Marine Systems, Food Security, and Future Earth

doi:10.1017/9781316761489.029

22 - Marine Systems, Food Security, and Future Earth

from Part VI - Future Earth and Food Security

Published online by Cambridge University Press: 22 October 2018

Elizabeth A. Fulton ,

Éva Plagányi ,

William Cheung ,

Julia Blanchard and

Reg Watson

Edited by

Tom Beer ,

Jianping Li and

Keith Alverson

Show author details

Tom Beer: Affiliation:
IUGG Commission on Climatic and Environmental Change (CCEC)
Jianping Li: Affiliation:
Beijing Normal University
Keith Alverson: Affiliation:
UNEP International Environmental Technology Centre

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Summary

Seafood, whether from fisheries or aquaculture, has been an important food source for millennia and appearslikely to continue to be so for many decades to come. Traditional sources of seafood are under increasing pressure as the Anthropocene generates growing pressure on the world’s oceans. Marine ecosystems are feeling the direct pressure of fisheries and aquaculture, as well as the effects of pollution, eutrophication, coastal development, ocean acidification, climate change, extreme events, pathogens and the growing number and magnitude of marine industries – shipping, tourism, mining and energy generation. Nevertheless, there is hope. Both model based and empirical studies are showing sustainable options can be found. It is clear that integrated system-level understanding will be an important part of sustainable use of future ocean resources. As we navigate a changing ocean it is clear that human ingenuity will also be key to future sustainability and food security.

Type: Chapter
Information: Global Change and Future Earth
The Geoscience Perspective
, pp. 296 - 310

DOI: https://doi.org/10.1017/9781316761489.029 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2018

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References

Alder, J., Guénette, S., Beblow, J., Cheung, W., and Christensen, V. (2007) Ecosystem-based Global Fishing Policy Scenarios. Fisheries Centre Research Reports 15(7).Google Scholar

Allison, E.H., Perry, A.L., Badjeck, M.-C., Adger, W.N., Brown, K., Conway, D., Halls, A.S., Pilling, G.M., Reynolds, J.D., Andrew, N.L., and Dulvy, N.K. (2009) Vulnerability of national economies to the impacts of climate change on fisheries. Fish and Fisheries, 10, 173–196.Google Scholar

Apaza, M., and Figari, A. (1999) Mortandad de aves marinas durante El Niño 1997–98 en el litoral sur de San Juan de Marcona, Ica, Perú. Revista Peruana de Biología, Vol. Extraordinario, pp. 110–117.Google Scholar

Asif, M., and Muneer, T. (2007) Energy supply, its demand and security issues for developed and emerging economies. Renewable and Sustainable Energy Reviews, 11, 1388–1413.Google Scholar

Barange, M., Merino, G., Blanchard, J.L., Scholtens, J., Harle, J., Allison, E.H., Allen, J.I., Holt, J., and Jennings, S. (2014) Impacts of climate change on marine ecosystem production in societies dependent on fisheries. Nature Climate Change, 4, 211–216.Google Scholar

Barber, R.T., and Chavez, F.P. (1983) Biological consequences of El Niño. Science 222, 1203–1210.Google Scholar

Battisti, D.S., and Naylor, R.L. (2009) Historical warnings of future food insecurity with unprecedented seasonal heat. Science, 323, 240–244.CrossRef Google Scholar PubMed

Baines, J., Baines, T., and Quigley, R. (2015) The Social and Community Effects of Aquaculture: A Case Study of Southland Aquaculture. New Zealand Ministry for Primary Industries report.Google Scholar

Beldade, R., Holbrook, S.J., Schmitt, R.J., Planes, S., Malone, D., and Bernardi, G. (2012) Larger female fish contribute disproportionately more to self-replenishment. Proceedings of the Royal Society B, 279, 2116–2121.CrossRef Google Scholar PubMed

Bell, J.D., Ganachaud, A., Gehrke, P.C., Griffiths, S.P., Hobday, A.J., Hoegh-Guldberg, O., Johnson, J.E., Le Borgne, R., Lehodey, P., Lough, J.M., Matear, R.J., Pickering, T.D., Pratchett, M.S., Gupta, A.S., Senina, I., and Waycott, M. (2013) Mixed responses of tropical Pacific fisheries and aquaculture to climate change. Nature Climate Change, 3, 591–599.Google Scholar

Béné, C., Barange, M., Subasinghe, R., Pinstrup-Andersen, P., Merino, G., Hemre, G.-I., and Williams, M. (2015). Feeding 9 billion by 2050—putting fish back on the menu. Food Security, 7, 261–274.Google Scholar

Bradshaw, C.J.A., and Brook, B.W. (2014) Human population reduction is not a quick fix for environmental problems. Proceedings of the National Academy of Sciences, 111, 16610–16615.CrossRef Google Scholar

Branch, T.A., DeJoseph, B.M., Ray, L.J., and Wagner, C.A. (2013) Impacts of ocean acidification on marine seafood. Trends in Ecology & Evolution, 28, 178–186.Google Scholar

Brodie, J.E., Kroon, F.J., Schaffelke, B., Wolanski, E.C., Lewis, S.E., Devlin, M.J., Bohnet, I.C., Bainbridge, Z.T., Waterhouse, J., and Davis, A.M. (2012) Terrestrial pollutant runoff to the Great Barrier Reef: An update of issues, priorities and management responses. Marine Pollution Bulletin, 65, 81–100.Google Scholar

Brūchert, V., Currie, B., Peard, K.R., Lass, U., Endler, R., Dübecke, A., Julies, E., Leipe, T., and Zitzmann, S. 2006. Biogeochemical and physical control on shelf anoxia and water column hydrogen sulphide in the Benguel: A coastal upwelling off Namibia. In: Past and Present Water Column Anoxia, Neretin, L.N. (Ed.). Springer. pg. 161–193.Google Scholar

Burge, C.A., Eakin, C.M., Friedman, C.S., Froelich, B., Hershberger, P.K., Hofmann, E.E., Petes, L.E., Prager, K.C., Weil, E., Willis, B.L., Ford, S.E., and Harvell, C.D. (2014) Climate change influences on marine infectious diseases: Implications for management and society. Annual Reviews in Marine Science, 6, 249–77.Google Scholar

Buschmann, A.H., Varela, D.A., Hernández-González, M.C., Huovinen, P., (2008)Opportunities and challenges for the development of an integrated seaweed based aquaculture activity in Chile: Determining the physiological capabilities of Macrocystis and Gracilaria as biofilters. Journal of Applied Phycology, 20, 571–577.Google Scholar

Butterworth, A. (2016) A Review of the welfare impact on pinnipeds of plastic marine debris. Frontiers in Marine Science, 3,149. doi: 10.3389/fmars.2016.00149.CrossRef Google Scholar

Capone, D.G., and Hutchins, D.A. (2013) Microbial biogeochemistry of coastal upwelling regimes in a changing ocean. Nature Geoscience, 6, 711–717.Google Scholar

CBI (2015) CBI Trade Statistics: Fish and Seafood. CBI.Google Scholar

Chassot, E., Bonhommeau, S., Dulvy, N.K., Mélin, F., Watson, R., Gascuel, D. and Le Pape, O. (2010) Global marine primary production constrains fisheries catches. Ecology Letters, 13, 495–505.Google Scholar

Chern, W.S., Ishibashi, K., Taniguchi, K., and Tokoyama, Y. (2002) Analysis of food consumption behavior by Japanese households. ESA Working Paper No. 02–06.Google Scholar

Cheung, W.W.L., Lam, V.W.Y., Sarmiento, J.L., Kearney, K., Watson, R., Zeller, D., and Pauly, D. (2010). Large-scale redistribution of maximum fisheries catch potential in the global ocean under climate change. Global Change Biology, 16, 24–35.Google Scholar

Cheung, W.W.L., Dunne, J., Sarmiento, J.L., and Pauly, D. (2011) Integrating ecophysiology and plankton dynamics into projected maximum fisheries catch potential under climate change in the Northeast Atlantic. ICES Journal of Marine Science, 68, 1008–1018.CrossRef Google Scholar

Cheung, W.W.L., Sarmiento, J.L., Dunne, J., Frölicher, T.L., Lam, V.W.Y., Palomares, M.L.D., Watson, R., and Pauly, D. (2013) Shrinking of fishes exacerbates impacts of global ocean changes on marine ecosystems. Nature Climate Change, 3, 254–258.Google Scholar

Cheung, W.W.L., Jones, M.C., Reygondeau, G., Stock, C.A., Lam, V.W.Y., and Frölicher, T.L. (2016) Structural uncertainty in projecting global fisheries catches under climate change. Ecological Modelling, 325, 57–66.Google Scholar

Cheung, W.W.L., Reygondeau, G., and Frölicher, T.L. (2016) Large benefits to marine fisheries of meeting the 1.5 °C global warming target. Science, 354, 1591–1594.Google Scholar

Chimits, P. (1957) Tilapia in ancient Egypt. FAO Fisheries Bulletin, 10, 211–215.Google Scholar

Christensen, V. Walters, C.J., Ahrens, R., Alder, J., Buszowski, J., Christensen, L.B., Cheung, W.W.L., Dunne, J., Froese, R., Karpouzi, V., Kastner, K., Kearney, K., Lai, S., Lam, V., Palomares, M.L.D., Peters-Mason, A., Piroddi, C., Sarmiento, J.L., Steenbeek, J., Sumaila, R., Watson, R., Zeller, D. and Pauly, D. (2008) Models of the world’s large marine ecosystems. GEF/LME global project Promoting Ecosystem-based Approaches to Fisheries Conservation and Large Marine Ecosystems. IOC Technical Series No. 80. Paris, UNESCO.CrossRef Google Scholar

Cinner, J.E., Huchery, C., MacNeil1, M.A., Graham, N.A.J., McClanahan, T.R., Maina, J.,Maire, E., Kittinger, J.N., Hicks, C.C., Mora, C., Allison, E.H., D’Agata, S., Hoey, A., Feary, D.A., Crowder, L., Williams, I.D., Kulbicki, M., Vigliola, L., Wantiez, L., Edgar, G., Stuart-Smith, R.D., Sandin, S.A., Green, A.L., Hardt, M.J., Beger, M., Friedlander, A., Campbell, S.J., Holmes, K.E., Wilson, S.K., Brokovich, E., Brooks, A.J., Cruz-Motta, J.J., Booth, D.J., Chabanet, P., Gough, C., Tupper, M., Ferse, S.C.A., Sumaila, U.R., and Mouillot, D. (2016) Bright spots among the world’s coral reefs. Nature, 535, 416–419.Google Scholar

Costa-Pierce, B.A. (2002). Ecological Aquaculture: The evolution of the blue revolution. Oxford: Wiley-Blackwell. pp 1–29.CrossRef Google Scholar

Costello, C., Ovando, D., Hilborn, R., Gaines, S.D., Deschenes, O., Lester, S.E. (2012) Status and solutions for the world’s unassessed fisheries. Science, 338, 517–520.Google Scholar

Costello, C., Ovando, D., Clavelle, T., Strauss, C.K., Hilborn, R., Melnychuk, M.C., Branch, T.A., Gaines, S.D., Szuwalski, C.S., Cabral, R.B., Rader, D.N., and Leland, A. (2016) Global fishery prospects under contrasting management regimes. Proceedings of the National Academy of Sciences, 113, 5125–5129.Google Scholar

Cotner, J.B., and Biddanda, B.A. (2002) Small players, large role: Microbial influence on biogeochemical processes in pelagic aquatic ecosystems. Ecosystems, 5, 105–121.CrossRef Google Scholar

Crossland, C.J., Kremer, H.H., Lindeboom, H.J., Marshall Crossland, J.I., and Le Tissier, M.D.A. (2005) Coastal Fluxes in the Anthropocene: The Land-Ocean Interactions in the Coastal Zone Project of the International Geosphere-Biosphere Programme. Springer.Google Scholar

Dafforn, K.A., Glasby, T.M., Airoldi, L., Rivero, N.K., Mayer-Pinto, M., and Johnston, E.L. (2015). Marine urbanization: An ecological framework for designing multifunctional artificial structures. Frontiers in Ecology and the Environment, 13, 82–90.CrossRef Google Scholar

Derraik, J.G.B. (2002) The pollution of the marine environment by plastic debris: A review. Marine Pollution Bulletin, 44, 842–852.CrossRef Google Scholar PubMed

Dhar, A.K., Manna, S.K., and Allnutt, F.C.T. (2014) Viral vaccines for farmed finfish. Virus Disease, 25, 1–17.Google Scholar

Dodds, S. (1997) Towards a ‘science of sustainability’: Improving the way ecological economics understands human well-being. Ecological Economics, 23, 95–111.Google Scholar

Doney, S.C., Fabry, V.J., Feely, R.A., and Kleypas, J.A. (2009) Ocean acidification: The other CO₂ problem. Annual Reviews in Marine Science, 1, 169–92.Google Scholar

Doyen, L., Pereau, J.-C., and Cissé, A. (2016) The tragedy of open ecosystems. Dynamic Games and Applications. doi: 10.1007/s13235-016-0205-3.Google Scholar

Dugdale, R., Goering, J., Barber, R., Smith, R., and Packard, T. (1977) Denitrification and hydrogen sulfide in the Peru upwelling region during 1976. Deep Sea Research, 24, 601–608.Google Scholar

EIA (U.S. Energy Information Administration) (2016) Monthly Energy Review October 2016. Washington, DC: EIA.Google Scholar

Elliott, J., Deryng, D., Müller, C., Frieler, K., Konzmann, M., Gerten, D., Glotter, M., Flörke, M., Wada, Y., Best, N., Eisner, S., Feket, B.M., Folberth, C., Foster, I., Gosling, S.N., Haddeland, I., Khabarov, N., Ludwig, F., Masaki, Y., Olin, S., Rosenzweig, C., Ruane, A.C., Satoh, Y., Schmid, E., Stack, T., Tang, W., and Wisser, D. (2014). Constraints and potentials of future irrigation water availability on agricultural production under climate change. Proceedings of the National Academy of Sciences, 111, 3239–3244.CrossRef Google Scholar PubMed

EJF (2016) The EU IUU Regulation: Building on success, EU progress in the global fight against illegal fishing. Report by The Environmental Justice Foundation (EJF), Oceana, The Pew Charitable Trusts and WWF.Google Scholar

Ekstrom, J.A., Suatoni, L., Cooley, S.R., Pendleton, L.H., Waldbusser, G.G., Cinner, J.E., Ritter, J., Langdon, C., van Hooidonk, R., Gledhill, D., Wellman, K., Beck, M.W., Brander, L.M., Rittschof, D., Doherty, C., Edwards, P.E.T., and Portela, R. (2015) Vulnerability and adaptation of US shellfisheries to ocean acidification. Nature Climate Change, 5, 207–214.Google Scholar

Essington, T.E., Beaudreau, A.H., and Wiedenmann, J. (2006) Fishing through marine food webs. Proceedings of the National Academy of Sciences, 103, 3171–3175.Google Scholar

Elliot, J., Deryng, D., Müller, C., Frieler, K., Konzmann, M., Gerten, D., Glotter, M., Flörke, M., Wada, Y., Best, N., Eisner, S., Fekete, B.M., Folberth, C., Foster, I., Gosling, S.N., Haddeland, I., Khabarov, N., Ludwig, F., Masaki, Y., Olin, S., Rosenzweig, C., Ruane, A.C., Satoh, Y., Schmid, E., Stacke, T., Tang, Q., and Wisser, D. (2014) Constraints and potentials of future irrigation water availability on agricultural production under climate change. Proceedings of the National Academy of Sciences, 111, 3239–3244.Google Scholar

Evans, K., Bax, N., and Smith, D.C. (2017) Australia State of the Environment 2016: Marine Environment, Independent Report to the Australian Government Minister for the Environment and Energy. Canberra: Australian Government Department of the Environment and Energy.Google Scholar

FAO (2016) The State of World Fisheries and Aquaculture 2016. Contributing to Food Security and Nutrition for All. Rome: FAO.Google Scholar

FAO, IFAD and WFP (2014) The State of Food Insecurity in the World 2014. Strengthening the Enabling Environment for Food Security and Nutrition. Rome: FAO.Google Scholar

Fogarty, M.J., Rosenberg, A.A, Cooper, A.B., Dickey-Collas, M., Fulton, E.A., Gutiérrez, N.L., Hyde, K.J.W., Kleisner, K.M., Kristiansen, T., Longo, C., Minte-Vera, C.V., Minto, C., Mosqueira, I., Osio, G.C., Ovando, D., Selig, E.R., Thorson, J.T., and Yimin, Y (2016) Fishery production potential of large marine ecosystems: A prototype analysis. Environmental Development, 17, 211–219.Google Scholar

Francis, C.D., and Barber, J.R. (2013) A framework for understanding noise impacts on wildlife: An urgent conservation priority. Frontiers in Ecology and the Environment, 11, 305–313.Google Scholar

Fujita, M., Yamasaki, S., Katagiri, C., Oshiro, I., Sano, K., Kurozumi, T., Sugawara, H., Kunikita, D., Matsuzaki, H., Kano, A., Okumura, T., Sone, T., Fujita, H., Kobayashi, S., Naruse, T., Kondo, M., Matsu’ura, S., Suwa, G., and Kaifu, Y. (2016) Advanced maritime adaptation in the western Pacific coastal region extends back to 35,000–30,000 years before present. Proceedings of the National Academy of Sciences, 113, 11184–11189.Google Scholar

Fulton, E.A., and Gorton, R. (2014) Adaptive Futures for SE Australian Fisheries & Aquaculture: Climate Adaptation Simulations. Hobart: CSIRO.Google Scholar

Garcia, S.M., Kolding, J., Rice, J., Rochet, M.J., Zhou, S., Arimoto, T., Beyer, J.E., Borges, L., Bundy, A., Dunn, D., Fulton, E.A., Hall, M., Heino, M., Law, R., Makino, M., Rijnsdorp, A.D., Simard, F., and Smith, A.D.M. (2012) Reconsidering the consequences of selective fisheries. Science, 335, 1045–1047.CrossRef Google Scholar PubMed

Gerland, P., Raftery, A.E., Ševčíková, H., Li, N., Gu, D., Spoorenberg, T., Alkema, L., Fosdick, B.K., Chunn, J., Lalic, N., Bay, G., Buettner, T., Heilig, G.K., and Wilmoth, J. (2014) World population stabilization unlikely this century. Science, 346, 234–237.Google Scholar

Goldburg, R.J., Elliott, M.S., and Naylor, R.L. (2001) Marine Aquaculture in the United States: Environmental Impacts and Policy Options. Wasington, DC: Pew.Google Scholar

Golden, C.D., Allison, E.H., Cheung, W.W.L., Dey, M.M., Halpern, B.S., McCauley, D.J., Smith, M., Vaitla, B., Zeller, D., and Myers, S.S. (2016) Fall in fish catch threatens human health. Nature, 534, 317–320.Google Scholar

Gornall, J., Betts, R., Burke, E., Clark, R., Camp, J., Willett, K., and Wiltshire, A. (2010) Implications of climate change for agricultural productivity in the early twenty-first century. Philosophical Transactions of the Royal Society B, 365, 2973–2989.Google Scholar

Graham, H.W., and Edwards, R.L. (1962) The world biomass of marine fishes. In: Fish in Nutrition, Heen, E. and Kreuzer, R., (eds). London: Fishing News (books), pp. 3–8.Google Scholar

Griffith, G.P., Richardson, A.J., Fulton, E.A., and Gorton, R. (2012) Evaluating the interaction effects of ocean warming, ocean acidification and fisheries. Conservation Biology, 6, 1145–1152.Google Scholar

Griffith, G.P., and Fulton, E.A. (2014) New approaches to simulating the complex interaction effects of multiple human impacts on the marine environment. ICES Journal of Marine Science, 71, 764–774.Google Scholar

Gulland, J.A. (1970) Summary In: The Fish Resources of the Ocean, Gulland, J.A. (ed). FAO Fisheries Technical Paper 97.Google Scholar

Halpern, B.S., Walbridge, S., Selkoe, K.A., Kappel, C.V., Micheli, F., D’Agrosa, C., Bruno, J.F., Casey, K.S., Ebert, C., Fox, H.E., Fujita, R., Heinemann, D., Lenihan, H.S., Madin, E.M.P., Perry, M.T., Selig, E.R., Spalding, M., Steneck, R., and Watson, R., (2008) A global map of human impact on marine ecosystems. Science, 319, 948–952.Google Scholar

Halpern, B.S., Frazier, M., Potapenko, J., Casey, K.S., Koenig, K., Longo, C., Stewart Lowndes, J., Rockwood, R.C., Selig, E.R., Selkoe, K.A., and Walbridge, S. (2015) Spatial and temporal changes in cumulative human impacts on the world’s ocean. Nature, 6, 1–7.Google Scholar

Harvell, C.D., Mitchell, C.E., Ward, J.R., Altizer, S., Dobson, A.P., Ostfeld, R.S., and Samuel, M.D. (2002) Climate warming and disease risks for terrestrial and marine biota. Science, 296, 2158–2162.Google Scholar

Hildebrand, J.A. (2009) Anthropogenic and natural sources of ambient noise in the ocean. Marine Ecology Progress Series, 395, 5–20.Google Scholar

Hobday, A.J., and Pecl, G.T. (2014) Identification of global marine hotspots: Sentinels for change and vanguards for adaptation action. Reviews in Fish Biology and Fisheries, 24, 415–425.Google Scholar

Hobday, A.J., Alexander, L.V., Perkins, S.E., Smale, D.E., Straub, S.C., Oliver, E.C.J., Benthuysen, J.A., Burrows, M.T., Donat, M.G., Feng, M., Holbrook, N.J., Moore, P.J., Scannell, H.A., Gupta, A.S., and Wernberg, T. 2016. A hierarchical approach to defining marine heatwaves. Progress in Oceanography, 141, 227–238.Google Scholar

Hoegh-Guldberg, O., and Bruno, J.F. (2010) The impact of climate change on the world’s marine ecosystems. Science, 328, 1523–1528.Google Scholar

Hönisch, B., Ridgwell, A., Schmidt, D.N., Thomas, E., Gibbs, S.J., Sluijs, A., Zeebe, R., Kump, L., Martindale, R.C., Greene, S.E., Kiessling, W., Ries, J., Zachos, J.C., Royer, D.L., Barker, S., Marchitto, T.M. Jr., Moyer, R., Pelejero, C., Ziveri, P., Foster, G.L., Williams, B., 2012. The geological record of ocean acidification. Science, 335, 1058–1063.Google Scholar

Hu, Y., Shang, H., Tong, H., Nehlich, O., Liu, W., Zhao, C., Yu, J., Wang, C., Trinkaus, E., and Richards, M.P. (2009) Stable isotope dietary analysis of the Tianyuan 1 early modern human. Proceedings of the National Academy of Sciences, 107, 10971–10974.Google Scholar

IPCC. (2013) Summary for Policymakers. In: 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., Tignor, M., Allen, S.K., Boschung, J., Nauels, A., Xia, Y., Bex, V. and Midgley, P.M. (eds). Cambridge: Cambridge University Press.Google Scholar

Irigoien, X., Klevjer, T.A., Røstad, A., Martinez, U., Boyra, G., Acuña, J.L., Bode, A., Echevarria, F., Gonzalez-Gordillo, J.I., Hernandez-Leon, S., Agusti, S., Aksnes, D.L., Duarte, C.M., and Kaartvedt, S. (2014) Large mesopelagic fishes biomass and trophic efficiency in the open ocean. Nature Communications, 5, 1–10.Google Scholar

Jambeck, J.R., Geyer, R., Wilcox, C., Siegler, T.R., Perryman, M., Andrady, A., Narayan, R., and Law, K.L. (2015) Plastic waste inputs from land into the ocean. Science, 347, 768–771.Google Scholar

Jennings, S., Mélin, F., Blanchard, J.L., Forster, R.M., Dulvy, N.K., and Wilson, R.W. (2008) Global-scale predictions of community and ecosystem properties from simple ecological theory. Proceedings of the Royal Society B Biological Sciences, 275, 1375–1383.Google Scholar

Jennings, S., and Brander, K. (2010) Predicting the effects of climate change on marine communities and the consequences for fisheries. Journal of Marine Systems, 79, 418–426.Google Scholar

Jennings, S., and Collingridge, K. (2015) Predicting consumer biomass, size-structure, production, catch potential, responses to fishing and associated uncertainties in the world’s marine ecosystems. PLoS One, 10, e0133794.Google Scholar

Jones, M.C., and Cheung, W.W.L. (2015) Multi-model ensemble projections of climate change effects on global marine biodiversity. ICES Journal of Marine Science, 72, 741–752.Google Scholar

Koslow, J.A., and Davison, P.C. (2016) Productivity and biomass of fishes in the California Current Large Marine Ecosystem: Comparison of fishery-dependent and –independent time series. Environmental Development, 17, 23–32.Google Scholar

Kunc, H.P., McLaughlin, K.E., and Schmidt, R. (2016) Aquatic noise pollution: Implications for individuals, populations, and ecosystems. Proceedings of the Royal Society B, 283, 20160839.Google Scholar

Leadbitter, D., Benguerel, R. (2014). Sustainable tuna–can the marketplace improve fishery management? Business Strategy and the Environment, 23, 417–432.Google Scholar

Ling, S.D., Johnson, C.R., Ridgway, K., Hobday, A.J., and Haddon, M. (2009). Climate‐driven range extension of a sea urchin: Inferring future trends by analysis of recent population dynamics. Global Change Biology, 15, 719–731.Google Scholar

Lönnstedt, O.M., and Eklöv, P. (2016) Environmentally relevant concentrations of microplastic particles influence larval fish ecology. Science, 352, 1213–1216.Google Scholar

Maeda, H. (2015) The Past, Present and Future of the Ocean Engineering Activities: Maritime Technology and Engineering – Soares, Guedes & Santos, (eds). Taylor & Francis Group, London. pgs 3–9.Google Scholar

McCauley, D.J., Pinsky, M.L., Palumbi, S.R., Estes, J.A., Joyce, F.H., and Warner, R.R. (2015) Marine defaunation: Animal loss in the global ocean. Science, 347, 1255641.Google Scholar

Merino, G., Barange, M., Blanchard, J.L., Harle, J., Holmes, R., Allen, I., Allison, E.H., Badjeck, M.C., Dulvy, N.K., Holt, J., Jennings, S., Mullon, C., Rodwell, L.D. (2012) Can marine fisheries and aquaculture meet fish demand from a growing human population in a changing climate? Global Environmental Change, 22, 795–806.Google Scholar

Molinos, J.G., Halpern, B.S., Schoeman, D.S., Brown, C.J., Kiessling, W., Moore, P.J., Pandolfi, J.M., Poloczanska, E.S., Richardson, A.J., and Burrows, M.T. (2015) Climate velocity and the future global redistribution of marine biodiversity. Nature Climate Change. doi: 10.1038/nclimate2769.Google Scholar

Murphy, E.J., Cavanagh, R.D., Drinkwater, K.F., Grant, S.M., Heymans, J.J., Hofmann, E.E., Hunt, G.L. Jr., and Johnston, N.M. (2016) Understanding the structure and functioning of polar pelagic ecosystems to predict the impacts of change. Proceedings of the Royal Society B, 283, 20161646.Google Scholar

Neori, A., Chopin, T., Troell, M., Buschmann, A., Kraemer, G.P., Halling, C., Shpigel, M., and Yarish, C. (2004). Integrated aquaculture: Rationale, evolution and state of the art emphasizing seaweed biofiltration in modern mariculture. Aquaculture, 231, 361–391.Google Scholar

Nicklisch, S.C.T., Rees, S.D., McGrath, A.P., Gökirmak, T., Bonito, L.T., Vermeer, L.M., Cregger, C., Loewen, G., Sandin, S., Chang, G., and Hamdoun, A. (2016) Global marine pollutants inhibit P-glycoprotein: Environmental levels, inhibitory effects, and cocrystal structure. Science Advances, 2, e1600001.Google Scholar

NRC (National Research Council)(2014) Responding to Oil Spills in the U.S. Arctic Marine Environment. Washington, DC: The National Academies Press.Google Scholar

O’Connor, S., Ono, R., and Clarkson, C. (2011) Pelagic fishing at 42,000 years before the present and the maritime skills of modern humans. Science, 334, 1117–1121.Google Scholar

Parkinson, C. (2014) Global sea ice coverage from satellite data: Annual cycle and 35-yr trends. Journal of Climate, 27, 9377–9382.Google Scholar

Pauly, D., Christensen, V., Dalsgaard, J., Froese, R., and Torres, F. Jr. (1998) Fishing down marine food webs. Science, 279, 860–863.Google Scholar

Pecl, G.T., Araújo, M.B., Bell, J.D., Blanchard, J., Bonebrake, T.C., Chen, I-C., Clark, T.D., Colwell, R.K., Danielsen, F., Evengård, B., Falconi, L., Ferrier, S., Frusher, S., Garcia, R.A., Griffis, R.B., Hobday, A.J., Janion-Scheepers, C., Jarzyna, M.A., Jennings, S., Lenoir, J., Linnetved, H.I., Martin, V.Y., McCormack, P.C., McDonald, J., Mitchell, N.J., Mustonen, T., Pandolfi, J.M., Pettorelli, N., Popova, E., Robinson, S.A., Scheffers, B.R., Shaw, J.D., Sorte, C.J.B., Strugnell, J.M., Sunday, J.M., Tuanmu, M.-N., Vergés, A., Villanueva, C., Wernberg, T., Wapstra, E., and Williams, S.E. (2017) Biodiversity redistribution under climate change: Impacts on ecosystems and human well-being. Science, 355, eaai9214.Google Scholar

Perkins, S.E., Alexander, L.V., and Nairn, J., (2012) Increasing frequency, intensity and duration of observed global heat waves and warm spells. Geophysical Research Letters, 39, 20. http://dx.doi.org/10.1029/2012GL053361.Google Scholar

Plagányi, É.E., van Putten, I., Thébaud, O., Hobday, A.J., Innes, J., Lim-Camacho, J., Norman-Ló pez, A., Bustamante, R.H., Farmery, A., Fleming, A., Frusher, S., Green, B., Hoshino, E., Jennings, S., Pecl, G., Pascoe, S., Schrobback, P., and Thomas, L. (2014) A quantitative metric to identify critical elements within seafood supply networks. PLoS ONE, 9: e91833. doi: 10.1371/journal.pone.0091833.CrossRef Google Scholar PubMed

Poloczanska, E.S., Brown, C.J., Sydeman, W.J., Kiessling, W., Schoeman, D.S., Moore, P.J., Brander, K., Bruno, J.F., Buckley, L.B., Burrows, M.T., Duarte, C.M., Halpern, B.S., Holding, J., Kappel, C.V., O’Connor, M.I., Pandolfi, J.M., Parmesan, C., Schwing, F., Thompson, S.A., and Richardson, A.J. (2013) Global imprint of climate change on marine life. Nature Climate Change, 3, 919–925.Google Scholar

Popper, A.N., and Hastings, M.C. (2009) The effects of human-generated sound on fish. Integrative Zoology, 4, 43–52.Google Scholar

Radcliffe, W. (1921) Fishing from the Earliest Times. London: Murray.Google Scholar

Rakocy, J.E. (2012) Aquaponics – Integrating fish and plant culture. In: Aquaculture Production Systems, Tidwell, J. (Ed.). John Wiley & Sons.Google Scholar

Rammelt, C.F., and van Schie, M.. (2016) Ecology and equity in global fisheries: Modelling policy options using theoretical distributions. Ecological Modelling, 337, 107–122.Google Scholar

Revollo-Fernández, D., Aguilar-Ibarra, A., Micheli, F., and Sáenz-Arroyo, A. (2016) Exploring the role of gender in common-pool resource extraction: Evidence from laboratory and field experiments in fisheries. Applied Economics Letters, 23, 912–920.Google Scholar

REN21 (Renewable Energy Policy Network for the 21st Century) (2015) Renewables 2015 Global Status Report. Paris: REN21 Secretariat.Google Scholar

Ricker, W.E. (1969) Food from the sea. In: Resources and Man, the report of the Committee on Resources and Man to the U.S. National Academy of Sciences. San Francisco: W.H. Freeman,Google Scholar

Roberts, S.M., Grattan, L.M., Toben, A.C., Ausherman, C., Trainer, V.L., Tracy, K., Morris, J.G. Jr. (2016) Perception of risk for domoic acid related health problems: A cross-cultural study. Harmful Algae, 57, 39–44.Google Scholar

Rosenzweig, C., Elliott, J., Deryng, D., Ruane, A.C., Müller, C., Arneth, A., Boote, K.J., Folberth, C., Glotter, M., Khabarov, N., Neumann, K., Piontek, F., Pugh, T.A.M., Schmid, E., Stehfest, E., Yang, H., and Jones, J.W. (2014) Assessing agricultural risks of climate change in the 21st century in a global gridded crop model intercomparison. Proceedings of the National Academy of Sciences, 111, 3268–3273.Google Scholar

Ryther, J. (1969) Photosynthesis and fish production in the sea. Science, 166, 72–76.CrossRef Google Scholar PubMed

Sabine, C.L., Feely, R.A., Gruber, N., Key, R.M., Lee, K., Bullister, J.L., Wanninkhof, R., Wong, C.S., Wallace, D.W.R., Tilbrook, B., Millero, F.J., Peng, T.-H., Kozyr, A., Ono, T., and Rios, A.F. (2004) The oceanic sink for anthropogenic CO₂. Science, 305, 367–71.Google Scholar

Schaefer, M.B. (1965) The potential harvest of the sea. Transactions of the American Fisheries Society, 94, 123–128.Google Scholar

Sethi, S.A., Branch, T.A., and Watson, R. (2010) Global fishery development patterns are driven by profit but not trophic level. Proceedings of the National Academy of Sciences, 107, 12163–12167.Google Scholar

Shepherd, C.J., and Jackson, A.J. (2013). Global fishmeal and fish-oil supply: Inputs, outputs and marketsa. Journal of Fish Biology, 83, 1046–1066.Google Scholar

Skretting, . (2015). Annual Sustainability Report 2015. Skretting Australia. Cambridge Tasmania, Skretting. 24 pages.Google Scholar

Smith, A.D.M., Smith, D.C., Haddon, M., Knuckey, I., Sainsbury, K.J., and Sloan, S. (2014) Implementing harvest strategies in Australia: 5 years on. ICES Journal of Marine Science, 71, 195–203.Google Scholar

Sofonia, J.J., and Anthony, K.R.N. (2008) High-sediment tolerance in the reef coral Turbinaria mesenterina from the inner Great Barrier Reef lagoon (Australia). Estuarine, Coastal and Shelf Science, 78, 748–752.Google Scholar

Sunday, J.M., Pecl, G.T., Frusher, S., Hobday, A.J., Hill, N., Holbrook, N.J., Edgar, G.J., Stuart-Smith, R., Barrett, N., Wernberg, T., Watson, R.A., Smale, D.A., Fulton, E.A., Slawinski, D., Feng, M., Radford, B.T., Thompson, P.A., and Bates, A.E. (2015). Species traits and climate velocity explain geographic range shifts in an ocean-warming hotspot. Ecology Letters, 18, 944–953.Google Scholar

Thums, M., Whiting, S.D., Reisser, J., Pendoley, K.L., Pattiaratchi, C.B., Proietti, M., Hetzel, Y., Fisher, R., and Meekan, M.G. (2016) Artificial light on water attracts turtle hatchlings during their near shore transit. Royal Soceity Open Science, 3, 160142.Google Scholar

Troell, M., Joyce, A., Chopin, T., Neori, A., Buschmann, A.H., and Fang, J.G. (2009). Ecological engineering in aquaculture—potential for integrated multi-trophic aquaculture (IMTA) in marine offshore systems. Aquaculture, 297, 1–9.Google Scholar

Van Dover, C.L. (2014) Impacts of anthropogenic disturbances at deep-sea hydrothermal vent ecosystems: A review. Marine Environmental Research, 102, 59–72.Google Scholar

Whitmee, S., Haines, A., Beyrer, C., Boltz, F., Capon, A.G., de Souza Dias, B.F., Ezeh, A., Frumkin, H., Gong, P., Head, P., Horton, R., Mace, G.M., Marten, R., Myers, S.S., Nishtar, S., Osofsky, S.A., Pattanayak, S.K., Pongsiri, M.J., Romanelli, C., Soucat, A., Vega, J., and Yach, D. (2015) Safeguarding human health in the Anthropocene epoch: Report of The Rockefeller Foundation–Lancet Commission on planetary health. Lancet, 386, 1973–2028.Google Scholar

Wilcox, C., Van Sebille, E., and Hardesty, B.D. (2015) Threat of plastic pollution to seabirds is global, pervasive, and increasing. Proceedings of the National Academy of Sciences, 112, 11899–11904.Google Scholar

Wilson, R.W., Millero, F.J., Taylor, J.R., Walsh, P.J., Christensen, V., Jennings, S., and Grosell, M. (2009) Contribution of fish to the marine inorganic carbon cycle. Science, 323, 359–362.Google Scholar

World Bank (2013) Fish to 2030: Prospects for Fisheries and Aquaculture. Washington, DC: World Bank.Google Scholar

World Bank (2014) Reducing Disease Risk in Aquaculture. Washington, DC: World Bank.Google Scholar

World Bank (2016) Global Monitoring Report 2015/2016: Development Goals in an Era of Demographic Change. Washington, DC: World Bank.Google Scholar

Worm, B., Hilborn, R., Baum, J., Branch, T., Collie, J., Costello, C., Fogarty, M., Fulton, E.A., Hutchings, J., Jennings, S., Jensen, O., Lotze, H., Mace, P., McClanahan, T., Minto, C., Palumbi, S., Parma, A., Ricard, D., Rosenberg, A., Watson, R., and Zeller, D. (2009) Rebuilding global fisheries. Science, 325, 578–585.Google Scholar

Yool, A., Popova, E.E., and Coward, A.C. (2015) Future change in ocean productivity: Is the Arctic the new Atlantic? Journal of Geophysical Research, 120, 7771–7790.Google Scholar

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22 - Marine Systems, Food Security, and Future Earth

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