memorandum No. 79–4, 71pp.Google Scholar
Hands, E. B., 1980. Prediction of shore retreat and nearshore profile adjustments to rising water levels on the Great Lakes. Coastal Engineering Research Center, Technical Memorandum No. 80-7, 119pp.Google Scholar
Hands, E. B., 1983. The Great Lakes as a test model for profile response to sea level changes. In Komar, P. D. (ed.), Handbook of Coastal Processes and Erosion. Boca Raton, FL: CRC Press, 167189.Google Scholar
Hanson, H., 1987. GENESIS, a generalized shoreline change model for engineering use. Report No. 1007, Department of Water Resources Engineering, University of Lund, Sweden.Google Scholar
Hanson, H., and Kraus, N. C., 1989. GENESIS: Generalized model for simulating shoreline change. Technical Report CERC-89-19, Coastal Engineering Research Center, Vicksburg, MS. 247pp.Google Scholar
Hayes, M. O., 1979. Barrier island morphology as a function of tidal and wave regimes. In Leatherman, S. P. (ed.), Barrier Islands: From the Gulf of St. Lawrence to the Gulf of Mexico. New York: Academic Press, 127.Google Scholar
Hayes, M. O., 1980. General morphology and sediment patterns in tidal inlets. Sedimentary Geology, 26, 139156.Google Scholar
Hayes, M. O., 1994. The Georgia Bight Barrier systems. In Davis, R. A. (ed.), Geology of Holocene Barrier Island Systems. Berlin: Springer-Verlag, 233304.CrossRefGoogle Scholar
Hayes, M. O., Michel, J., and Holmes, J. M. (Illustrator), 2008. A Naturalist’s Guide to the Coast of South Carolina. South Carolina: Pandion Books, 288pp.Google Scholar
Hesp, P. A., 1988. Surf zone, beach and foredune interactions on the Australian southeast coast. Journal of Coastal Research, 3(SI), 1525.Google Scholar
Hesp, P. A., 1989. A review of biological and geomorphological processes involved in the initiation and development of incipient foredunes. Proceedings of the Royal Society of Edinburgh, Section B, 96, 181201.Google Scholar
Hesp, P. A., 2002. Foredunes and blowouts: Initiation, geomorphology and dynamics. Geomorphology, 48, 245268.Google Scholar
Hesp, P. A., 2011. Dune coasts. In Wolanski, E. and McLusky, D. S. (eds.), Treatise on Estuarine and Coastal Science, Vol 3. Waltham, MA: Academic Press, 193221.Google Scholar
Hesp, P. A., and Walker, I. J., 2013. Coastal dunes. In Lancaster, N., Sherman, D. J., and Baas, A. C. W. (eds.), Treatise on Geomorphology. New York: Academic Press, 328355.CrossRefGoogle Scholar
Hey, R. D., 1979. Flow resistance in gravel bed rivers. Journal of Hydraulic Division, ASCE, 105, 365379.Google Scholar
Hillyer, T. M., 1996. Shoreline protection and beach erosion control study, final report: An analysis of the US Army Corps of Engineers shore protection program. IWR Report 96-PS-1, Shoreline Protection and Beach Erosion Control Task Force, Water Resources Support Center, Institute for Water Resources, US Army Corps of Engineers, Alexandria, VA.Google Scholar
Hoefel, F., and Elgar, S., 2003. Wave-induced sediment transport and sandbar migration. Science, 299(5614), 18851887.Google Scholar
Holling, C. S., 1973. Resilience and stability of ecological systems. Annual Review of Ecology and Systematics, 4, 123.Google Scholar
Holman, R. A., 1986. Extreme value statistics for wave run-up on a natural beach. Coastal Engineering, 9, 527544.Google Scholar
Holman, R. A., and Sallenger, A. H., 1985. Setup and swash on a natural beach. Journal of Geophysical Research, 90(C1), 945953.Google Scholar
Horikawa, K., and Kuo, T. C., 1966. A study of wave transformation inside the surf zone. Proceedings of the 10th International Conference on Coastal Engineering. New York: ASCE Press, 217233.Google Scholar
Horwitz, M. H., 2017. Morphodynamics and sediment pathways of the John’s Pass–Blind Pass dual-inlet system: Pinellas County, Florida. PhD dissertation, University of South Florida, Tampa, 297 p.Google Scholar
Houser, C., and Hamilton, S., 2009. Sensitivity of post‐hurricane beach and dune recovery to event frequency. Earth Surface Processes and Landforms, 34, 613628.Google Scholar
Houser, C., Hapke, C., and Hamilton, S., 2008. Controls on coastal dune morphology, shoreline erosion and barrier island response to extreme storms. Geomorphology, 100, 223240.Google Scholar
Houston, J. R., 1995. Beach-fill volume required to produce specific dry beach width. Coastal Engineering Technical Note CETN II-32, US Army Corps of Engineers, Waterways Experiment Station, Vicksburg, MS.Google Scholar
Houston, J. R., 2008. The economic value of beaches: A 2008 update. Shore and Beach, 76(3), 2226.Google Scholar
Houston, J. R., 2013a. The value of Florida beaches. Shore and Beach, 81(4), 411.Google Scholar
Houston, J. R., 2013b. The economic value of beaches: A 2013 update. Shore and Beach, 86(2), 311.Google Scholar
Houston, J. R., 2018. The economic value of America’s beaches: A 2018 update. Shore and Beach, 81(1), 313.Google Scholar
Hoyt, J. H., 1967. Barrier island formation. Geological Society of America Bulletin, 78, 11251136.Google Scholar
Hsu, J. R. C., Silvester, R., and Xia, Y. M., 1989. Applications of headland control. Journal of Waterway, Port, Coastal and Ocean Engineering, ASCE, 115, 299310.Google Scholar
Hubbard, D. K., 1975. Morphology and hydrodynamics of the Merrimack River ebb-tidal delta. Proceedings of the 2nd International Estuarine Research Federation Conference, 253–266.Google Scholar
Hubbard, D. K., Barwis, J. H., and Nummedal, D., 1977. Sediment transport in four South Carolina inlets. Proceedings of Coastal Sediments ’77. New York: ASCE Press, 582601.Google Scholar
Hume, T. M., and Herdendorf, C. E., 1992. Factors controlling tidal inlet characteristics on low drift coasts. Journal of Coastal Research, 8, 355375.Google Scholar
Huntley, D. A., and Bowen, A. J., 1973. Field observations of edge waves. Nature, 243, 160161.Google Scholar
Huntley, D. A., and Bowen, A. J., 1975. Field observations of edge waves and their effect on beach material. Journal of Geological Society of London, 131, 6881.Google Scholar
Huntley, D. A., Guza, R. T., and Thornton, D. B., 1981. Field observations of surf beach, 1: Progressive edge waves. Journal of Geophysical Research, 83, 19131920.Google Scholar
Inman, D. L., 1991. Budget of sediment and prediction of the future state of the coast. State of the Coast Report, San Diego Region. Volume 1, Main Report, Chapter 9.Google Scholar
Inman, D. L., and Bagnold, R. A., 1963. Littoral processes. In Hill, M. N. (ed.), The Sea. New York: Wiley-Interscience, 529533.Google Scholar
Inman, D. L., Elwany, M. H. S., and Jekins, S. A., 1993. Shorerise and bar-berm profiles on ocean beaches. Journal of Geophysical Research, 98(C10), 1818118199.Google Scholar
Inman, D. L., and Nordstrom, C. E., 1971. On the tectonic and morphologic classification of coasts. The Journal of Geology, 79, 121.Google Scholar
IPCC, 2013. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change [Stocker, T. F., Qin, D., Plattner, G.-K., et al. (eds.)]. Cambridge: Cambridge University Press, 1535pp.Google Scholar
IPCC, 2014. Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part A: Global and Sectoral Aspects. Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change [Field, C. B., Barros, V. R., Dokken, D. J., et al. (eds.)]. Cambridge: Cambridge University Press, 1132pp.Google Scholar
Irish, J., Lynett, P. J., Weiss, R., Smallegan, S. M., and Cheng, W., 2013. Buried relic seawall mitigates hurricane Sandy’s impacts. Coastal Engineering, 80, 7982.Google Scholar
Jaffe, B. E., List, J. H., and Sallenger, A. H. Jr., 1997. Massive sediment bypassing on the lower shoreface offshore of a wide tidal inlet: Cat Island Pass, Louisiana. Marine Geology, 136, 131150.Google Scholar
Jarrett, B. D., Hine, A. C., Halley, R. B., et al., 2005. Strange bedfellows: A deep-water hermatypic coral reef superimposed on a drowned barrier island: Southern Pulley Ridge, SW Florida platform margin. Marine Geology, 214, 295307.Google Scholar
Jarrett, J. T., 1976. Tidal prism-inlet area relationships. GITI Report 3, U.S. Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Johnson, D. W., 1919. Shoreline Processes and Shoreline Development. New York: John Wiley, 584pp.Google Scholar
Jones, H. P., Nickel, B., Srebotnjak, T., et al., 2020. Global hotspots for coastal ecosystem-based adaptation. PLoS One, 15, e0233005.Google Scholar
Kaminsky, G., and Kraus, N. C., 1993. Evaluation of depth-limited wave breaking criteria. Waves ’93. New York: ASCE Press, 180193.Google Scholar
Kamphuis, J. W., 1974. Determination of sand roughness for fixed beds. Journal of Hydraulic Research, 12, 193203.Google Scholar
Kamphuis, J. W., 1991. Alongshore sediment transport rate. Journal of Waterways, Port, Coastal and Ocean Engineering, ASCE, 117(6), 624641.Google Scholar
Kamphuis, J. W., Davies, M. H., Nairn, R. B., and Sayaoo, J., 1986. Calculation of littoral sand transport rate. Coastal Engineering, 10, 121.Google Scholar
Kana, T. W., 2002. Barrier island formation via channel avulsion and shoal bypassing. Proceedings of International Conference on Coastal Engineering 2002. New York: ASCE Press, 34383448.Google Scholar
Kana, T. W., Hayter, E. J., and Work, P. A., 1999. Mesoscale sediment transport at Southeastern US tidal inlets: Conceptual model applicable to mixed energy settings. Journal of Coastal Research, 15, 303313.Google Scholar
Kana, T. W., and Stevens, F., 1992. Coastal geomorphology and sand budgets applied to beach nourishment. Proceedings, Coastal Engineering Practice ’92. New York: ASCE Press, 2944.Google Scholar
Keulegan, G. H., 1967. Tidal flow in entrances: Water-level fluctuations of basins in communications with seas. Technical Bulletin No. 14, Committee on Tidal Hydraulics, US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Kim, H., and Marcouiller, D. W., 2016. Natural disaster response, community resilience, and economic capacity: A case study of coastal Florida. Society & Natural Resources, 29, 981997.Google Scholar
King, C. A. M., 1972. Beaches and Coasts, 2nd ed. New York: St. Martin’s Press, 570pp.Google Scholar
Komar, P. D., 1979. Beach-slope dependence of longshore currents. Journal of Waterway, Ports, Coastal and Ocean Division, ASCE, 105, 460464.Google Scholar
Komar, P. D., 1998. Beach Processes and Sedimentation. New Jersey: Prentice Hall, 544pp.Google Scholar
Komar, P. D., and Gaughan, M. K., 1972. Airy wave theory and breaker height prediction. Proceedings of the 13th Coastal Engineering Conference. New York: ASCE Press, 405418.Google Scholar
Komar, P. D., and Inman, D. L., 1970. Longshore sand transport on beaches. Journal of Geophysical Research, 75(30), 55145527.Google Scholar
Komar, P. D., and McDougal, W. G., 1994. The analysis of exponential beach profiles. Journal of Coastal Research, 10, 5969.Google Scholar
Komar, P. D., and Miller, M. C., 1973. The threshold of sediment movement under oscillatory water waves. Journal of Sedimentary Petrology, 43, 11011110.Google Scholar
Komar, P. D., and Miller, M. C., 1975. On the comparison between the threshold of sediment motion under waves and unidirectional currents with a discussion of the practical evaluation of the threshold. Journal of Sedimentary Petrology, 45, 362367.Google Scholar
Kopp, R. E., Horton, R. M., Little, C. M., et al., 2014. Probabilistic 21st and 22nd century sea-level projections at a global network of tide gauge sites. Earth’s Future, 2, 383406.Google Scholar
Kraft, J. C., 1971. Sedimentary facies patterns and geologic history of a Holocene marine transgression. Geological Society of American Bulletin, 82, 21312158.Google Scholar
Kraus, N. C., 1989. Beach change modeling and the coastal planning process. Proceedings of Coastal Zone ’89. New York: ASCE Press, 553567.Google Scholar
Kraus, N. C., 2000. Reservoir model of ebb-tidal shoal evolution and sand bypassing. Journal of Waterway, Port, Coastal, and Ocean Engineering, ASCE, 126, 305313.Google Scholar
Kraus, N. C., 2002. Reservoir model for calculating natural sand bypassing and change in volume of ebb-tidal shoals, Part 1: Description. ERFC/CHL CHETN-IV-39, US Army Engineer Research and Development Center, Vicksburg, MS.Google Scholar
Kraus, N. C., 2018. Engineering of tidal inlets and morphologic consequences. In Kim, Y. C. (ed.), Handbook of Coastal and Ocean Engineering. Singapore: World Scientific, 12671300.Google Scholar
Kraus, N. C., and Galgano, F. A., 2001. Beach erosional hot spots: Types, causes, and solutions. ERDC/CHL CHETN-II-44, US Army Corps of Engineers, Vicksburg, MS, 18pp.Google Scholar
Kraus, N. C., and Larson, M., 2001. Mathematical model for rapid estimation of coastal inlet entrance channel infilling. Coastal Engineering Technical Note CETN-IV-35. US Army Engineer Research and Development Center, Vicksburg, MS, 13pp.Google Scholar
Kraus, N. C., Larson, M., and Wise, R. A., 1999. Depth of closure in beach fill design. Proceedings of 1999 National Conference on Beach Preservation Technology, FSBPA, Tallahassee, FL.Google Scholar
Kraus, N. C., and McDougal, W. G., 1996. The effects of seawalls on the beach: Part I, an updated literature review. Journal of Coastal Research, 12, 691701.Google Scholar
Kraus, N. C., and Rosati, J. D., 1998. Estimation of uncertainty in coastal-sediment budgets at inlets. Coastal Engineering Technical Note CETN IV-16, US Army Engineer Research and Development Center, Coastal and Hydraulics Laboratory, Vicksburg, MS, 12pp.Google Scholar
Kraus, N. C., Abbott, C. E., Arden, H. T., et al., 2000. Study of navigation channel feasibility, Willapa Bay, Washington. ERDC/CHL TR-00-6, US Army Engineer Research and Development Center, Vicksburg, MS, 426pp.Google Scholar
Kulp, M. A., Penland, S., Williams, S. J., et al., 2005. Geological framework, evolution, and sediment resources for restoration of the Louisiana coastal zone. Journal of Coastal Research, 44, 5671.Google Scholar
Lambeck, K., and Chappell, J., 2001. Sea level change through the last glacial cycle. Science, 292, 679686.Google Scholar
Larson, M., 1988. Quantification of beach profile change. Report No. 1008, Department of Water Resources Engineering, Lund University, Lund, Sweden.Google Scholar
Larson, M., 1991. Equilibrium profile of a beach with varying grain size. Proceedings of Coastal Sediments ’91. New York: ASCE Press, 861874.Google Scholar
Larson, M., Camenen, B., and Nam, P. T., 2011. A unified sediment transport model for inlet application. Journal of Coastal Research, 59(SI), 2739.Google Scholar
Larson, M., and Kraus, N. C., 1989. SBEACH: Numerical model for simulating storm-induced beach change, Report 1: Empirical foundation and model development. Technical Report CERC-89-9, Coastal Engineering Research Center, US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Larson, M., and Kraus, N. C., 1994. Temporal and spatial scales of beach profile change, Duck, North Carolina. Marine Geology, 117, 7594.Google Scholar
Larson, M., and Kraus, N. C., 1998. SBEACH: Numerical model for simulating storm-induced beach change, Report 5: Representation of nonerodible (hard) bottoms. Technical Report CHL-98-9, Coastal Engineering Research Center, US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Larson, M., and Kraus, N. C., 2001. Estimation of suspended sediment trapping ratio for channel infilling and bypassing. ERDC/CHL CHETN-IV-34, US Army Engineer Research and Development Center, Vicksburg, MS, 9pp.Google Scholar
Larson, M., Kraus, N. C., and Byrnes, M. R., 1990. SBEACH: Numerical model for simulating storm-induced beach change, Report 2: Numerical formulation and model tests. Technical Report CERC-89-9, Coastal Engineering Research Center, US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Law, M. N., and Davidson-Arnott, R. G. D., 1990. Seasonal controls on aeolian processes on the beach and foredune. In Davidson-Arnott, R. G. D. (ed.), Proceedings of the Symposium on Coastal Sand Dunes. Ottawa, Canada: National Research Council of Canada, 4968.Google Scholar
Leatherman, S. P., Zhang, K., and Douglas, B. C., 2000. Sea level rise shown to drive coastal erosion. Eos, Transactions of the American Geophysical Union, 81(6), 5557.Google Scholar
Lemke, L., and Miller, J. K., 2020. Evaluation of storms through the lens of erosion potential along the New Jersey, USA coast. Coastal Engineering, 158, 103699.Google Scholar
Lesser, G. R., Roelvink, J. A., van Kester, J. A. T. M., and Stelling, G. S., 2004. Development and validation of a three-dimensional morphological model. Coastal Engineering, 51, 883915.Google Scholar
Li, H., Beck, T. M., Moritz, H. R., et al., 2018. Sediment tracer tracking and numerical modeling at Coos Bay Inlet, Oregon. Journal of Coastal Research, 35, 425.Google Scholar
Lin, L., Demirbilek, Z., and Mase, H., 2011. Recent capabilities of CMS-wave: A coastal wave model for inlets and navigation projects. Journal of Coastal Research, 59(SI), 715.Google Scholar
Liu, Z., Bernéb, S., Saito, Y., et al., 2007. Internal architecture and mobility of tidal sand ridges in the East China Sea. Continental Shelf Research, 27, 18201834.Google Scholar
Loeb, W. A., 1994. Beaches of Pinellas County, Florida: A history of their comings and goings (circa 1950–present). USGS Open File Report 94-565. US Geological Survey.Google Scholar
Longuet-Higgins, M. S., 1970. Longshore currents generated by obliquely incident waves, 1 and 2. Journal of Geophysical Research, 75, 67786810.Google Scholar
Longuet-Higgins, M. S., and Stewart, R. W., 1963. Radiation stress in water waves: A physical discussion with applications. Deep Sea Research, 11, 529563.Google Scholar
Lorenzo-Trueba, J., and Ashton, A. D., 2014. Rollover, drowning, and discontinuous retreat: Distinct modes of barrier response to sea-level rise arising from a simple morphodynamic model. Journal of Geophysical Research: Earth Surface, 119, 779801.Google Scholar
Luijendijk, A. P., Ranasinghe, R., de Schipper, M. A., et al., 2017. The initial morphological response of the Sand Engine: A process-based modelling study. Coastal Engineering, 119, 114.Google Scholar
Magliocca, N. R., Mcnamara, D. E., and Murray, A. B., 2011. Long-term, large-scale morphodynamic effects of artificial dune construction along a barrier island coastline. Journal of Coastal Research, 27, 918930.Google Scholar
Masselink, G., and Puleo, J. A., 2006. Swash-zone morphodynamics. Continental Shelf Research, 26, 661680.Google Scholar
McBride, R. A., Anderson, J. B., Wallace, D., et al., 2021. Morphodynamics of barrier systems: A synthesis. In Shroder, J. (ed. in Chief), Sherman, D. (ed.), Treatise on Geomorphology, vol. 10, Coastal and Submarine Geomorphology, 2nd ed. San Diego, CA: Academic Press, 166244.Google Scholar
McBride, R. A., and Byrnes, M., 1997. Regional variations in shore response along barrier island systems of the Mississippi River delta plain: Historical change and future prediction. Journal of Coastal Research, 13, 628655.Google Scholar
McCowan, J., 1894. On the highest wave of permanent type. Philosophical Magazine, Edinburgh, 32, 351358.Google Scholar
Mellett, C. L., and Plater, A. J., 2018. Drowned barriers as archives of coastal response to sea-level rise. In Moore, L. J., and Murray, A. B. (eds.), Barrier Dynamics and Response to Changing Climate. Cham: Springer, 5789.Google Scholar
Meyer-Peter, E., and Mueller, R., 1948. Formulas for bed-load transport. Proceedings of the International Association for Hydraulic Research, 2nd Congress, Stockholm, Sweden, 39–64.Google Scholar
Midun, Z., and Lee, S. C., 1994. Implications of a greenhouse-induced sea-level rise: A national assessment for Malaysia. Journal of Coastal Research, SI14, 96115.Google Scholar
Miller, K. G., Kopp, R. E., Horton, B. P., Browning, J. V., and Kemp, A. C., 2013. A geological perspective on sea-level rise and its impacts along the U.S. mid-Atlantic coast. Earth’s Future, 1, 3.Google Scholar
Miner, M. D., Kulp, M. A., FitzGerald, D. M., and Georgiou, I. Y., 2009. Hurricane-associated ebb-tidal delta sediment dynamics. Geology, 37, 851854.Google Scholar
Moftakhari, H. R., AghaKouchak, A., Sanders, B. F., Allaire, M., and Matthew, R. A., 2018. What is nuisance flooding? Defining and monitoring an emerging challenge. Water Resources Research, 54, 42184227.Google Scholar
Moore, B. D., 1982. Beach profile evolution in response to changes in water level and wave height. MCE Thesis, Department of Civil Engineering, University of Delaware, 164pp.Google Scholar
Moore, L. J., List, J. H., Williams, S. J., and Stolper, D., 2010. Complexities in barrier island response to sea level rise: Insights from numerical model experiments, North Carolina Outer Banks. Journal of Geophysical Research, 115, F03004.Google Scholar
Moore, L. J., and Murray, A. B., 2018. Barrier Dynamics and Response to Changing Climate. Cham: Springer, 395pp.Google Scholar
Morang, A., 1992. Inlet migration and hydraulic processes at East Pass, Florida. Journal of Coastal Research, 8, 457481.Google Scholar
Morang, A., and Parson, L. E., 2006. Coastal terminology and geologic environments. EM 1110-2-1100 (Part IV, Chapter 1). US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Morton, R. A., 1994. Texas barriers. In Davis, R. A. (ed.), Geology of Holocene Barrier Island Systems. Berlin: Springer-Verlag, 75114.Google Scholar
Morton, R. A., 2003. Morphological impacts of extreme storms on sandy beaches and barriers. Journal of Coastal Research, 19, 560573.Google Scholar
Morton, R. A., Bernier, J. C., and Barras, J. A., 2006. Evidence of regional subsidence and associated interior wetland loss induced by hydrocarbon production, Gulf Coast region, USA. Environmental Geology, 50, 261274.Google Scholar
Morton, R. A., and Donaldson, A. C., 1973. Sediment distribution and evolution of tidal deltas along a tide dominated shoreline, Wachapreague, VA. Sedimentary Geology, 10, 285299.Google Scholar
Moslow, T. F., and Heron, S. D., 1994. The outer banks of North Carolina. In Davis, R. A. (ed.), Geology of Holocene Barrier Island Systems. Berlin: Springer-Verlag, 4774.Google Scholar
Moutzouris, C. I., 1991. Beach profile vs. cross-shore distribution of sediment grain size. Proceedings of Coastal Sediments ’91. New York: ASCE Press, 419431.Google Scholar
Murray, A. B., and Moore, L. J., 2018. Geometric constraints on long-term barrier migration: From simple to surprising. In Moore, L. J. and Murray, A. B., (eds.), Barrier Dynamics and Response to Changing Climate. Cham: Springer, 211241.Google Scholar
Murray-Wallace, C. V., and Woodroffe, C. D., 2014. Quaternary Sea-Level Changes: A Global Perspective. Cambridge: Cambridge University Press, 504pp.Google Scholar
Narayan, S., Beck, M. W., Reguero, B. G., et al., 2016. The effectiveness, costs and coastal protection benefits of natural and nature-based defences. PLoS One, 11, e0154735.Google Scholar
Nel, J. L., Le Maitre, D. C., Nel, D. C., et al., 2014. Natural hazards in a changing world: A case for ecosystem-based management. PLoS One, 9, e95942.Google Scholar
Neumann, B., Vafeidis, A. T., Zimmermann, J., and Nicholls, R. J., 2015. Future coastal population growth and exposure to sea-level rise and coastal flooding: A global assessment. PLoS One, 10(3), e0131375.Google Scholar
Nicholls, R. J., Birkemeier, W. A., and Hallermeier, R. J., 1996. Application of depth of closure concept. Proceedings of the 25th Conference on Coastal Engineering. New York: ASCE Press, 38743887.Google Scholar
Nicholls, R. J., and Leatherman, S. P. (eds.), 1994. Potential impacts of accelerated sea-level rise on developing countries. Journal of Coastal Research, 14(SI), 324pp.Google Scholar
Nickling, W. G., and Davidson-Arnott, R. G. D., 1990. Aeolian sediment transport on beaches and coastal sand dunes. In Davidson-Arnott, R. G. D. (ed.), Proceedings of the Symposium on Coastal Sand Dunes. Ottawa, Canada: National Research Council of Canada, 135.Google Scholar
Niederoda, A. W., Swift, D. J. P., Figueiredo, A. G., and Freeland, G. L., 1985. Barrier island evolution, Middle Atlantic Shelf, USA, part II: Evidence from the shelf floor. Marine Geology, 63, 363396.Google Scholar
Nielsen, P., 1984a. On the motion of suspended sediment particles. Journal of Geophysical Research, 89(C1), 616626.Google Scholar
Nielsen, P., 1984b. Field measurements of suspended sediment concentrations under waves. Coastal Engineering, 8, 5173.Google Scholar
Nielsen, P., 1986. Suspended sediment concentrations under waves. Coastal Engineering, 10, 2331.Google Scholar
Nielsen, P., 1992. Coastal Bottom Boundary Layers and Sediment Transport. Singapore: World Scientific, 324pp.Google Scholar
Niemeyer, H. D., Eiben, H., and Rohde, H., 1996. History of coastal engineering in Germany. In Kraus, N. C. (ed.), History and Heritage of Coastal Engineering. New York: ASCE Press, 169213.Google Scholar
Nienhuis, J. H., and Ashton, A. D., 2016. Mechanics and rates of tidal inlet migration: Modeling and application to natural examples. Journal of Geophysical Research: Earth Surface, 121, 21182139.Google Scholar
NOAA, 2013. National Coastal Population Report: Population Trends from 1970 to 2020. Available at: aamboceanservice.blob.core.windows.net/oceanservice-prod/facts/coastal-population-report.pdf.Google Scholar
Nordstrom, K. F., 1994. Beaches and dunes of human-altered coasts. Progress in Physical Geography, 18, 497516.Google Scholar
Nordstrom, K. F., 2019. Coastal dunes with resistant cores. Journal of Coastal Conservation, 23, 227237.Google Scholar
Nordstrom, K. F., and Jackson, N. L., 2018. Constraints on restoring landforms and habitats on storm-damaged shorefront lots in New Jersey, USA. Ocean and Coastal Management, 155, 1523.Google Scholar
NRC (National Research Council), 1995. Beach Nourishment and Protection. Washington, DC: National Academy Press, 334pp.Google Scholar
NRC (National Research Council), 2005. Valuing Ecosystem Services: Toward Better Environmental Decision Making. Washington, DC: The National Academies Press.Google Scholar
NRC (National Research Council), 2012. Disaster Resilience: A National Imperative. Washington, DC: The National Academies Press.Google Scholar
O’Brien, M. P., 1931. Estuary tidal prisms related to entrance areas. Civil Engineering, 1, 738739.Google Scholar
O’Brien, M. P., 1969. Equilibrium flow areas of inlets on sandy coasts. Journal of the Waterways and Harbors Division, ASCE, 95, 4352.Google Scholar
Oertel, G. F., 1972. Sediment transport of estuary entrance shoals and the formation of swash platforms. Journal of Sedimentary Petrology, 42, 857863.Google Scholar
Oertel, G. F., and Kraft, J. C., 1994. New Jersey and Delmarva barrier islands. In Davis, R. A. (ed.), Geology of Holocene Barrier Island Systems. Berlin: Springer-Verlag, 207232.Google Scholar
Ogden, J. G., III, 1974. Shoreline change along the southeastern coast of Martha’s Vineyard, Massachusetts, for the past 200 years. Quaternary Research, 4, 496508.Google Scholar
Okazaki, S., and Sunamura, T., 1991. Re-examination of breaker-type classification on uniformly inclined laboratory beaches. Journal of Coastal Research, 7, 559564.Google Scholar
Otvos, E. G., 2018. Coastal barriers, northern Gulf: Last eustatic cycle; genetic categories and development contrasts. A review. Quaternary Science Reviews, 193, 212243.Google Scholar
Passeri, D. L., Bilskie, M. V., Hagen, S. C., et al., 2021. Assessing the effectiveness of nourishment in decadal barrier island morphological resilience. Water, 13, 944.Google Scholar
Pelnard-Considere, R., 1956. Essai de Theorie de l’Evolution des Forms de Rivage en Plage de Sable et de Galets. 4th Journees de l’Hydraulique, Les Energies de la Mer, Question III, Rapport No.1, 289–298 (in French).Google Scholar
Penland, S., and Ramsey, K. E., 1990. Relative sea-level rise in Louisiana and the Gulf of Mexico: 1908–1988. Journal of Coastal Research, 6, 323342.Google Scholar
Penland, S., Suter, J. R., and Boyd, R., 1988. The transgressive depositional systems of the Mississippi River delta plain: A model for barrier shoreline and shelf sand development. Journal of Sedimentary Petrology, 58, 932949.Google Scholar
Penland, S., Suter, J. R., McBride, R. A., et al., 1989. Holocene sand shoals offshore of the Mississippi River delta plain. Transactions – Gulf Coast Association of Geological Societies, 39, 471480.Google Scholar
Pfeffer, W. T., Harper, J. T., and O’Neel, S., 2008. Kinematic constraints on glacier contributions to 21st-century sea-level rise. Science, 321, 13401343.Google Scholar
PIANC, 2011. PIANC Position Paper: Working with Nature. Available at: www.pianc.org/downloads/envicom/WwN%20Final%20position%20paper%20January%202011.pdf.Google Scholar
Pilkey, O. H., and Clayton, T. D., 1989. Summary of beach replenishment experience on U.S. east coast barrier islands. Journal of Coastal Research, 5, 147159.Google Scholar
Pilkey, O. H., and Fraser, M. E., 2003. A Celebration of the World’s Barrier Islands. New York: Columbia University Press, 309pp.Google Scholar
Plant, N. G., Freilich, M. H., and Holman, R. A., 2001. Role of morphologic feedback in surf zone sandbar response. Journal of Geophysical. Research, 106(C1), 973989.Google Scholar
Plant, N. G., and Stockdon, H. F., 2012. Probabilistic prediction of barrier-island response to hurricanes. Journal of Geophysical Research, 117, F03015.Google Scholar
Plumlee, G. S., Benzel, W. M., Hoefen, T. M., et al., 2016. Environmental implications of the use of sulfidic back-bay sediments for dune reconstruction: Lessons learned from post hurricane Sandy. Marine Pollution Bulletin, 107, 459471.Google Scholar
Polyak, V. J., Onac, B. P., Fornós, J. J., et al., 2018. A highly resolved record of relative sea level in the western Mediterranean Sea during the last interglacial period. Nature Geoscience, 11, 860864.Google Scholar
Pope, J., 2000. Where and why channels shoal: A conceptual geomorphic framework. ERDC/CHL CHETN-IV-12, US Army Engineer Research and Development Center, Vicksburg, MS.Google Scholar
Powell, M. A., Thieke, R. J., and Mehta, A. J., 2006. Morphodynamic relationships for ebb and flood delta volume at Florida’s tidal entrances. Ocean Dynamics, 56, 295307.Google Scholar
Psuty, N. P., 1988. Sediment budget and dune/beach interaction. Journal of Coastal Research, 3, 14.Google Scholar
Puleo, J. A., Beach, R. A., Holman, R. A., and Allen, J. S., 2000. Swash zone sediment suspension and transport and the importance of bore-generated turbulence. Journal of Geophysical Research, 105(C7), 1702117044.Google Scholar
Puleo, J. A., Holland, K. T., Plant, N., Slinn, D. N., and Hanes, D. M., 2003. Fluid acceleration effects on suspended sediment transport in the swash zone. Journal of Geophysical Research, 108, 3350.Google Scholar
Puleo, J. A., Lanckriet, T. M., and Wang, P., 2012. Near bed cross-shore velocity profiles, bed shear stress and friction on the foreshore of a microtidal beach. Coastal Engineering, 68, 616.Google Scholar
Reed, C. W., Brown, M. E., Sanchez, A., Wu, W., and Buttolph, A. M., 2011. The Coastal Modeling System Flow Model (CMS-Flow): Past and present. Journal of Coastal Research, 59(SI), 17.Google Scholar
Reguero, B. G., Beck, M. W., Bresch, D. N., Calil, J., and Meliane, I., 2018. Comparing the cost effectiveness of nature-based and coastal adaptation: A case study from the Gulf Coast of the United States. PLoS One, 13, e0192132.Google Scholar
Roberts, H. H., 1997. Dynamic changes of the Holocene Mississippi river delta plain: The delta cycle. Journal of Coastal Research, 13, 605627.Google Scholar
Roberts, T. M., and Wang, P., 2012. Four-year performance and associated controlling factors of several beach nourishment projects along three adjacent barrier islands, West-Central Florida, USA. Coastal Engineering, 70, 2139.Google Scholar
Roberts, T. M., Wang, P., and Kraus, N. C., 2010. Limits of beach and dune erosion in response to wave runup from large-scale laboratory data. Journal of Coastal Research, 26, 184198.Google Scholar
Roberts, T. M., Wang, P., and Puleo, J. A., 2013. Storm-driven cyclic beach morphodynamics of a mixed sand and gravel beach along the mid-Atlantic coast, USA. Marine Geology, 346, 403421.Google Scholar
Roelvink, D., and Reniers, A., 2012. A Guide to Modeling Coastal Morphology. Singapore: World Scientific, 274pp.Google Scholar
Roelvink, D., Reniers, A., van Dongeren, A., et al., 2009. Modelling storm impacts on beaches, dunes and barrier islands. Coastal Engineering, 56, 11331152.Google Scholar
Rosati, J. D., 1990. Functional design of breakwaters for shore protection: Empirical methods. Technical Report, CERC-90-15, US Army Engineer Waterways Experiment Station, Vicksburg, MS, 48pp.Google Scholar
Rosati, J. D., 2005a. Coastal inlet navigation channel shoaling with deepening and widening. ERDC/CHL CHETN-IV-64, 12pp.Google Scholar
Rosati, J. D., 2005b. Concepts in sediment budgets. Journal of Coastal Research, 21, 307322.Google Scholar
Rosati, J. D., 2009. Barrier island migration over a consolidating substrate. PhD Dissertation, Louisiana State University, Baton Rouge, 206pp.Google Scholar
Rosati, J. D., Dabees, M., and Tanner, W., 2011. Inlet reservoir model, Part II: PC-interface. Coastal and Hydraulics Engineering Technical Note ERDC/CHL CIRP-WN-12-1. US Army Engineer Research and Development Center, Vicksburg, MS.Google Scholar
Rosati, J. D., Dean, R. G., and Stone, G. W., 2010. A cross-shore model of barrier island migration over a compressible substrate. Marine Geology, 271, 116.Google Scholar
Rosati, J. D., Dean, R. G., and Walton, T. L., 2013. The modified Bruun Rule extended for landward transport. Marine Geology, 340, 7181.Google Scholar
Rosati, J. D., and Kraus, N. C., 1999a. Formulation of sediment budgets at inlets. Coastal Engineering Technical Note IV-15, 20pp.Google Scholar
Rosati, J. D., and Kraus, N. C., 1999b. Sediment Budget Analysis System (SBAS). Coastal Engineering Technical Note IV-20, 14pp.Google Scholar
Rosati, J. D., and Kraus, N. C., 2003. Sediment Budget Analysis System (SBAS): Upgrade for regional applications. ERDC/CHL CHETN-XIV-3, 13pp.Google Scholar
Rosati, J. D., and Stone, G. W., 2009. Geomorphic evolution of barrier islands along the northern U.S. Gulf of Mexico and implications for engineering design in barrier island restoration. Journal of Coastal Research, 25, 822.Google Scholar
Rosati, J. D., Walton, T. L., and Bodge, K., 2002. Longshore sediment transport. EM 1110-2-1100 (Part III, Chapter 2). US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Rovere, A., Raymo, M. E., Vacchi, M., et al., 2016. The analysis of last interglacial (MIS 5e) relative sea-level indicators: Reconstructing sea-level in a warmer world. Earth-Science Reviews, 159, 404427.Google Scholar
Ruessink, B. G., Van Enckevort, I. M. M., Kingston, K. S., and Davidson, M. A., 2000. Analysis of observed two- and three-dimensional nearshore bar behavior. Marine Geology, 169, 161183.Google Scholar
Ruggiero, P., Hacker, S., Seabloom, E., and Zarnetske, P., 2018. The role of vegetation in determining dune morphology, exposure to sea-level rise, and storm-induced coastal hazards: A U.S. Pacific Northwest perspective. In Moore, L. J. and Murray, A. B. (eds.), Barrier Dynamics and Response to Changing Climate. Cham: Springer, 337361.Google Scholar
Ruggiero, P., Komar, P. D., McDougal, W. G., Marra, J. J., and Beach, R. A., 2001. Wave runup, extreme water levels and the erosion of properties backing beaches. Journal of Coastal Research, 17, 407419.Google Scholar
Russell, P. E., 1993. Mechanism for beach erosion during storms. Continental Shelf Research, 13, 12431265.Google Scholar
Saffir, H. S., 1977. Design and construction requirements for hurricane resistant construction. American Society of Civil Engineers, Preprint Number 2830, 20pp.Google Scholar
Sallenger, A. H., 2000. Storm impact scale for barrier islands. Journal of Coastal Research, 16, 890895.Google Scholar
Sanchez, A., and Wu, W., 2011. A non-equilibrium sediment transport model for coastal inlets and navigation channels. Journal of Coastal Research, 59(SI), 3949.Google Scholar
Sanchez, A., Wu, W., Li, H., et al., 2014. Coastal Modeling System: Mathematical Formulations and Numerical Methods. Vicksburg, MS: US Army Engineer Research and Development Center, Coastal and Hydraulics Laboratory.Google Scholar
Sandoval, E., 2015. Morphodynamics of Mullet Key, West-Central Florida. MS Thesis, University of South Florida, Tampa, 110pp.Google Scholar
Scheffner, N. W., 2006. Water levels and long waves. EM 1110-2-1100 (Part II, Chapter 5). US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Schoonees, J. S., and Theron, A. K., 1993. Review of the field-data base for longshore sediment transport. Coastal Engineering, 19, 125.Google Scholar
Schoonees, J. S., and Theron, A. K., 1996. Improvement of the most accurate longshore transport formula. Proceedings of the 25th International Conference on Coastal Engineering. New York: ASCE Press, 36523665.Google Scholar
Schrader, M. H., Douglass, E. C., and Lillycrop, L. S., 2016. Regional sediment management strategies for the vicinity of St. Augustine Inlet, St. Johns County, Florida. ERDC/CHL Technical Report TR-16-12. US Army Engineer Research and Development Center, Coastal and Hydraulics Laboratory, Vicksburg, MS.Google Scholar
Schwartz, M. L., 1965. Laboratory study of sea-level as a cause offshore erosion. Journal of Geology, 73, 528534.Google Scholar
Schwartz, M. L., 1967. The Bruun theory of sea-level rise as a cause of shore erosion. Journal of Geology, 75, 7692.Google Scholar
SCOR (Working Group 89), 1991. The response of beaches to sea level changes: A review of predictive models. Journal of Coastal Research, 7, 895921.Google Scholar
Scott, T. M., 1992. A Geological Overview of Florida. Florida Geological Survey, Tallahassee, 80pp.Google Scholar
Seabergh, W. C., 1983. Weir jetty performance: Hydraulic and sedimentary considerations. Technical Report HL-83-5, US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Seabergh, W. C., 2006. Hydrodynamics of tidal inlets. EM 1110-2-1100 (Part II, Chapter 6). US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Sempier, T. T., Swann, D. L., Emmer, R., Sempier, S. H., and Schneider, M., 2010. Coastal community resilience index: A community self-assessment. MASGP-08-014.Google Scholar
Sexton, W. J., and Hayes, M. O., 1982. Natural bar-bypassing of sand at a tidal inlet. Proceedings of the 18th Coastal Engineering Conference. New York: ASCE Press, 14791495.Google Scholar
Sherman, D. J., Namikas, S. L., Jackson, D. W. T., and Wang, S. L., 1998. Wind blown sand on beaches: An evaluation of models. Physical Geography, 15, 381395.Google Scholar
Shields, A., 1936. Anwendung der Aehnlichkeitsmechanik und der Turbulenzforschung auf die Geschiebebewegung [Application of similarity mechanics and turbulence research on shear flow]. Berlin: Preußische Versuchsanstalt für Wasserbau (in German).Google Scholar
Short, A. D., and Hesp, P. A., 1982. Wave, beach and dune interactions in southeast Australia. Marine Geology, 48, 259284.Google Scholar
Silvester, R., and Hsu, J. R. C., 1997. Coastal Stabilization. Singapore: World Scientific, 578pp.Google Scholar
Simpson, R. H., 1971. A proposed scale for ranking hurricanes by intensity. Minutes of the Eighth NOAA, NWS Hurricane Conference, Miami, FL.Google Scholar
Sloss, C. R., Shepherd, M., and Hesp, P. A., 2012. Coastal dunes: Geomorphology. Nature Education Knowledge, 3(10), 2.Google Scholar
Smith, E. R., and Kraus, N. C., 1991. Laboratory study of breaking waves on bars and artificial reefs. Journal of Waterway, Port, Coastal and Ocean Engineering, ASCE, 117, 307325.Google Scholar
Smith, E. R., Wang, P., Ebersole, B. A., and Zhang, J., 2009. Dependence of total longshore sediment transport rates on incident wave parameters and breaker type. Journal of Coastal Research, 25, 675683.Google Scholar
Smith, J. M., and Kraus, N. C., 1995. SUPERTANK laboratory data collection project, Volume II: Appendices A-I. Technical Report CERC-94–3, US Army Engineer Waterways Experiment Station, Coastal Engineering Research Center, Vicksburg, MI.Google Scholar
Sorensen, T., Fredsoe, J., and Jakobsen, P. R., 1996. History of coastal engineering in Denmark. In Kraus, N. C. (ed.), History and Heritage of Coastal Engineering. New York: ASCE Press, 103141.Google Scholar
Soulsby, R., 1997. Dynamics of Marine Sands. London: Thomas Telford, 272pp.Google Scholar
Soulsby, R., and Whitehouse, R. J. S. W., 1997. Threshold of sediment motion in coastal environments. Proceedings of Pacific Coasts and Ports ’97, 149–154.Google Scholar
SPM (Shore Protection Manual), 1984. US Army Corps of Engineers, Coastal Engineering Research Center, US Government Printing Office, Washington, DC.Google Scholar
Sriver, R. L., Urban, N. M., Olson, R., and Keller, K., 2012. Toward a physically plausible upper bound of sea-level rise projections. Climatic Change, 115, 893902.Google Scholar
Stauble, D. K., 1993. An overview of southeast Florida inlet morphodynamics. Journal of Coastal Research, 18(SI), 127.Google Scholar
Stockdon, H. F., Holman, R. A., Howd, P. A., and Sallenger, A. H., 2006. Empirical parameterization of setup, swash, and runup. Coastal Engineering, 53, 573588.Google Scholar
Streif, H., 1988. Barrier islands, tidal flats, and coastal marshes resulting from a relative rise of sea level in East Frisia on the German North Sea coast. In Coastal Lowlands, Geology and Geotechnology. Dordrecht: Kluwer, 213233.Google Scholar
Stutz, M. L., and Pilkey, O. H., 2001. A review of global barrier island distribution. Journal of Coastal Research, 34(SI), 1522.Google Scholar
Svendsen, I. A., 1984. Mass flux and undertow in a surf zone. Coastal Engineering, 8, 347365.Google Scholar
Sweet, W. V., Horton, R., Kopp, R. E., LeGrande, A. N., and Romanou, A., 2017. Sea level rise. In Wuebbles, D. J., Fahey, D. W., Hibbard, K. A., et al. (eds.), Climate Science Special Report: Fourth National Climate Assessment, Vol. I. Washington, DC: US Global Change Research Program, 333363.Google Scholar
Tanner, W. F., 1960. Florida coastal classifications. Transactions of Gulf Coast Association of Geological Society, 10, 259266.Google Scholar
Temmerman, S., Meire, P., Bouma, T. J., et al., 2013. Ecosystem-based coastal defense in the face of global change. Nature, 504, 7983.Google Scholar
Thieler, E. R., Pilkey, O. H., Young, R. S., Bush, D. M., and Chai, F., 2000. The use of mathematical models to predict beach behavior for US coastal engineering: A critical review. Journal of Coastal Research, 16, 4870.Google Scholar
Thom, B. G., 1984. Sand barriers of east Australia: Gippsland – A case study. In Thom, B. G. (ed.), Coastal Geomorphology in Australia. New York: Academic Press, 233261.Google Scholar
Thornton, E. B., Humiston, R. T., and Birkemeier, W. A., 1996. Bar/trough generation on a natural beach. Journal Geophysical. Research, 101(C5), 1209712110.Google Scholar
Timmerman, P., 1981. Vulnerability, Resilience and the Collapse of Society: A Review of Models and Possible Climatic Applications. Environmental Monograph No. 1. Institute for Environmental Studies, University of Toronto, 46pp.Google Scholar
Torres, M. J., Nadal-Caraballo, N. C., Ramos-Santiago, E., et al., 2020. StormSim-CHRPS: Coastal Hazards Rapid Prediction System. Journal of Coastal Research, 95(SI), 13201325.Google Scholar
Trawle, M. J., 1981. Effects of depth on dredging frequency, Report 2: Methods of estuarine shoaling analysis. Technical Report H-78-5, US Army Engineer Waterways Experiment Station, Vicksburg, MS, 65pp.Google Scholar
Trindell, R., Arnold, D., Moody, K., and Morford, B., 1998. Post-construction marine turtle nesting monitoring on nourished beaches. Proceedings of the 11th Beach Preservation Technology Conference, Florida Shore and Beach Preservation Association, Tallahassee, FL, 77–92.Google Scholar
Ursell, F., 1952. Edge waves on a sloping beach. Proceedings of the Royal Society of London. Series A, 214, 7998.Google Scholar
USACE (US Army Corps of Engineers), 2006. The Atlantic Coast of New Jersey Regional Sediment Budget 1986–2003 Manasquan Inlet to Sea Bright. US Army Engineer District, New York, NY, Draft Report, April, 2006.Google Scholar
USGCRP, 2017. Climate Science Special Report: Fourth National Climate Assessment, Volume I. Edited by Wuebbles, D. J., Fahey, D. W., Hibbard, K. A., et al. Washington, DC: US Global Change Research Program, 470pp.Google Scholar
USGCRP, 2018. Impacts, Risks, and Adaptation in the United States: Fourth National Climate Assessment, Volume II. Edited by Reidmiller, D. R., Avery, C. W., Easterling, D. R., et al. Washington, DC: US Global Change Research Program, 1515pp.Google Scholar
Van de Kreeke, J., 1998. Adaptation of the Frisian Inlet to a reduction in basin area with special reference to the cross-sectional area. Proceedings of the 8th Conference on Physics of Estuaries and Coastal Seas (PECS), 355–362.Google Scholar
Van de Kreeke, J., and Brouwer, R. L., 2017. Tidal Inlets: Hydrodynamics and Morphodynamics. Cambridge: Cambridge University Press, 174pp.Google Scholar
Van Rijn, L. C., 1984a. Sediment transport, part I: Bed load transport. Journal of Hydraulic Engineering, 110, 14311456.Google Scholar
Van Rijn, L. C., 1984b. Sediment transport, part II: Suspended load transport. Journal of Hydraulic Engineering, 110, 16131641.Google Scholar
Van Rijn, L. C., 1989. Handbook of Sediment Transport by Current and Waves. Delft: Delft Hydraulics.Google Scholar
Van Rijn, J. C., 1993. Principles of Sediment Transport in Rivers, Estuaries and Coastal Seas. Amsterdam: Aqua Publications.Google Scholar
Van Rijn, J. C., 2007a. Unified view of sediment transport by currents and waves. I: Initiation of motion, bed roughness, and bed-load transport. Journal of Hydraulic Engineering, 133, 649667.Google Scholar
Van Rijn, J. C., 2007b. Unified view of sediment transport by currents and waves. II: Suspended transport. Journal of Hydraulic Engineering, 133, 668689.Google Scholar
Van Rijn, J. C., 2007c. Unified view of sediment transport by currents and waves. III: Graded beds. Journal of Hydraulic Engineering, 133, 761775.Google Scholar
Van Rijn, J. C., Walstra, D. R., and Van Ormondt, M., 2007. Unified view of sediment transport by currents and waves. IV: Application of morphodynamic model. Journal of Hydraulic Engineering, 133, 776–693.Google Scholar
Vanoni, V., and Hwang, L., 1967. Relation between bed forms and friction in streams. Journal of the Hydraulics Division, ASCE, 93, 121144.Google Scholar
Vincent, C. L., and Corson, W. D., 1980. The geometry of selected US tidal inlets. GITI Report 20, US Army Corps of Engineers, Washington, DC.Google Scholar
Vincent, C. L., and Corson, W. D., 1981. Geometry of tidal inlets: Empirical equations. Journal of the Waterway, Port, Coastal and Ocean Division, ASCE, 107, 19.Google Scholar
Vincente, C. M., and Uva, L. P., 1984. Sedimentation in dredged channels and basins: Prediction of shoaling rates. Proceedings of 19th International Conference on Coastal Engineering. New York: ASCE Press, 18631878.Google Scholar
Volonte, C. R., and Arismendi, J., 1994. Sea-level rise and Venezuela: Potential impacts and consequences. Journal of Coastal Research, 14(SI), 285302.Google Scholar
Volonte, C. R., and Nicholls, R. J., 1994. Sea-level rise and Uruguay: Potential impacts and responses. Journal of Coastal Research, 14(SI), 262284.Google Scholar
Walker, I. J., Davidson-Arnott, R. G. D., Bauer, B. O., et al., 2017. Scale-dependent perspectives on the geomorphology and evolution of beach–dune systems. Earth-Science Reviews, 171, 220253.Google Scholar
Walton, T. L., 1976. Littoral drift estimates along the coastline of Florida. Technical Report No. 13, Florida Sea Grant Program, 39pp.Google Scholar
Walton, T. L., and Adams, W. D., 1976. Capacity of inlet outer bars to store sand. Proceedings of the 15th Coastal Engineering Conference. New York: ASCE Press, 19191937.Google Scholar
Walton, T. L., Dean, R. G., and Rosati, J. D., 2012. Sediment budget possibilities and improbabilities. Coastal Engineering, 60, 323325.Google Scholar
Wamsley, T. V., Cialone, M. A., Smith, J. M., Atkinson, J. H., and Rosati, J. D., 2010. The potential of wetlands in reducing storm surge. Ocean Engineering, 37, 5968.Google Scholar
Wamsley, T. V., Cialone, M. A., Smith, J. M., and Ebersole, B. A., 2009a. Influence of landscape restoration and degradation on storm surge and waves in southern Louisiana. Journal of Natural Hazards, 51, 207224.Google Scholar
Wamsley, T. V., Cialone, M. A., Westerink, J., and Smith, J. M., 2009b. Numerical modeling system to simulate influence of marsh restoration and degradation on storm surge and waves. ERDC/CHL CHETN-I-77. US Army Engineer and Research Development Center, Vicksburg, MS.Google Scholar
Wang, P., 1998. Longshore sediment flux in the water column and across the surf zone. Journal of Waterway, Port, Coastal & Ocean Engineering, ASCE, 124, 108117.Google Scholar
Wang, P., 2012. Measuring and modeling suspended sediment concentration profiles in the surf zone. Journal of Palaeogeography, 1(2), 172193.Google Scholar
Wang, P., Adam, J. D., Cheng, J., and Vallée, M., 2020. Morphological and sedimentological impacts of Hurricane Michael along the northwest Florida coast. Journal of Coastal Research, 36, 932950.Google Scholar
Wang, P., and Beck, T. M., 2012. Morphodynamics of an anthropogenically altered dual-inlet system: John’s Pass and Blind Pass, west-central Florida, USA. Marine Geology, 291–294, 162175.Google Scholar
Wang, P., and Beck, T. M., 2017. Determining dredge-induced turbidity and sediment plume settling within an Intracoastal Waterway System. Journal of Coastal Research, 33, 243253.Google Scholar
Wang, P., and Davis, R. A., 1998. A beach profile model for a barred coast: Case study from Sand Key, west-central Florida. Journal of Coastal Research, 14, 981991.Google Scholar
Wang, P., and Davis, R. A., 1999. Depth of closure and the equilibrium beach profile: A case study from Sand Key, West-Central Florida. Shore and Beach, 67, 3342.Google Scholar
Wang, P., Davis, R. A., and Kraus, N. C., 1998a. Cross-shore distribution of sediment textures under breaking waves. Journal of Sedimentary Research, 68, 497506.Google Scholar
Wang, P., Ebersole, B. A., and Smith, E. R., 2003. Beach profile evolution under plunging and spilling breakers. Journal of Waterway, Port, Coastal and Ocean Engineering, ASCE, 129(1), 4146.Google Scholar
Wang, P., Ebersole, B. A., Smith, E. R., and Johnson, B. D., 2002a. Temporal and spatial variations of surf-zone currents and suspended-sediment concentration. Coastal Engineering, 46, 175211.Google Scholar
Wang, P., and Horwitz, M. H., 2007. Erosional and depositional characteristics of regional overwash deposits caused by multiple hurricanes. Sedimentology, 54, 545564.Google Scholar
Wang, P., Kirby, J. H., Haber, J. D., et al., 2006. Morphological and sedimentological impacts of Hurricane Ivan and immediate poststorm beach recovery along the northwestern Florida barrier-island coasts. Journal of Coastal Research, 22(6), 13821402.Google Scholar
Wang, P., and Kraus, N. C., 1999. Longshore sediment transport rate measured by short-term impoundment. Journal of Waterway, Port, Coastal and Ocean Engineering, ASCE, 125, 118126.Google Scholar
Wang, P., and Kraus, N. C., 2005. Beach profile equilibrium and patterns of wave decay and energy dissipation across the surf zone elucidated in a large-scale laboratory experiment. Journal of Coastal Research, 21, 522534.Google Scholar
Wang, P., Kraus, N. C., and Davis, R. A., 1998b. Total rate of longshore sediment transport in the surf zone: Field measurements and empirical predictions. Journal of Coastal Research, 14, 269283.Google Scholar
Wang, P., Smith, E. R., and Ebersole, B. A., 2002b. Large-scale laboratory measurements of longshore sediment transport under spilling and plunging breakers. Journal of Coastal Research, 18, 118135.Google Scholar
Wang, P., Stone, G. W., and Cheng, J., 2017. Nearshore wave measurement. In Finkl, C. (ed.), Encyclopedia of Coastal Science, 2nd ed. Dordrecht: Springer, 702705.Google Scholar
Weggel, J. R., 1972. Maximum breaker height. Journal of Waterway, Harbors, and Coastal Engineering Division, ASCE, 98, 529548.Google Scholar
Weggel, J. R., 1981. Weir sand-bypassing systems. Special Report No. 8, Coastal Engineering Research Center, US Army Engineer Waterways Experiment Station, Vicksburg, MS.Google Scholar
Westfall, Z., 2018. Morphodynamics of Shell Key and Mullet Key barrier islands: Their origin and development. MS Thesis, University of South Florida, Tampa, 121pp.Google Scholar
Wiegel, R. L., 1991. Protection of Galveston, Texas from overflows by gulf storms: Grade raising, seawall and embankment. Shore and Beach, 59, 410.Google Scholar
Wiegel, R. L., and Saville, T., Jr., 1996. History of coastal engineering in the United States. In Kraus, N. C. (ed.), History and Heritage of Coastal Engineering. New York: ASCE Press, 214274.Google Scholar
Wilson, K. C., 1987. Analysis of bed-load motion at high shear stress. Journal of Hydraulic Engineering, 113, 97103.Google Scholar
Work, P. A., and Dean, R. G., 1991. Effect of varying sediment size on equilibrium beach profiles. Proceedings of Coastal Sediments ’91. New York: ASCE Press, 891903.Google Scholar
Work, P. A., and Kaihatu, J. M., 1997. Wave transformation at Pensacola Pass, Florida. Journal of Waterway, Port, Coastal, and Ocean Engineering, ASCE, 123, 314321.Google Scholar
Wright, L. D., 1976. Nearshore wave power dissipation and coastal energy regime of the Sydney-Jervis Bay region, New South Wales: A comparison. Australian Journal of Marine and Freshwater Research, 27, 633640.Google Scholar
Wright, L. D., 1987. Shelf-surf zone coupling: Diabathic shoreface transport. Proceedings of Coastal Sediments ’87. New York: ASCE Press, 85101.Google Scholar
Wright, L. D., 1995. Morphodynamics of Inner Continental Shelves. Boca Raton, FL: CRC Press, 241pp.Google Scholar
Wright, L. D., Boon, J. D., Green, M. O., and List, J. H., 1986. Response of the mid-shoreface of the southern Mid-Atlantic Bight to a “northeaster”. Geo-Marine Letters, 6, 153160.Google Scholar
Wright, L. D., and Short, A. D., 1984. Morphodynamic variability of surf zones and beaches: A synthesis. Marine Geology, 56, 93118.Google Scholar
Wu, W., Sanchez, A., and Zhang, M., 2011. An implicit 2-D shallow water flow model for inlets and navigation projects. Journal of Coastal Research, 59(SI), 1527.Google Scholar
Xu, Y. J., Lam, N. S.-N., and Liu, K., 2018. Assessing resilience and sustainability of the Mississippi River Delta as a coupled natural-human system. Water, 10, 1317.Google Scholar
Zhang, J., Larson, M., and Ge, Z. P., 2020. Numerical model of beach profile evolution in the nearshore. Journal of Coastal Research, 36, 506520.Google Scholar
Zhang, K., Douglas, B. C., and Leatherman, S. P., 2004. Global warming and coastal erosion. Climatic Change, 64, 4158.Google Scholar

Save book to Kindle

To save this book to your Kindle, first ensure [email protected] is added to your Approved Personal Document E-mail List under your Personal Document Settings on the Manage Your Content and Devices page of your Amazon account. Then enter the ‘name’ part of your Kindle email address below. Find out more about saving to your Kindle.

Note you can select to save to either the @free.kindle.com or @kindle.com variations. ‘@free.kindle.com’ emails are free but can only be saved to your device when it is connected to wi-fi. ‘@kindle.com’ emails can be delivered even when you are not connected to wi-fi, but note that service fees apply.

Find out more about the Kindle Personal Document Service.

  • References
  • Ping Wang, University of South Florida, Tanya M. Beck
  • Book: Beach-Inlet Interaction and Sediment Management
  • Online publication: 15 September 2022
  • Chapter DOI: https://doi.org/10.1017/9781108772273.009
Available formats
×

Save book to Dropbox

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Dropbox.

  • References
  • Ping Wang, University of South Florida, Tanya M. Beck
  • Book: Beach-Inlet Interaction and Sediment Management
  • Online publication: 15 September 2022
  • Chapter DOI: https://doi.org/10.1017/9781108772273.009
Available formats
×

Save book to Google Drive

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Google Drive.

  • References
  • Ping Wang, University of South Florida, Tanya M. Beck
  • Book: Beach-Inlet Interaction and Sediment Management
  • Online publication: 15 September 2022
  • Chapter DOI: https://doi.org/10.1017/9781108772273.009
Available formats
×