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International Environmental Law in the Anthropocene: Towards a Purposive System of Multilateral Environmental Agreements

Published online by Cambridge University Press:  24 June 2013

Rakhyun E. Kim
Affiliation:
Fenner School of Environment and Society, The Australian National University, Canberra (Australia). Email: [email protected].
Klaus Bosselmann
Affiliation:
Faculty of Law, University of Auckland (New Zealand). Email: [email protected].

Abstract

Our point of analytical departure is that the state of the global environment is deteriorating despite the accumulating body of international environmental law. By drawing on the recent Earth system science concept of interlinked planetary boundaries, this article makes a case for a goal-oriented, purposive system of multilateral environmental agreements. The notion of ‘goal’ is used here to mean a single, legally binding, superior norm – a grundnorm – that gives all international regimes and organizations a shared purpose to which their specific objectives must contribute. A bird’s eye view of the international environmental law system reveals how the absence of a unifying goal has created a condition that is conducive to environmental problem shifting rather than problem solving. We argue that a clearly agreed goal would provide the legal system with a point of reference for legal reasoning and interpretation, thereby enhancing institutional coherence across Earth’s subsystems. To this end, this article concludes by observing that the protection of the integrity of Earth’s life-support system has emerged as a common denominator among international environmental law instruments. Accordingly, we suggest that this notion is a strong candidate for the overarching goal of international environmental law.

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Articles
Copyright
Copyright © Cambridge University Press 2013 

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References

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79 UNFCCC, ibid., Art. 7(2)(1).

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88 Rio de Janeiro (Brazil), 5 Jun. 1992, in force 29 Dec. 1993, available at: http://www.cbd.int.

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102 UNCLOS, ibid., Art. 195.

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111 Decision 2/CP.7, The Marrakesh Accords, UN Doc. FCCC/CP/2001/13/Add.1, 21 Jan. 2002.

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116 For general discussions on the legal dimension of ocean fertilization, see, e.g., Freestone, D. & Rayfuse, R., ‘Ocean Iron Fertilization and International Law’ (2008) 364 Marine Ecology Progress Series, pp. 227–33Google Scholar; Abate, R.S. & Greenlee, A.B., ‘Sowing Seeds Uncertain: Ocean Iron Fertilization, Climate Change, and the International Environmental Law Framework’ (2010) 27(2) Pace Environmental Law Review, pp. 555–98Google Scholar; Bertram, C., ‘Ocean Iron Fertilization in the Context of the Kyoto Protocol and the Post-Kyoto Process’ (2010) 38(2) Energy Policy, pp. 1130–9Google Scholar; VanderZwaag, D.L., ‘Ocean Dumping and Fertilization in the Antarctic: Tangled Legal Currents, Sea of Challenges’, in Berkman, P.A., Lang, M.A., Walton, D.W.H. & Young, O.R. (eds), Science Diplomacy: Antarctica, Science, and the Governance of International Spaces (Smithsonian Institution Scholarly Press, 2011), pp. 245–52Google Scholar; Warner, R., ‘Marine Snow Storms: Assessing the Environmental Risks of Ocean Fertilization’ (2009) 3(4) Carbon and Climate Law Review, pp. 426–36.Google Scholar

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118 Protocol to the Convention on the Prevention of Marine Pollution by Dumping of Wastes and Other Matter, 1972, London (United Kingdom), 7 Nov. 1996, in force 24 Mar. 2006, available at: http://www.imo.org.

119 See, e.g., Zeebe, R.E., Zachos, J.C., Caldeira, K. & Tyrrell, T., ‘Carbon Emissions and Acidification’, (2008) 321(5885) Science, pp. 51–2.Google Scholar

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124 UNFCCC, n. 77 above, Art. 4(1)(d); Kyoto Protocol, n. 121 above, Art. 2(1)(a)(ii).

125 Ocean iron fertilization could, in theory, reduce the rate of increase of atmospheric carbon dioxide, and hence the rate of ocean acidification in the upper ocean. However, if deployed on a climatically significant scale, this approach would relocate acidification from the upper ocean to mid- or deep water, where biota may be more sensitive to pH changes: Cao, L. & Caldeira, K., ‘Can Ocean Iron Fertilization Mitigate Ocean Acidification?’ (2010) 99(1–2) Climatic Change, pp. 303–11Google Scholar; Caldeira, K. & Duffy, P.B., ‘The Role of the Southern Ocean in Uptake and Storage of Anthropogenic Carbon Dioxide’ (2000) 287(5453) Science, pp. 620–2Google Scholar; Williamson, P. & Turley, C., ‘Ocean Acidification in a Geoengineering Context’ (2012) 370(1974) Philosophical Transactions of the Royal Society A, pp. 4317–42.Google Scholar

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128 Proelss, A. & Krivickaite, M., ‘Marine Biodiversity and Climate Change’ (2009) 3(4) Carbon and Climate Law Review, pp. 437–45, at 438.Google Scholar

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132 Ibid.

133 See, e.g., Folke, C. et al. et al., ‘Reconnecting to the Biosphere’ (2011) 40(7) Ambio, pp. 719–38.Google Scholar

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141 Report of the Study Group of the International Law Commission (ILC), Fragmentation of International Law: Difficulties Arising from the Diversification and Expansion of International Law, UN Doc. A/CN.4/L.682, 13 Apr. 2006.

142 Vienna (Austria), 23 May 1969, in force 27 Jan. 1980, available at: http://untreaty.un.org/ilc/texts/instruments.

143 VCLT, ibid., Art. 31(3)(c).

144 We note that the formulation of Article 31(3)(c) has been criticized as unclear both in its substantive and temporal scope and its normative force. See, e.g., Linderfalk, U., ‘Who Are “The Parties”? Article 31, Paragraph 3(c) of the 1969 Vienna Convention and the “Principle of Systemic Integration” Revisited’ (2008) 55(3) Netherlands International Law Review, pp. 343–64Google Scholar; McLachlan, C., ‘The Principle of Systemic Integration and Article 31(3)(c) of the Vienna Convention’ (2005) 54(2) International and Comparative Law Quarterly, pp. 279319Google Scholar; Tzevelekos, V.P., ‘The Use of Article 31(3)(c) of the VCLT in the Case Law of the ECtHR: An Effective Anti-Fragmentation Tool or a Selective Loophole for the Reinforcement of Human Rights Teleology?’ (2010) 31 Michigan Journal of International Law, pp. 621–90.Google Scholar

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148 Steiner, Kimball & Scanlon, n. 21 above.

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152 GLWQA, ibid., Art. II.

153 Canberra (Australia), 20 May 1980, in force 7 Apr. 1982, available at: http://www.ccamlr.org.

154 Ibid., Preamble.

155 See, e.g., Protocol Concerning Specially Protected Areas and Biological Diversity in the Mediterranean, Barcelona (Spain), 10 Jun. 1995, in force 12 Dec. 1999, available at: http://eur-lex.europa.eu.

156 N. 65 above.

157 N. 66 above.

158 Agenda 21: Programme of Action for Sustainable Development, UN Doc. A/CONF.151/26, 14 Jun. 1992, available at: http://www.unep.org.

159 IUCN Environmental Law Programme, Draft International Covenant on Environment and Development. Fourth edition: Updated Text (IUCN Environmental Law Programme & International Council of Environmental Law, 2010), available at: http://www.iucn.org/about/work/programmes/environmental_law/elp_resources/elp_res_publications/?uPubsID=4197.

160 The Earth Charter Initiative, The Earth Charter (The Earth Charter Initiative, 2000), available at: http://www.earthcharterinaction.org.

161 Report of the World Summit on Sustainable Development, Plan of Implementation of the World Summit on Sustainable Development, UN Doc. A/CONF.199/20, 4 Sep. 2002, available at: http://www.johannesburgsummit.org.

162 N. 30 above.

163 Rio Declaration, n. 66 above, Preamble.

164 Rio Declaration, ibid., Principle 7.

165 World Charter for Nature, n. 65 above, Principle 4.

166 Earth Charter, n. 160 above, Principle 5.

167 Draft International Covenant, n. 159 above, Art. 2. This was reflected in the text upon consulting with the drafters of the Earth Charter to ensure consistency among the principles set forth in both texts.

168 Bosselmann, n. 32 above, at pp. 162–74.

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172 Griggs et al., n. 170 above.

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