The role of coastal plant communities for climate change mitigation and adaptation (original) (raw)

References

1. Le Quéré, C. et al. Trends in the sources and sinks of carbon dioxide. Nature Geosci. 2, 831–836 (2009).
   Article Google Scholar
2. Agrawal, A., Nepstad, D. & Chhatre, A. Reducing emissions from deforestation and forest degradation. Annu. Rev. Environ. Resour. 36, 373–396 (2011).
   Google Scholar
3. Duarte, C. M., Middelburg, J. & Caraco, N. Major role of marine vegetation on the oceanic carbon cycle. Biogeosciences 2, 1–8 (2005).
   CAS Google Scholar
4. Nellemann, C. et al. Blue Carbon: A Rapid Response Assessment (United Nations Environment Programme, 2009).
   Google Scholar
5. McLeod, E. et al. A blueprint for blue carbon: Towards an improved understanding of the role of vegetated coastal habitats in sequestering CO2 . Front. Ecol. Environ. 9, 552–560 (2011).
   Google Scholar
6. Jones, H. P., Hole, D. G. & Zavaleta, E. S. Harnessing nature to help people adapt to climate change. Nature Clim. Change 2, 504–509 (2012).
   Google Scholar
7. http://www.ramsar.org
8. Waycott, M. et al. Accelerating loss of seagrasses across the globe threatens coastal ecosystems. Proc. Natl Acad. Sci. USA 106, 12377–12381 (2009).
   CAS Google Scholar
9. Orth, R. J. et al. A global crisis for seagrass ecosystems. BioScience 56, 987–996 (2006).
   Google Scholar
10. Valiela, I., Bowen, J. L. & York, J. K. Mangrove forests: One of the world's threatened major tropical environments. BioScience 51, 807–815 (2001).
    Google Scholar
11. Adam, P. Saltmarshes in a time of change. Environ. Conserv. 29, 39–61 (2002).
    Google Scholar
12. Reusch, T. B. H., Ehlers, A., Hämmerli, A. & Worm, B. Ecosystem recovery after climatic extremes enhanced by genotypic diversity. Proc. Natl Acad. Sci. USA 102, 2826–2831 (2005).
    CAS Google Scholar
13. Marbà, N. & Duarte, C. M. Mediterranean warming triggers seagrass (Posidonia oceanica) shoot mortality. Glob. Change Biol. 16, 2366–2375 (2010).
    Google Scholar
14. Wernberg, T., Thomsen, M. S., Tuya, F. & Kendrick, G. A. J. Exp. Mar. Biol. Ecol. 400, 264–271 (2011).
    Google Scholar
15. Jordà, G., Marbà, N. & Duarte, C. M. Mediterranean seagrass vulnerable to regional climate warming. Nature Clim. Change 2, 821–824 (2012).
    Google Scholar
16. Sorte, C. J. B., Williams, S. L. & Carlton, J. T. Marine range shifts and species introductions: Comparative spread rates and community impacts. Glob. Ecol. Biogeog. 19, 303–316 (2010).
    Google Scholar
17. Ackerman, J. D. & Okubo, A. Reduced mixing in a marine macrophyte canopy. Funct. Ecol. 7, 305–309 (1993).
    Google Scholar
18. Koch, E. W. et al. Non-linearity in ecosystem services: Temporal and spatial variability in coastal protection. Front. Ecol. Environ. 7, 29–37 (2009).
    Google Scholar
19. Mendez, F. J. & Losada, I. J. Transformation of random and non-random breaking waves over vegetation fields. Coast. Eng. 51, 103–118 (2004).
    Google Scholar
20. Bouma, T. J. et al. Trade-offs related to ecosystem engineering: A case study on stiffness of emerging macrophytes. Ecology 86, 2187–2199 (2005).
    Google Scholar
21. Koch, E. W., Ackerman, J. D., Verduin, J. & van Keulen, M. in Seagrasses: Biology, Ecology and Conservation (eds Larkum, A. W. D., Orth, R. J. & Duarte, C. M.) 193–225 (Springer, 2006).
    Google Scholar
22. Gacia, E. & Duarte, C. M. Sediment retention by a Mediterranean Posidonia oceanica meadow: The balance between deposition and resuspension. Estuar. Coast. Shelf Sci. 52, 505–514 (2001).
    Google Scholar
23. Peralta, G., van Duren, L. A., Morris, E. P. & Bouma, T. J. Consequences of shoot density and stiffness for ecosystem engineering benthic macrophytes in flow dominated areas: A hydrodynamic flume study. Mar. Ecol. Prog. Ser. 368, 103–115 (2008).
    Google Scholar
24. Yang, S. L., Shi, B. W., Bouma, T. J., Ysebaert, T. & Luo, X. X. Wave attenuation at a salt-marsh margin: A case study of an exposed coast on the Yangtze estuary. Estuar. Coasts 35, 169–182 (2012).
    Google Scholar
25. Furukawa, K., Wolanski, E. & Mueller, H. Currents and sediment transport in mangrove forests. Estuar. Coast. Shelf Sci. 44, 301–310 (1997).
    CAS Google Scholar
26. Barbier, E. B., Hacker, S. D., Kennedy, C., Koch, E. W., Stier, A. C. & Silliman, B. R. The value of estuarine and coastal ecosystem services. Ecol. Monogr. 81, 169–193 (2011).
    Google Scholar
27. Costanza, R. et al. The value of the world´s ecosystem services and natural capital. Nature 387, 253–260 (1997).
    CAS Google Scholar
28. Duarte, C. M. & Cebrián, J. The fate of marine autotrophic production. Limnol. Oceanogr. 41, 1758–1766 (1996).
    CAS Google Scholar
29. Kennedy, H. et al. Seagrass sediments as a global carbon sink: Isotopic constraints. Glob. Biogeochem. Cycles 24, GB4026 (2010).
    Google Scholar
30. Mateo, M. A., Romero, J., Pérez, M., Littler, M. M. & Littler, D. S. Dynamics of millenary organic deposits resulting from the growth of the Mediterranean seagrass Posidonia oceanica. Estuar. Coast. Shelf Sci. 44, 103–110 (1997).
    Google Scholar
31. Ward, L. G., Zaprowski, B. J., Trainer, K. D. & Davis, P. T. Stratigraphy, pollen history and geochronology of tidal marshes in a Gulf of Maine estuarine system: Climatic and relative sea level impacts. Mar. Ecol. 256, 1–17 (2008).
    Google Scholar
32. Filho, P. W. M. et al. Holocene coastal evolution and facies model of the Braganca macrotidal flat on the Amazon mangrove coast, northern Brazil. J. Coast. Res. 39, 306–31 (2006).
    Google Scholar
33. Enríquez, S., Duarte, C. M. & Sand-Jensen, K. Patterns in decomposition rates among photosynthetic organisms: The importance of detritus C: N:P content. Oecologia 94, 457–471 (1993).
    Google Scholar
34. Duarte, C. M. et al. Root production and belowground seagrass biomass. Mar. Ecol. Prog. Ser. 171, 97–108 (1998).
    Google Scholar
35. Breithaupt, J. L., Smoak, J. M., Smith, T. J. III, Sanders, C. J. & Hoare, A. Organic carbon burial rates in mangrove sediments: Strengthening the global budget. Glob. Biogeochem. Cycles 26, GB3011 (2012).
    Google Scholar
36. Langley, J. A., McKee, K. L., Cahoon, D. R., Cherry, J. A. & Megonigal, J. P. Elevated CO2 stimulates marsh elevation gain, counterbalancing sea-level rise. Proc. Natl Acad. Sci. USA 106, 6182–6186 (2009).
    CAS Google Scholar
37. Kirwan, M. L. & Mudd, S. M. Response of salt-marsh carbon accumulation to climate change. Nature 489, 550–553 (2012).
    CAS Google Scholar
38. Donato, D. C. et al. Mangroves among the most carbon-rich forests in the tropics. Nature Geosci. 4, 293–297 (2011).
    CAS Google Scholar
39. Fourqurean, J. W. et al. Seagrass ecosystems as a significant global carbon stock. Nature Biogeosci. 5, 505–509 (2012).
    CAS Google Scholar
40. Menéndez, M. & Woodworth, P. L. Changes in extreme high water levels based on a quasi-global tide-gauge data set. J. Geophys. Res. 115, C10011 (2010).
    Google Scholar
41. Izaguirre, C., Mendez, F. J., Menendez, M., Luceño, A & Losada, I. J. Extreme wave climate variability southern Europe using satellite data. J. Geophys. Res. 115, C04009 (2010).
    Google Scholar
42. Menéndez, M., Mendez, F. J., Losada, I. J. & Graham, N. E. Variability of extreme wave heights in the northeast Pacific Ocean based on buoy measurements. Geophys. Res. Lett. 35, L22607 (2008).
    Google Scholar
43. Hemer, M. A., Church, J. A. & Hunter, J. R. Variability and trends in the directional wave climate of the Southern Hemisphere. Int. J. Climatol. 30, 475–491 (2010).
    Google Scholar
44. Izaguirre, C., Mendez, F. J., Menendez, M. & Losada, I. J. Global extreme wave height variability based on datellite data. Geophys. Res. Lett. 38, L10607 (2011).
    Google Scholar
45. Young, R. R., Zieger, S. & Babanin. A. V. Global trends in wind speed and wave height. Science 332, 451–455 (2011).
    CAS Google Scholar
46. Church, J. A. & White, J. W. Sea level rise from the late 19th to early 21st century. Surv. Geophys. 32, 585–602 (2011).
    Google Scholar
47. Meehl, G. A. et al. in Climate Change 2007: The Physical Science Basis (eds Solomon, S. et al.) Ch. 10 (IPCC, Cambridge Univ. Press, 2007).
    Google Scholar
48. Vermeer, M. & Rahmstorf, S. Global sea level linked to global temperature. Proc. Natl Acad. Sci. USA 106, 21527–21532 (2009).
    CAS Google Scholar
49. Seneviratne, S. I. et al. in Special Report on Managing the Risks of Extreme Events and Disasters to Advance Climate Change Adaptation (SREX) (eds Field, C. B. et al.) Ch. 3 (IPCC, Cambridge Univ. Press, 2012).
    Google Scholar
50. Méndez, F. J., Losada, I. J. & Losada, M. A. Hydrodynamics induced by wind waves in a vegetation field. J. Geophys. Res. Oceans 104, 18383–18396 (1999).
    Google Scholar
51. Mazda, Y. et al. Drag force due to vegetation in mangrove swamps. Mangroves Salt Marsh 1, 193–199 (1997).
    Google Scholar
52. Ghisalberti, M. & Nepf, H. Shallow flows over a permeable medium: The hydrodynamics of submerged aquatic canopies. Transport Porous Med. 78, 385–402 (2009).
    Google Scholar
53. Chen, Z., Ortiz, A., Zong, L. & Nepf, H. The wake structure behind a porous obstruction and its implications for deposition near a finite patch of emergent vegetation. Wat. Resour. Res. 8, W09517 (2012).
    Google Scholar
54. Hemminga, M. A. & Duarte, C. M. Seagrass Ecology (Cambridge Univ. Press, 2000).
    Google Scholar
55. Tanino, Y. & Nepf, H. Laboratory investigation oF mean drag in a random array of rigid, emergent cylinders. J. Hydraul. Eng. 134, 4–41 (2008).
    Google Scholar
56. Bryan, K. R., Tay, H. W., Pilditch, C. A., Lundquist, C. J. & Hunt, H. L. The effects of seagrass (Zostera muelleri) on boundary-layer hydrodynamics in Whangapoua Estuary, New Zealand. J. Coast. Res. 50, 668–672 (2007).
    Google Scholar
57. Vo-Luong, P. & Massel, S. Energy dissipation in non-uniform mangrove forests of arbitrary depth. J. Mar. Syst. 74, 603–622 (2008).
    Google Scholar
58. Losada, I. J., Losada, M. A. & Martin, F. Experimental study of wave-induced flow in porous media. Coast. Eng. 26, 77–98 (1995).
    Google Scholar
59. Mazarrasa, I., Marbà, N., Hendriks, I. E., Losada, I. J. & Duarte, C. M. Estimates of Average Sediment Accretion Rates in Vegetated Coastal Habitats Around the World (Digital CSIC, 2013); http://hdl.handle.net/10261/77396
60. Turner, W. R., Oppenheimer, M. & Wilcove, D. S. A force to fight global warming. Nature 462, 278–279 (2009).
    CAS Google Scholar
61. Duarte, C. M., Dennison, W. C., Orth, R. J. W. & Carruthers, T. J. B. The charisma of coastal ecosystems: Addressing the imbalance. Estuar. Coasts 31, 233–238 (2008).
    Google Scholar
62. Cahoon, D. R. et al. Mass tree mortality leads to mangrove peat collapse at Bay Islands, Honduras after Hurricane Mitch. J. Ecol. 91, 1093–1105 (2003).
    Google Scholar
63. Lovelock, C. E., Ruess, R. W. & Feller, I. C. CO2 efflux from cleared mangrove peat. PLoS ONE 6, e21279 (2011).
    CAS Google Scholar
64. Siikamäki, J., Sanchirico, J. N. & Jardine, S. L. Global economic potential for reducing carbon dioxide emissions from mangrove loss. Proc. Natl Acad. Sci. USA 109, 14369–14374 (2012).
    Google Scholar
65. Pendleton, L. et al. Estimating global “blue carbon” emissions from conversion and degradation of vegetated coastal ecosystems. PLoS ONE 7, e43542 (2012).
    CAS Google Scholar
66. Report of the Conference of the Parties on its Fifteenth Session, Held in Copenhagen from 7 to 19 December 2009 (UNFCCC, 2009).
67. Arnaud-Haond, S. et al. Genetic recolonization of mangrove: Genetic diversity still increasing in the Mekong Delta 30 years after Agent Orange. Mar. Ecol. Prog. Ser. 390, 129–135 (2009).
    Google Scholar
68. An, S. et al. China's natural wetlands: Past problems, current status, and future challenges. Ambio 36, 335–342 (2007).
    CAS Google Scholar
69. http://www.globalrestorationnetwork.org/ecosystems/coastal/estuaries-marshes-mangroves/case-studies
70. Sintes, T., Marbà, N., Duarte, C. M. & Kendrick. G. A. Non-linear processes in seagrass colonisation explained by simple clonal growth rules. Oikos 108, 165–175 (2005).
    Google Scholar
71. McGlathery, K. J. et al. Recovery trajectories during state change from bare sediment to eelgrass dominance. Mar. Ecol. Prog. Ser. 448, 209–221 (2012).
    Google Scholar
72. Osland, M. J. et al. Ecosystem development after mangrove wetland creation: Plant-soil change across a 20-year chronosequence. Ecosystems 15, 848–866 (2012).
    CAS Google Scholar
73. Craft, C. et al. The pace of ecosystem development of constructed Spartina alterniflora marshes. Ecol. Appl. 13, 1417–1432 (2003).
    Google Scholar
74. Irving, A. D., Connell, S. D. & Russell, B. D. Restoring coastal plants to improve global carbon storage: Reaping what we sow. PLoS ONE 6, e18311 (2011).
    CAS Google Scholar
75. Mudd, S. M., Howell, S. M. & Morris, J. T. Impact of dynamic feedbacks between sedimentation, sea-level rise, and biomass production on near-surface marsh stratigraphy and carbon accumulation. Estuar. Coast. Shelf Sci. 82, 377–389 (2009).
    CAS Google Scholar
76. Dierssen, H. M., Zimmerman, R. C., Drake, L. A. & Burdige, D. J. Potential export of unattached benthic macroalgae to the deep sea trough wind-driven Langmuir circulation. Geophys. Res. Lett. 36, L04602 (2009).
    Google Scholar
77. Hossain, A. B. M. S., Salleh, A., Boyce, A. N., Chowdhury, P. & Naqiuddin, M. Biodiesel fuel production from algae as renewable energy. Am. J. Biochem. Biotechnol. 4, 250–254 (2008).
    CAS Google Scholar
78. Hussain, K., Nawaz, K., Majeed, A. & Feng, L. Economically effective potential of algae for biofuel production. World Appl. Sci. 9, 1313–1323 (2010).
    CAS Google Scholar
79. Sawyer, D. Climate change, biofuels and eco-social impacts in the Brazilian Amazon and Cerrado. Phil. Trans. R. Soc. B 363, 1747–1752 (2008).
    Google Scholar
80. Phalan, B. The social and environmental impacts of biofuel in Asia: An overview. Appl. Energy 86, S21–S29 (2009).
    CAS Google Scholar
81. Eide, A. The Right to Food and the Impact of Liquid Biofuels (Agrofuels) (FAO, 2008).
    Google Scholar
82. Harrison, R. & Webb, J. A review of the effect of N fertilizer type on gaseous emissions. Adv. Agron. 73, 65–108 (2001).
    CAS Google Scholar
83. Hallegatte, S. Strategies to adapt to an uncertain climate change. Glob. Environ. Change 19, 240–247 (2009).
    Google Scholar
84. Feagin, R. Vegetation's role in coastal protection. Science 320, 176–177 (2008).
    CAS Google Scholar
85. Gedan, K. B., Kirwan, M. L., Wolanski, E., Barbier, E. B. & Silliman, B. R. The present and future role of coastal wetland vegetation in protecting shorelines: Answering recent challenges to the paradigm. Climatic Change 106, 7–29 (2010).
    Google Scholar
86. Barbier, E. B. et al. Coastal ecosystem–based management with nonlinear ecological functions and values. Science 319, 321–323 (2008).
    CAS Google Scholar
87. Adams, C. A., Andrews, J. E. & Jickells, T. Nitrous oxide and methane fluxes versus carbon, nitrogen and phosphorous burial in new intertidal and saltmarsh sediments. Sci. Total Environ. 434, 240–251 (2012).
    CAS Google Scholar
88. Temmerman, S., Govers, G., Wartel, S. & Meire, P. Modelling estuarine variations in tidal marsh sedimentation: Response to changing sea level and suspended sediment concentrations. Mar. Geol. 212, 1–19 (2004).
    Google Scholar
89. Borsje, B. W. et al. How ecological engineering can serve in coastal protection. Ecol. Eng. 37, 113–122 (2011).
    Google Scholar
90. Mangrove planting saves lifes and money in Viet Nam. International Federation of the Red Cross and Red Crescent (19 June 2002); http://go.nature.com/B6ZVwU
91. Costanza, R. et al. The value of coastal wetlands for hurricane protection. Ambio 37, 241–248 (2008).
    Google Scholar
92. Duarte, C. M. et al. Is global ocean sprawl a trojan horse for jellyfish blooms? Front. Ecol. Environ. 11, 91–97 (2013).
    Google Scholar
93. Aburto-Oropeza, O. et al. Mangroves in the Gulf of California increase fishery yields. Proc. Natl Acad. Sci. USA 105, 10456–10459 (2008).
    CAS Google Scholar
94. Odum, H. T. Experiments with engineering of marine ecosystems. Publ. Inst. Mar. Sci. Univ. Texas 9, 374–403 (1963).
    Google Scholar
95. Mitsch, W. J. & Jørgensen, S. E. Ecological engineering: A field whose time has come. Ecol. Eng. 20, 363–377 (2003).
    Google Scholar
96. Fiselier, J. et al. Perspectief Natuurlijke Keringen (Ecoshape, 2011).
    Google Scholar
97. Nowak, K. Mangrove and peat swamp forests: Refuge habitats for primates and felids. Folia Primatol. 83, 361–376 (2013).
    Google Scholar
98. Cai, W. J. Estuarine and coastal ocean carbon paradox: CO2 sinks or sites of terrestrial carbon incineration? Annu. Rev. Mar. Sci. 3, 123–45 (2011).
    Google Scholar
99. Alongi, D. M. Present state and future of the world's mangrove forests. Environ. Conserv. 29, 331–349 (2002).
    Google Scholar
100. Spalding, M., Kainuma, M. & Collins, L. World Atlas of mangroves (Earthscan, 2010).
     Google Scholar
101. Charpy-Robaud, C. & Sournia, A. The comparative estimation of phytoplanktonic microphytobenthic and macrophytobenthic primary production in the oceans. Mar. Microb. Food Webs 4, 31–57 (1990).
     Google Scholar
102. http://www.ecoshape.nl/en_GB/delfland-sand-engine.html

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