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901. Roff, G. 2020, Reef accretion and coral growth rates are decoupled in Holocene reef frameworks, Marine Geology 419: 106065.
902. Kayal, M. and Adjeroud, M. 2022, The war of corals: patterns, drivers and implications of changing coral competitive performances across reef environments, Royal Society Open Science 9(6): 220003.
903. Chadwick, N.E. and Morrow, K.M. 2011, Competition among sessile organisms on coral reefs, in Coral reefs: an ecosystem in transition, eds Z. Dubinsky and N. Stambler, Springer, Dordrecht, pp. 347-371.
904. McCook, L.J., Jompa, J. and Diaz-Pulido, G. 2001, Competition between corals and algae on coral reefs: a review of evidence and mechanisms, Coral Reefs 19(4): 400-417.
905. Hoey, A.S., McClure, E. and Sims, C. 2022, Coral reef ecology, in Coral Reefs of Australia: Perspectives from Beyond the Water's Edge, eds S.M. Hamylton, P. Hutchings and O. Hoegh-Guldberg, CSIRO Publishing, Collingwood, pp. 151–157.
906. Rölfer, L., Reuter, H., Ferse, S.C., Kubicek, A., Dove, S., et al. 2021, Coral-macroalgal competition under ocean warming and acidification, Journal of Experimental Marine Biology and Ecology 534: 151477.
907. Bieg, C., Vallès, H., Tewfik, A., Lapointe, B.E. and McCann, K.S. 2024, Toward a Multi-stressor theory for coral reefs in a changing world, Ecosystems 27: 310-328.
908. Richardson, L.E., Graham, N.A.J. and Hoey, A.S. 2020, Coral species composition drives key ecosystem function on coral reefs, Proceedings of the Royal Society B 287(1921): 20192214.
909. Johnson, M.D., Swaminathan, S.D., Nixon, E.N., Paul, V.J. and Altieri, A.H. 2021, Differential susceptibility of reef-building corals to deoxygenation reveals remarkable hypoxia tolerance, Scientific Reports 11(1): 23168.
910. Wakwella, A., Mumby, P.J. and Roff, G. 2020, Sedimentation and overfishing drive changes in early succession and coral recruitment, Proceedings of the Royal Society B 287(1941): 20202575.
911. Cresswell, A.K., Renton, M., Langlois, T.J., Thomson, D.P., Lynn, J., et al. 2023, Coral reef state influences resilience to acute climate-mediated disturbances, Global Ecology and Biogeography 33(1): 4-16.
912. McDowell, N.G., Allen, C.D., Anderson-Teixeira, K., Aukema, B.H., Bond-Lamberty, B., et al. 2020, Pervasive shifts in forest dynamics in a changing world, Science 368(6494): eaaz9463.
913. Staude, I.R., Weigelt, A. and Wirth, C. 2023, Biodiversity change in light of succession theory, Oikos 2023(11): e09883.
914. Harvey, B.P., Kon, K., Agostini, S., Wada, S. and Hall‐Spencer, J.M. 2021, Ocean acidification locks algal communities in a species‐poor early successional stage, Global Change Biology 27(10): 2174-2187.
915. Bonin, M.C., Boström-Einarsson, L., Munday, P.L. and Jones, G.P. 2015, The prevalence and importance of competition among coral reef fishes, Annual Review of Ecology, Evolution, and Systematics 46: 169-190.
916. Matley, J.K., Heupel, M.R., Fisk, A.T., Simpfendorfer, C.A. and Tobin, A.J. 2017, Measuring niche overlap between co-occurring Plectropomus spp. using acoustic telemetry and stable isotopes, Marine and Freshwater Research 68(8): 1468-1478.
917. Poulos, D.E. and McCormick, M.I. 2022, Prior residency improves the performance of a habitat specialist in a degrading environment, Coral Reefs 41(2): 423-433.
918. Doll, P.C., Munday, P.L., Bonin, M.C. and Jones, G.P. 2021, Habitat specialisation and overlap in coral reef gobies of the genus Eviota (Teleostei: Gobiidae), Marine Ecology Progress Series 677: 81-94.
919. Waterhouse, J., Pearson, R., Lewis, S., Davis, A. and Waltham, N. 2024, 7. Great Barrier Reef ecohydrology, in Oceanographic Processes of Coral Reefs. Physical and Biological Links in The Great Barrier Reef, eds E. Wolanski and M.J. Kingsford, CRC Press, Boca Raton, pp. 105-125.
920. Quigley, K.M., Bay, L.K. and van Oppen, M.J.H. 2019, The active spread of adaptive variation for reef resilience, Ecology and evolution 9(19): 11122-11135.
921. Schlaff, A.M., Heupel, M.R., Udyawer, V. and Simpfendorfer, C.A. 2020, Sex-based differences in movement and space use of the blacktip reef shark, Carcharhinus melanopterus, PLoS One 15(4): e0231142.
922. Dobbelaere, T., Holstein, D.M., Muller, E.M., Gramer, L.J., McEachron, L., et al. 2022, Connecting the dots: Transmission of stony coral tissue loss disease from the Marquesas to the Dry Tortugas, Frontiers in Marine Science 9: 778938.
923. Hendrick, G.C., Nicholson, M.D., Narvaez, P., Sun, D., Packard, A., et al. 2023, Diel fish migration facilitates functional connectivity of coral reef and seagrass habitats via transport of ectoparasites, Marine Ecology Progress Series 731: 249-265.
924. Waltham, N.J., Burrows, D., Wegscheidl, C., Buelow, C., Ronan, M., et al. 2019, Lost floodplain wetland environments and efforts to restore connectivity, habitat, and water quality settings on the Great Barrier Reef, Frontiers in Marine Science 6: 71.
925. van Woesik, R., Shlesinger, T., Grottoli, A.G., Toonen, R.J., Vega Thurber, R., et al. 2022, Coral-bleaching responses to climate change across biological scales, Global Change Biology 28(14): 4229-4250.
926. Riginos, C., Hock, K., Matias, A.M., Mumby, P.J., van Oppen, M.J.H., et al. 2019, Asymmetric dispersal is a critical element of concordance between biophysical dispersal models and spatial genetic structure in Great Barrier Reef corals, Diversity and Distributions 25(11): 1684-1696.
927. Gurdek-Bas, R., Benthuysen, J.A., Harrison, H.B., Zenger, K.R. and van Herwerden, L. 2022, The El Niño Southern Oscillation drives multidirectional inter-reef larval connectivity in the Great Barrier Reef, Scientific Reports 12(1): 21290.
928. Cumming, G.S. and Bellwood, D.R. 2023, Broad‐scale analysis of fish community data suggests critical need to support regional connectivity of coral reefs, Ecological Applications 33(4): e2849.
929. Hock, K., Doropoulos, C., Gorton, R., Condie, S.A. and Mumby, P.J. 2019, Split spawning increases robustness of coral larval supply and inter-reef connectivity, Nature Communications 10(1): 3463.
930. Saint-Amand, A., Lambrechts, J. and Hanert, E. 2023, Biophysical models resolution affects coral connectivity estimates, Scientific Reports 13(1): 9414.
931. Thomas, C.J., Bridge, T.C., Figueiredo, J., Deleersnijder, E. and Hanert, E. 2015, Connectivity between submerged and near‐sea‐surface coral reefs: can submerged reef populations act as refuges? Diversity and Distributions 21: 1254-1266.
932. Figueiredo, J., Thomas, C.J., Deleersnijder, E., Lambrechts, J., Baird, A.H., et al. 2022, Global warming decreases connectivity among coral populations, Nature Climate Change 12(1): 83-87.
933. Hale, L., Gerhardt, K., Day, J.C. and Heron, S.F. 2022, A First Nations approach to addressing climate change—Assessing interrelated key values to identify and address adaptive management for country, 38(2).
934. Roberts, P., Buhrich, A., Caetano-Andrade, V., Cosgrove, R., Fairbairn, A., et al. 2021, Reimagining the relationship between Gondwanan forests and Aboriginal land management in Australia's “Wet Tropics”, Iscience 24(3).
935. Jaensch, R. 2005, Wetland Management Profile: Saltmarshes, Department of Environment and Science (Qld).
936. Neldner, V.J., Niehus, R.E., Wilson, B.A., McDonald, W.J.F., Ford, A.J., et al. 2017, The vegetation of Queensland: Descriptions of broad vegetation groups. Version 3.0, Queensland Herbarium, Department of Science, Information Technology and Innovation, Brisbane.
937. Meynecke, J., Lee, S.Y., Duke, N.C. and Warnken, J. 2007, Relationships between estuarine habitats and coastal fisheries in Queensland, Australia, Bulletin of Marine Science 80(3): 773-793.
938. Abbott, B.N., Wallace, J., Nicholas, D.M., Karim, F. and Waltham, N.J. 2020, Bund removal to re-establish tidal flow, remove aquatic weeds and restore coastal wetland services—North Queensland, Australia, PLoS One 15(1): e0217531.
939. Thomas, B.E. and Connolly, R.M. 2001, Fish use of subtropical saltmarshes in Queensland, Australia: relationships with vegetation, water depth and distance onto the marsh, Marine Ecology Progress Series 209: 275-288.
940. Taylor, M.D., Becker, A., Moltschaniwskyj, N.A. and Gaston, T.F. 2018, Direct and indirect interactions between lower estuarine mangrove and saltmarsh habitats and a commercially important penaeid shrimp, Estuaries and Coasts 41(3): 815-826.
941. Perera, N., Lokupitiya, E., Halwatura, D. and Udagedara, S. 2022, Quantification of blue carbon in tropical salt marshes and their role in climate change mitigation, Science of the Total Environment 820: 153313.
942. Wegscheidl, C., Sheaves, M., McLeod, I.M. and Fries, J. 2015, Queensland's saltmarsh habitats: Values, threats and opportunities to restore ecosystem services, James Cook University, Townsville.
943. Department of Natural Resources and Mines 2001, Policy for Development and Use of Ponded Pastures, Department of Natural Resources and Mines, Brisbane.
944. Luke, H., Martens, M.A., Moon, E.M., Smith, D., Ward, N.J., et al. 2017, Ecological restoration of a severely degraded coastal acid sulfate soil: A case study of the East Trinity wetland, Queensland, Ecological Management & Restoration 18(2): 103-114.
945. Queensland Government 2013, WetlandInfo - Palustrine ecology, <https://wetlandinfo.des.qld.gov.au/wetlands/ecology/aquatic-ecosystems-natural/palustrine/>.
946. Wallace, J., Bueno, C. and Waltham, N.J. 2022, Modelling the removal of nitrogen and sediment by a constructed wetland system in north Queensland, Australia, Ecological Engineering 184: 106767.
947. Yao, L., Adame, M.F. and Chen, C. 2021, Resource stoichiometry, vegetation type and enzymatic activity control wetlands soil organic carbon in the Herbert River catchment, North-east Queensland, Journal of environmental management 296: 113183.
948. Waltham, N., Motson, K. and Molinari, B. 2024, 2022 Scientific Consensus Statement: Summary | Evidence Statement for Question 4.7: What is the efficacy of natural/near-natural wetlands, restored, treatment (constructed) wetlands and other treatment systems in GBR catchments in improving water quality (nutrients, fine sediments, and pesticides?) in 2022 Scientific Consensus Statement on land-based impacts on Great Barrier Reef water quality and ecosystem condition, eds J. Waterhouse, M. Pineda and K. Sambrook, Commonwealth of Australia and Queensland Government.
949. Waltham, N., Lovelock, C., Adame, M.F. and Motson, K. 2024, 2022 Scientific Consensus Statement: Summary | Evidence Statement for Question 4.9: What role do natural/near-natural wetlands play in the provision of ecosystem services and how is the service of water quality treatment compatible or at odds with other services (e.g., habitat, carbon sequestration? in 2022 Scientific Consensus Statement on land-based impacts on Great Barrier Reef water quality and ecosystem condition, eds J. Waterhouse, M. Pineda and K. Sambrook, Commonwealth of Australia and Queensland Government.
950. Wetland Condition Science 2023, Wetland condition 2022: Great Barrier Reef catchment wetland condition monitoring program, Department of Environment and Science, Queensland Government.