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Assessing progress towards global marine protection targets: shortfalls in information and action

Published online by Cambridge University Press:  10 July 2008

Louisa J. Wood*
Affiliation:
Sea Around Us Project, Fisheries Centre, Aquatic Ecosystems Research Laboratory, 2202 Main Mall, Vancouver, BC, Canada, V6T 1Z4.
Lucy Fish
Affiliation:
United Nations Environment Programme–World Conservation Monitoring Centre, 219 Huntingdon Road, Cambridge, CB3 0DL, UK.
Josh Laughren
Affiliation:
WWF-Canada, 245 Eglinton Avenue East, Suite 410, Toronto, ON, Canada, M4P 3J1.
Daniel Pauly
Affiliation:
Sea Around Us Project, Fisheries Centre, Aquatic Ecosystems Research Laboratory, 2202 Main Mall, Vancouver, BC, Canada, V6T 1Z4.
*
Sea Around Us Project, Fisheries Centre, Aquatic Ecosystems Research Laboratory, 2202 Main Mall, Vancouver, BC, Canada, V6T 1Z4. E-mail [email protected]
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Abstract

Current global marine protection targets aim to protect 10–30% of marine habitats within the next 3–5 years. However, these targets were adopted without prior assessment of their achievability. Moreover, ability to monitor progress towards such targets has been constrained by a lack of robust data on marine protected areas. Here we present the results of the first explicitly marine-focused, global assessment of protected areas in relation to global marine protection targets. Approximately 2.35 million km2, 0.65% of the world's oceans and 1.6% of the total marine area within Exclusive Economic Zones, are currently protected. Only 0.08% of the world's oceans, and 0.2% of the total marine area under national jurisdiction is no-take. The global distribution of protected areas is both uneven and unrepresentative at multiple scales, and only half of the world's marine protected areas are part of a coherent network. Since 1984 the spatial extent of marine area protected globally has grown at an annual rate of 4.6%, at which even the most modest target is unlikely to be met for at least several decades rather than within the coming decade. These results validate concerns over the relevance and utility of broad conservation targets. However, given the low level of protection for marine ecosystems, a more immediate global concern is the need for a rapid increase in marine protected area coverage. In this case, the process of comparing targets to their expected achievement dates may help to mobilize support for the policy shifts and increased resources needed to improve the current level of marine protection.

Type
Reviews
Copyright
Copyright © Fauna & Flora International 2008

Introduction

Marine protected areas are increasingly viewed as an important management tool within a suite of policy alternatives to reduce, prevent and/or reverse, ongoing (and in some cases rapid) declines in marine biodiversity and fisheries (Agardy, Reference Agardy1994; Pauly et al., Reference Pauly, Christensen, Guénette, Pitcher, Sumaila and Walters2002; Hoyt, Reference Hoyt2005; Roberts et al., Reference Roberts, Hawkins and Gell2005). This has led to their inclusion in three recent global marine protection targets. The 2002 Plan of Implementation of the World Summit on Sustainable Development committed to establishing a representative global network of marine protected areas by 2012 (United Nations, 2002, Section IV, paragraph 32(c)). At the Vth World Parks Congress in 2003 the recommendation was made to ‘[g]reatly increase the marine and coastal area managed in marine protected areas by 2012; these networks should include strictly protected areas that amount to at least 20–30% of each habitat'. Most recently, at the 8th Ordinary Conference of the Parties to the Convention on Biological Diversity (CBD) in 2006, a target that ‘at least 10% of each of the world's ecological regions [including marine and coastal be] effectively conserved [by 2010]' was adopted (CBD, 2006). However, these targets were adopted with limited prior knowledge of the existing global marine protected area network (the most recent global assessment is > 10 years old and had data limitations; Kelleher et al., Reference Kelleher, Bleakey and Wells1995), and without any assessment of the feasibility of the targets.

The World Database on Protected Areas (WDPA; UNEP-WCMC, 2004) is a global data source that has been widely used for monitoring marine protected areas. However, its coverage of marine protected areas has significant limitations (CBD, 2003), permitting only relatively broad-scale analyses of the total number and area of protected areas (Chape et al., Reference Chape, Harrison, Spalding and Lysenko2005). More complete information on individual marine protected areas has been largely unavailable. Consequently, there have been formal calls for better information (CBD, 2004). In response, a collaboration was established between the Sea Around Us Project at the University of British Columbia, Canada, WWF, and the UN Environment Programme–World Conservation Monitoring Centre to revise and update the marine protected area data in the WDPA.

The objective of this study was to collect data to enable more effective monitoring of marine protected areas in relation to four stated requirements of the three global targets: (1) distribution and coverage, (2) network characteristics, as defined by available information on larval dispersal distances, (3) representativeness, and (4) growth of the network over time. Here we present a global review of the current status of the world's marine protected areas, with explicit reference to the three global targets, as well as a preliminary quantitative assessment of the feasibility of the targets. We discuss these results, their implications and their limitations, and the role of large-scale targets in advancing marine conservation.

Methods

Database

Spatial and descriptive data were extracted from the WDPA (Version 6.2; UNEP-WCMC, 2004) for all sites that were listed as marine. This includes protected areas that have been designated using statutory and non-statutory mechanisms operating at a range of scales, including individual protected area agreements, customary or traditional mechanisms, state/provincial legislation, national legislation, and international conventions. It also includes marine protected areas of variable designation status, including designated, proposed and degazetted. These data were restructured and used to create a new database, MPA Global (Wood, Reference Wood2007). Some new fields were added, including marine area (portion of the total area that is below the mean high water mark), no-take area (portion of the marine area where extraction of resources, both living and non-living, is prohibited), and regulatory information. Registered users of the database can view, review and submit edits. Field-level referencing was built into the online editing process to increase the transparency of the database as well as document discrepancies between source materials.

The criterion used for inclusion of a protected area in MPA Global is based on the IUCN (1988) definition: ‘Any area of intertidal or subtidal terrain, together with its overlying water and associated flora, fauna, historical and cultural features, which has been reserved by law or other effective means to protect part or all of the enclosed environment’. This definition was applied by reviewing the legal boundary of the site. If it extended seaward of the mean high water mark the site was left in, or added to, the database. For sites designated under non-statutory mechanisms, or for which the designating legislation did not specify the legal seaward boundary, eligibility for inclusion was assessed using multiple sources (see below). Protected areas in the Caspian Sea were not included. Sites whose only so-called marine area was lagoonal were included only if the lagoon has a permanent surface connection to the sea. A globally extensive (although not yet fully exhaustive), multi-pronged, site-level update and verification process was undertaken. Marine protected areas whose boundaries appeared to fall completely inland, using the 1:3,000,000 countries' coastline geographical information system (GIS) shapefile provided in the ESRI Data and Maps Media Kit 2003 (ESRI, Redlands, USA), were identified and individually assessed. Updates were made at regional, country and sub-country levels using multiple sources, including: a range of existing marine protected area databases, legislation, websites, peer reviewed and non-peer reviewed literature, and direct communications with regional and national experts. Finally, stratified sampling was undertaken to verify the data for the largest sites.

To date, over 1,100 sources have been used to perform over 200,000 edits, pertaining to all countries with marine protected areas. Almost 1,000 non-qualifying marine protected areas have been removed, 1,000 marine protected areas have been added from the WDPA that were not previously listed in the WDPA as marine, and almost 900 new sites have been added. These updates represent a c. 75% change to the original WDPA list of marine protected areas. New spatial data (protected area boundary polygons) have been obtained for 1,822 of 3,061 marine protected areas with spatial boundary data.

Protected area network coverage

Global marine protected area coverage was estimated for all areas designated up to 31 December 2006. Sites listed under international conventions (e.g. UNESCO World Heritage Convention 1972, RAMSAR Convention 1971) were excluded because of near-complete overlap with nationally designated sites. Sites whose status was not designated or informally designated were excluded. It was considered more accurate to estimate global marine protected area coverage by summing marine area estimates obtained through the editing process, rather than through spatial analysis, because of a lack of spatial boundary data for c. 31% of protected areas, and knowledge that some of the boundary data are out of date and substantially under- or oversized. Of the total marine protected area estimate, 92% was obtained from verified sources and 8% estimated. For protected areas with unknown marine area, their total area was prorated according to the median proportion of total area for protected areas with known marine area and matching broad habitat types (intertidal only, intertidal and subtidal, subtidal only). Double counting of area because of overlap between protected areas was eliminated by subtracting the area of sites identified through the verification process as overlapping. Some overlap may remain but this is negligible relative to the total area.

Information on no-take status was collected on two levels: a qualitative status (all/part/none of the protected area is no-take) and a quantitative areal estimate where available. No-take data are currently available for 65% of the total marine protected area. Total global no-take area was estimated by summing the areas stored in the attribute data; no overlap is known to exist between sites for which no-take data are available.

Protected area network characteristics

We assessed the connectedness of marine protected areas globally in terms of recommendations for protected area size and inter-protected area spacing based on known marine larval dispersal distances. A size-frequency distribution was produced using marine area data to identify the number and combined area of the world's marine protected areas that are large enough to be self-seeding for short-dispersing species. Sizes assessed were: > 3.14 km2, 12.5–28.5 km2 (Shanks et al., Reference Shanks, Grantham and Carr2003), and 10–100 km2 (Halpern & Warner, Reference Halpern and Warner2003). Recommended inter-protected area distances were used to create buffers around protected areas in ArcGIS v 9.2 (ESRI, Redlands, USA). Distances used were: 10–20 km (Shanks et al., Reference Shanks, Grantham and Carr2003) and 20–150 km (adapted from Palumbi, Reference Palumbi2003, and Cowen et al., Reference Cowen, Paris and Srinivasan2006). Protected areas occurring within these bands were considered to be connected to at least one other protected area. These two analyses were combined to identify protected areas that meet both size and spacing requirements.

Global network representativeness

Four measures of protected area network representativeness were investigated. Firstly, the distance of the central point of each marine protected area from the coast was estimated in ArcGIS, enabling both the frequency and area to be plotted as a function of distance from shore. Secondly, the same procedure was used to measure distance of protected areas from the equator. The highly variable size and shape of individual protected area boundaries relative to the land mean that these distances may be an overestimate in some cases and an underestimate in others but it represents a standard measure for all marine protected areas. Thirdly, the proportions of the following individual habitat types (for which a global distribution map is available) that are protected were estimated in ArcGIS: estuaries (Alder, Reference Alder2003); mangroves (UNEP-WCMC data); seagrass (UNEP-WCMC data); coral reefs (UNEP-WCMC data); and seamounts (Kitchingman & Lai, Reference Kitchingman, Lai, Morato and Pauly2004). Finally, the proportions of two large scale political and/or broad marine habitat classifications that are currently protected was estimated: Large Marine Ecosystem and Exclusive Economic Zone.

Global network growth and target attainment

Designation dates were available for marine protected areas constituting 98% of the total global area protected. The remaining 2% of the area was distributed across all years, prorated according to the proportion of the total global marine protected area (in sites of known marine area) designated in that year. Known chronological changes in the size of individual protected areas were incorporated into the cumulative growth data. Simple linear regression of the logged cumulative global protected area was used to estimate annual growth rate with which to predict target attainment dates.

Results

Global network of marine protected areas

Extent By 31 December 2006 c. 4,435 marine protected areas had been statutorily or non-statutorily designated at national or local levels, covering c. 2.35 million km2, and occurring entirely within Exclusive Economic Zones. This represents 0.65% of the world's oceans, or 1.6% of the total global marine area within such Zones. Only 12.8% of those 2.35 million km2, representing 0.08% of the world's oceans and 0.20% of the global marine area under national jurisdiction, is subject to no-take regulations (i.e. is ‘strictly protected’ in the wording of the World Parks Congress Recommendation; IUCN, 2003; Fig. 1). This is the first estimate of global no-take area that has been based directly on no-take data, and improves upon previous estimates that, because of a lack of such information, used IUCN management category as a proxy (Agardy et al., Reference Agardy, Bridgewater, Crosby, Day, Dayton and Kenchington2003; Jones, Reference Jones2006).

Fig. 1 The global distribution of (a) all and (b) no-take marine protected areas designated by 31 December 2006. In (b) shaded polygons show protected areas that are entirely no-take; unshaded polygons show protected areas that include one or more no-take zones.

Characteristics The mean size of marine protected areas is c. 544 km2, with a median size of 4.6 km2. The substantial difference between mean and median size is largely attributable to 10 large protected areas that constitute 68% of global marine protected areas (Table 1). Following size range suggestions derived from larval dispersal distances (Halpern & Warner, Reference Halpern and Warner2003; Shanks et al., Reference Shanks, Grantham and Carr2003), 79% of marine protected areas, representing 98.6% of total marine area protected, appear to be either too small or too large (Fig. 2, Table 2), particularly the latter, because of the 10 largest areas. However, if the size recommendations are viewed as minima, 35–60% of marine protected areas, representing > 99% of the total area protected, are sufficiently large (Table 2).

Fig. 2 Area-frequency distribution of the world's marine protected areas, showing recommended sizes using marine larval dispersal distances: a, 10–100 km2 (Halpern & Warner, Reference Halpern and Warner2003); b, minimum 3.14 km2, preferable 12.5–28.5 km2 (Shanks et al., Reference Shanks, Grantham and Carr2003).

Table 1 Total and marine areas of the 10 largest marine protected areas globally.

1 This site was redesignated as a Marine National Monument in June 2006.

2 Total and marine areas include buffer zone areas.

Table 2 Percentage of the world's marine protected areas by number and area that are within the area and minimum area recommendations made by (a) Halpern & Warner (Reference Halpern and Warner2003) and (b) Shanks et al. (Reference Shanks, Grantham and Carr2003).

A total of 2,496 marine protected areas (56.3% of the global total), covering 1.28 million km2 (54.5% of the world's marine protected area) are connected within 10–20 km of at least one other marine protected area. The vast majority of these (85% by number and 98% by area) are connected to a maximum of 10 marine protected areas (Fig. 3a). Using the larger connectedness distance of 20–150 km, 3,487 marine protected areas (78.6% of the global total), covering 1.88 million km2 (80.3% of the world's marine protected area) are connected to at least one other protected area, and are generally connected to more marine protected areas (Fig. 3b) than under the previous scenario. Combining the minimum size and spacing requirements indicates that, at best, 49% of marine protected areas (80% by area) and at worst, only 18% (54% by area) could be considered as part of a connected network (Table 3).

Fig. 3 Combined area (left axis, bars) and relative frequency (right axis, dots) of marine protected areas exhibiting variable individual levels of connectedness, as measured by the relative frequency occurring (a) 10–20 km, and (b) 20–150 km away from each protected area.

Table 3 Percentage of the world's marine protected areas by number and area that meet both minimum size and inter-marine protected area distance recommendations made by (a) Halpern & Warner (Reference Halpern and Warner2003) (b) Shanks et al. (Reference Shanks, Grantham and Carr2003) and (c) Palumbi (Reference Palumbi2003).

Representativeness The distribution of the world's marine protected areas is distinctly non-uniform, being heavily biased towards both coastal waters and the 10 largest protected areas (Fig. 4, Table 1). The number of protected areas declines exponentially with distance from shore, as does the distribution of area protected with distance from shore, with the exception of some of the 10 largest protected areas. However, the boundaries of all of these large protected areas (Table 1) do abut the coast. As such, the measured distance of their centroid from shore is high simply by virtue of their large size (Fig. 4).

Fig. 4 Marine area protected as a function of distance from the coast, as area (bars) and number (dots). The world's 10 largest marine protected areas are shown separately (see Table 1). The limits for territorial sea (12 nm) and Exclusive Economic Zone (200 nm) are indicated for clarity.

The majority of the global marine area protected (approximately 65%, representing 43% of all protected areas) is within the tropical latitude belt, between 30°N and 30°S, suggesting that tropical coastal habitats may be among the best protected of all marine habitat types, at least on paper (Fig. 5a). However, most of the remaining global marine area protected (31%, representing 26% of all marine protected areas and including five of the world's 10 largest marine protected areas) is in latitudes > 50°, two-thirds of which is located in the northern hemisphere. These northern areas protect by far the highest proportion of sea surface area by latitude (Fig. 5b). However, this may be largely attributable to the relatively small surface area of sea north of 50°N. Intermediate latitudes (30°–50°), and particularly southern temperate and polar latitudes, appear to be the least protected.

Fig. 5 Distribution of marine protected areas (by number and mean area) as a function of distance from the Equator. (a) Absolute area protected, with the world's 10 largest protected areas shown separately (see Table 1). (b) The proportion of ocean area that is protected.

Laurel & Bradbury (Reference Laurel and Bradbury2006) suggested that, based on larval dispersal distances, marine protected area size should increase with latitude. Using a subset of MPA Global, they concluded that this trend is not observed in the global network of marine protected areas. Using the complete dataset, we found a similar result. However, we also found that mean and median protected area size at latitudes > 50° is larger than the global values, and increases through the high latitude range (Fig. 5b, Table 4).

Table 4 Summary statistics for marine protected areas (MPA) by number and area in high latitudes (> 50°).

Proportional representation of habitat types within the global network is shown in Fig. 6. These are the only habitats for which global distributional data are known to be available, and mirrors the paucity of global data for terrestrial habitats (Balmford et al., Reference Balmford, Green and Jenkins2003). The accuracy of the proportions protected varies with habitat type because of variable (and largely unknown) accuracy of the habitat distributions themselves, both in terms of their precision as well as the confounding problems of habitat loss and change through time.

Fig. 6 Estimated proportion of marine habitats protected within the current global marine protected area network, for habitat types where global distribution data are available.

Fig. 7 shows the proportions of Large Marine Ecosystems and Exclusive Economic Zones that are currently protected. Large Marine Ecosystems are suggested by the CBD as an appropriate classification system for monitoring progress towards its target (CBD, 2005). However, this is problematic for Pacific Island countries and territories, none of which occur within a Large Marine Ecosystem but all of which (with the exception of US territories) are party to the Convention. Given this, and the largely national scale of implementation of the CBD target, we view the proportion of Exclusive Economic Zone as the best current assessment of the representativeness of the global marine protected area network (despite the political basis of the boundaries). It indicates that the current global network falls far short of target requirements. Over 87% of 226 coastal countries (including 69 overseas territories and the non-contiguous US states of Hawaii and Alaska, listed separately) have less than the global average of 1.6% of their Exclusive Economic Zones protected (Appendix). Of the nine countries that currently have > 10% of their Exclusive Economic Zones protected, four have relatively small maritime territories, rather than a high absolute area under protection. The remaining five are overseas territories (including the non-contiguous US state of Hawaii) that include four of the 10 largest marine protected areas.

Fig. 7 Proportion of (a) Large Marine Ecosystem and (b) 200 nm Exclusive Economic Zones of maritime countries and territories that is protected.

Feasibility of attaining global targets

Growth of the network The cumulative global marine protected area has grown steadily since the mid 1970s, coincident with the coming into force of various international conservation conventions (UNESCO, 1970; Ramsar Convention, 1971; UNESCO World Heritage Convention, 1972), and with some irregularities because of the creation of a few large protected areas (Fig. 8, Table 1). Growth of no-take area has been slow until recently, when the rezoning of the Great Barrier Reef Marine Park in 2004 (GBRMPA, 2004) increased the global no-take area by > 50% and 100,000 km2 (Fig. 8). On 15 July 2006 the North-western Hawaiian Islands Coral Reef Ecosystem Reserve (341,362 km2, originally designated in 2000) was redesignated as a Marine National Monument. Although it is not yet completely no-take, various habitat-damaging activities and all fishing is required to have ceased within 5 years (Establishment of the North-western Hawaiian Islands Marine National Monument: a Proclamation by the President of the United States of America, 2006).

Fig. 8 Growth in cumulative global marine area protected for: total (solid circles), log(total) (open circles), and no-take (squares) area.

Simple linear regression of the log-transformed cumulative marine protected area indicates a 4.6% annual increase over 1984–2006 (Fig. 9). This timespan was selected as it represents a time of steady growth and is representative of the recent political environment. As such it was considered an appropriate time frame on which to base projections for target attainment. Subsequent to the designation of the majority of the Great Barrier Reef Marine Park in 1984 (it was created through a series of extensions over 1978–1984; GBRMPA, 2007), seven of the 10 largest marine protected areas were designated, together covering 43% of the current global marine area protected and 67% of the combined area of the top 10 protected areas (Table 1). In spite of this substantial increase in area protected, the overall rate of global marine protected area growth has not shifted from what appears to be a stable, but slow, trajectory.

Fig. 9 Projection of the annual rate of increase (4.6%, r 2=0.96) of global marine area protected between 1984 and 2006 and into the future, in relation to attainment of marine protection targets adopted by the Convention on Biological Diversity (CBD) and the World Parks Congress (WPC).

Projected attainment dates of targets We extrapolated the 4.6% growth into the future to assess the attainability of the World Parks Congress and CBD targets. It was not possible to assess attainability of the World Summit on Sustainable Development target using this method as it does not state quantitative areal targets. Results indicate that even the most modest targets will not be met for at least several decades (Fig. 9). Furthermore, the growth rates required to meet these targets on time are at least an order of magnitude greater than observed (Table 5). In other words, a marine area at least three times the combined size of the 10 largest marine protected areas (i.e. c. 4.5 million km2) would have to be designated every year until and including 2010 for timely attainment of the CBD target. These projections do not impose any of the additional requirements stated in the targets, including strict protection, habitat representation, and management effectiveness.

Table 5 Summary of the annual rates of increase in global marine protected area (MPA) coverage required to meet various Convention on Biological Diversity (CBD) and World Parks Congress (WPC) marine protection targets on time, both at the time the targets were made and as of 31 December 2006.

1 EEZ, Exclusive Economic Zone.

2 The CBD target does not explicitly include the high seas but states that the high seas should be urgently protected using international cooperation. The data presented here are based on an extension of the CBD 10% target to include the high seas.

Discussion

Our results indicate that the current extent, distribution, sizing and spacing of marine protected areas globally is vastly inadequate, particularly for no-take areas, and especially in light of past, ongoing, and expected future impacts on the oceans. The coastal bias of existing marine protected areas may not be too serious a disadvantage, because the coastal shelves contribute most to the world's primary production, known marine biodiversity and fisheries productivity (Pauly et al., Reference Pauly, Christensen, Guénette, Pitcher, Sumaila and Walters2002). However, other attributes of the existing network may serve to reduce the effective area and extent of the network. Between 20 and 46% of the global area protected occurs in small and isolated areas, which may thus not be effective at ensuring persistence of marine populations or form part of a coherent global network. At the other extreme the majority of the total marine area protected globally is contained within a handful of extremely large protected areas. At least some large areas are needed to protect highly migratory species such as large pelagic fish and marine mammals, as well as to offset the concentration of fishing effort outside them (Walters, Reference Walters2000), particularly if (as is the current situation) fishing effort is high and not reduced in conjunction with the creation of marine protected areas (Pauly et al., Reference Pauly, Christensen, Guénette, Pitcher, Sumaila and Walters2002; Worm et al., Reference Worm, Lotze and Myers2003). However, the total marine area protected globally is currently so small that its concentration in a few marine protected areas means that much of the world's oceans are essentially unprotected. This configuration thus confers low levels of representation of many marine habitats, as well as of various biophysical, geographical and political regions. All of these factors may limit the resilience of the global network to many external threats, as well as anticipated spatial shifts in species, communities and hydrological features in response to climate change (Carr et al., Reference Carr, Neigel, Estes, Andelman, Warner and Largier2003; Perry et al., Reference Perry, Low, Ellis and Reynolds2005; Parmesan, Reference Parmesan2006; Simmonds & Isaac, Reference Simmonds and Isaac2007).

In addition, the results presented here are best case scenarios, representing only the areas of the world's oceans that are protected on paper. It should not be assumed that (1) the process that created these marine protected areas also provided mechanisms for regulating human activities in the area, (2) where regulatory mechanisms are in place they are all being implemented, or (3) they are implemented effectively. In many, if not most, marine protected areas the biodiversity and fisheries benefits that may accrue through protection are eroded or undermined by inadequate management resources (financial and human), poor compliance with regulations, and little-managed or unmanaged external threats (Alder, Reference Alder1996; McClanahan, Reference McClanahan1999; Jameson et al., Reference Jameson, Tupper and Ridley2002). The best available information on management effectiveness is currently from large-scale analyses that are either outdated or focused on a subset of the world's marine protected areas. These assessments indicate low rates of effective management (Kelleher et al., Reference Kelleher, Bleakey and Wells1995; Alder, Reference Alder1996; Mora et al., Reference Mora, Andréfouët, Kranenburg, Rollo, Costello and Veron2006).

Our results imply almost certain failure, at the very least in terms of attainment of global marine protection targets. Despite the designation in 2006 of the 184,700 km2 Phoenix Islands Protected Area by the Government of Kiribati, a huge individual achievement, at least 76 more countries each need to create marine protected areas covering an area equivalent to this before 2010 for the CBD target to be met on time. Unfortunately, we suspect that the negative connotations of these predictions may undermine the benefits and successes of positive results at smaller scales, such as that of Kiribati. Our results do, however, demand that the question be asked, yet again: can large scale conservation targets do more harm than good?

The utility of broadscale conservation targets has been frequently questioned. Targets have historically been justified in terms of political expediency rather than ecological knowledge (Soulé & Sanjayan, Reference Soulé and Sanjayan1998; Agardy et al., Reference Agardy, Bridgewater, Crosby, Day, Dayton and Kenchington2003). Broadscale, uniform conservation targets may thus be inadequate for meeting biodiversity conservation objectives (Rodrigues et al., Reference Rodrigues, Andelman, Bakarr, Boitani, Brooks and Cowling2004), and may ultimately weaken the political process to create protected areas if the expected benefits are not observed, particularly within the electoral time frame. However, the terrestrial protected area network has developed over more than a century, with at least half of the area designated (Chape et al., Reference Chape, Harrison, Spalding and Lysenko2005) before quantitative global targets were first established in the early 1980s (Soulé & Sanjayan, Reference Soulé and Sanjayan1998). Similarly, the first explicitly marine, quantitative global protection target was made in 2003 (IUCN, 2003) when over 95% of the current marine area protected had already been created. Therefore, the location and design of both marine and terrestrial protected areas have, to date, been selected largely without explicit consideration of many of the recently formalized principles of marine protected area network design theory (Lubchenco et al., Reference Lubchenco, Palumbi, Gaines and Andelman2003; Roberts et al., Reference Roberts, Andelman, Branch, Bustamante, Castilla and Dugan2003) or the application of systematic conservation planning tools (Kirkpatrick, Reference Kirkpatrick1983). Whereas it is important to understand the adequacy or otherwise of existing protected areas in meeting specific objectives to inform future conservation planning, it may be counter-productive, and perhaps irrelevant politically, to criticize the products of past processes in terms of current ones.

A more pressing question is how to garner the political will required to motivate a rapid increase in marine protection, particularly in the face of wider policy concerns such as food security, human welfare and health. In this regard, broadscale conservation targets can help mobilize support for, and schedule, conservation intervention in the face of limited resources, ongoing biodiversity losses, and inadequate protection (Margules & Pressey, Reference Margules and Pressey2000; Pressey et al., Reference Pressey, Cowling and Rouget2003). In particular, the CBD target demonstrates a commitment of the parties to the Convention (presently 188; Appendix) to translate their general obligations under the Convention into concrete action for conservation and sustainable use (Pauly & Watson, Reference Pauly and Watson2005). Nevertheless, given the mismatch between the resources available and those required to implement and monitor a global network of marine protected areas, it seems likely that the network developed by the time of the target deadlines will almost certainly be a compromise, between quantity (i.e. how closely the targets are met) and quality (i.e. how appropriately designed and effectively implemented the protected areas thus created are). Broadscale conservation targets are thus, perhaps, necessary but not sufficient for effective marine resource conservation and management.

The work presented here has substantially improved knowledge of the global marine protected area baseline, and enhanced our ability to monitor various aspects of targets. While the value of a list of marine protected areas in terms of assessing the effective level of protection has been questioned (Roff, Reference Roff2005), it remains a fundamental prerequisite to any assessment of status or progress. Our analysis has provided the first quantitative estimate of the rate of change needed for these targets to be met. While daunting, this new information arms decision makers and conservation planners with a greater understanding of the magnitude of the task ahead and the urgency with which they must tackle it.

Acknowledgements

This work was supported by WWF, the UN Environment Programme–World Conservation Monitoring Centre, and the Sea Around Us Project, an activity funded and initiated by the Pew Charitable Trusts. We thank Chris O'Grady for developing the MPA Global website, as well as numerous data contributors, and Jackie Alder, Dan Ogolla, Marjo Vierros, Colette Wabnitz and Dirk Zeller for comments.

Appendix

The appendix for this article is available online at http://journals.cambridge.org

Biographical sketches

Louisa Wood has been working in the field of marine protected areas and their role in marine resource management and biodiversity conservation since 2001. She is currently working as a Technical Advisor on marine protected areas for IUCN's Global Marine Programme. Lucy Fish is a GIS Officer at the UNEP-World Conservation Monitoring Centre. A large part of her work is the maintenance of the World Database on Protected Areas. Josh Laughren is a marine protected area expert who served as Director of Marine Conservation for WWF-Canada for 1997–2006, and as the lead on marine protected area establishment for WWF's global Marine Advisory Group for 2000–2006. Daniel Pauly's research interests are in ecosystem-based management, and the geography of fisheries and their impacts on marine ecosystems (see http://www.seaaroundus.org), and he has written extensively on fish population dynamics, fisheries management and ichthyology, and is one of the co-initiators of FishBase (http://www.fishbase.org).

References

Agardy, T. (1994) Advances in marine conservation: the role of marine protected areas. Trends in Ecology & Evolution, 9, 267270.CrossRefGoogle Scholar
Agardy, T., Bridgewater, P., Crosby, M.P., Day, J., Dayton, P.K., Kenchington, R. et al. . (2003) Dangerous targets? Unresolved issues and ideological clashes around marine protected areas. Aquatic Conservation: Marine and Freshwater Ecosystems, 13, 353367.CrossRefGoogle Scholar
Alder, J. (1996) Have tropical marine protected areas worked? An initial analysis of their success. Coastal Management, 24, 97114.CrossRefGoogle Scholar
Alder, J. (2003) Putting the coast in the Sea Around Us project. Sea Around Us Project Newsletter, 15, 12.Google Scholar
Balmford, A., Green, R.E. & Jenkins, M. (2003) Measuring the changing state of nature. Trends in Ecology & Evolution, 18, 326330.CrossRefGoogle Scholar
Carr, M.H., Neigel, J.E., Estes, J.A., Andelman, S., Warner, R.R. & Largier, J.L. (2003) Comparing marine and terrestrial ecosystems: implications for the design of coastal marine reserves. Ecological Applications, 13, S90S107.CrossRefGoogle Scholar
CBD (2003) Marine and Coastal Biodiversity: Review, Further Elaboration and Refinement of the Programme of Work. Report of the Ad Hoc Technical Expert Group on Marine and Coastal Protected Areas. Convention on Biological Diversity, UNEP/CBD/SBSTTA/8/INF/7. Convention on Biological Diversity, Montreal, Canada.Google Scholar
CBD (2004) Decisions Adopted by the Conference of the Parties to the Convention on Biological Diversity at its Seventh Meeting (Decision VII/30). Convention on Biological Diversity, UNEP/CBD/COP/7/21. Convention on Biological Diversity, Kuala Lumpur, Malaysia.Google Scholar
CBD (2005) Draft Global Outcome-oriented Targets for the Programme of Work on Marine and Coastal Biological Diversity. Convention on Biological Diversity, UNEP/CBD/SBSTTA/10/8/Add.1. Convention on Biological Diversity, Bangkok, Thailand.Google Scholar
CBD (2006) Decisions Adopted by the Conference of the Parties to the Convention on Biological Diversity at its Eighth Meeting (Decision VIII/15, Annex IV). Convention on Biological Diversity, Curitiba, Brazil.Google Scholar
Chape, S., Harrison, J., Spalding, M. & Lysenko, I. (2005) Measuring the extent and effectiveness of protected areas as an indicator for meeting global biodiversity targets. Philosophical Transactions of the Royal Society of London, Series B, 360, 443455.CrossRefGoogle ScholarPubMed
Cowen, R.K., Paris, C.B. & Srinivasan, A. (2006) Scaling of connectivity in marine populations. Science, 311, 522527.CrossRefGoogle ScholarPubMed
Establishment of the Northwestern Hawaiian Islands Marine National Monument: A Proclamation by the President of the United States of America (2006) Presidential Proclamation 8031. Http://www.whitehouse.gov/news/releases/2006/06/20060615–18.html [accessed 26 July 2006].Google Scholar
GBRMPA (Great Barrier Reef Marine Park Authority) (2004) Marine Park Zoning. Http://www.gbrmpa.gov.au/corp_site/management/zoning/ [accessed 21 September 2005].Google Scholar
GBRMPA (Great Barrier Reef Marine Park Authority) (2007) The Great Barrier Reef Marine Park. Http://www.gbrmpa.gov.au [accessed 30 July 2007].Google Scholar
Halpern, B.S. & Warner, R.R. (2003) Matching marine reserve design to reserve objectives. Proceedings of the Royal Society of London, Series B, 270, 18711878.CrossRefGoogle ScholarPubMed
Hoyt, E. (2005) Marine Protected Areas for Whales, Dolphins and Porpoises. Earthscan, London, UK.Google Scholar
IUCN (1988) Resolution 17.38 of the 17th General Assembly of the IUCN. IUCN, Gland, Switzerland.Google Scholar
IUCN (2003) Recommendations of the Vth IUCN World Parks Congress. IUCN, Gland, Switzerland.Google Scholar
Jameson, S., Tupper, M.H. & Ridley, J.M. (2002) The three screen doors: can marine “protected” areas be effective? Marine Pollution Bulletin, 44, 11771183.CrossRefGoogle ScholarPubMed
Jones, P.J.S. (2006) Collective action problems posed by no-take zones. Marine Policy, 30, 143156.CrossRefGoogle Scholar
Kelleher, G., Bleakey, C. & Wells, S. (eds) (1995) A Global Representative System of Marine Protected Areas. The Great Barrier Reef Marine Park Authority/The World Bank/IUCN, Washington, DC, USA.Google Scholar
Kirkpatrick, J.B. (1983) An iterative model for establishing priorities for the selection of nature reserves. Biological Conservation, 25, 127134.CrossRefGoogle Scholar
Kitchingman, A. & Lai, S. (2004) Inferences on potential seamount locations from mid-resolution bathymetric data. In Seamounts: Biodiversity and Fisheries (eds Morato, T. & Pauly, D.), pp. 712. Fisheries Centre, Vancouver, Canada.Google Scholar
Laurel, B.J. & Bradbury, I.R. (2006) ‘Big’ concerns with high latitude marine protected areas (MPAs): trends in connectivity and MPA size. Canadian Journal of Fisheries and Aquatic Sciences, 63, 26032607.CrossRefGoogle Scholar
Lubchenco, J., Palumbi, S.R., Gaines, S.D. & Andelman, S.J. (2003) Plugging a hole in the ocean: the emerging science of marine reserves. Ecological Applications, 13, S3S7.CrossRefGoogle Scholar
Margules, C.R. & Pressey, R.L. (2000) Systematic conservation planning. Nature, 405, 243253.CrossRefGoogle ScholarPubMed
McClanahan, T.R. (1999) Is there a future for coral reef parks in poor tropical countries? Coral Reefs, 18, 321325.CrossRefGoogle Scholar
Mora, C., Andréfouët, S., Kranenburg, C., Rollo, A., Costello, M.J., Veron, J. et al. (2006) Conservation of coral reefs by the global network of marine protected areas. Science, 312, 17501751.CrossRefGoogle ScholarPubMed
Palumbi, S.R. (2003) Population genetics, demographic connectivity, and the design of marine reserves. Ecological Applications, 13, S146S158.CrossRefGoogle Scholar
Parmesan, C. (2006) Ecological and evolutionary responses to recent climate change. Annual Review of Ecology and Systematics, 37, 637669.CrossRefGoogle Scholar
Pauly, D., Christensen, V., Guénette, S., Pitcher, T., Sumaila, U.R., Walters, C. et al. . (2002) Towards sustainability in world fisheries. Nature, 418, 689695.CrossRefGoogle ScholarPubMed
Pauly, D. & Watson, R. (2005) Background and interpretation of the ‘Marine Trophic Index’ as a measure of biodiversity. Philosophical Transactions of the Royal Society of London, Series B, 360, 415423.CrossRefGoogle ScholarPubMed
Perry, A.L., Low, P.J., Ellis, J.R. & Reynolds, J.D. (2005) Climate change and distribution shifts in marine fishes. Science, 308, 19121915.CrossRefGoogle ScholarPubMed
Pressey, R.L., Cowling, R.M. & Rouget, M. (2003) Formulating conservation targets for biodiversity pattern and process in the Cape Floristic Region, South Africa. Biological Conservation, 112, 99127.CrossRefGoogle Scholar
Ramsar Convention (1971) The Convention on Wetlands of International Importance especially as Waterfowl Habitat, Ramsar, Iran, 2 February 1971. Http://ramsar.org/key_conv_e.htm [accessed 31 August 2007].Google Scholar
Roberts, C.M., Andelman, S., Branch, G., Bustamante, R.H., Castilla, J.C., Dugan, J. et al. . (2003) Ecological criteria for evaluating candidate sites for marine reserves. Ecological Applications, 13, S199S214.CrossRefGoogle Scholar
Roberts, C.M., Hawkins, J.P. & Gell, F.R. (2005) The role of marine reserves in achieving sustainable fisheries. Philosophical Transactions of the Royal Society, Series B, 360, 123132.CrossRefGoogle ScholarPubMed
Rodrigues, A.S.L., Andelman, S.J., Bakarr, M.I., Boitani, L., Brooks, T.M., Cowling, R.M. et al. . (2004) Effectiveness of the global protected area network in representing species diversity. Nature, 428, 640643.CrossRefGoogle ScholarPubMed
Roff, J.C. (2005) Conservation of marine biodiversity: too much diversity, too little cooperation. Aquatic Conservation: Marine and Freshwater Ecosystems, 15, 15.CrossRefGoogle Scholar
Shanks, A.L., Grantham, B.A. & Carr, M. (2003) Propagule dispersal distance and the size and spacing of marine reserves. Ecological Applications, 13, S159S169.CrossRefGoogle Scholar
Simmonds, M.P. & Isaac, S.J. (2007) The impacts of climate change on marine mammals: early signs of significant problems. Oryx, 41, 1926.CrossRefGoogle Scholar
Soulé, M.E. & Sanjayan, M.A. (1998) Conservation targets: do they help? Science, 279, 20602061.CrossRefGoogle ScholarPubMed
UNEP-WCMC (2004) World Database on Protected Areas, Version 6.2. UNEP-WCMC, Cambridge, UK. Http://sea.unep-wcmc.org/wdbpa [accessed 28 April 2007].Google Scholar
UNESCO (1970) Records of the General Conference, Sixteenth Session, Paris, 12 October to 14 November 1970, v.1: Resolutions. UNESCO, Paris, France.Google Scholar
UNESCO World Heritage Convention (1972) Convention Concerning the Protection of the World's Cultural and Natural Heritage, Paris, France, 17 October–17 November 1972. Http://whc.unesco.org/pg.cfm?cid=182 [accessed 31 August 2007].Google Scholar
United Nations (2002) Report of the World Summit on Sustainable Development, Johannesburg, South Africa, 26 August-4 September 2002. A/CONF.199/20. UN, New York, USA.Google Scholar
Walters, C. (2000) Impacts of dispersal, ecological interactions, and fishing effort dynamics on efficacy of marine protected areas: how large should protected areas be? Bulletin of Marine Science, 66, 745757.Google Scholar
Wood, L.J. (2007) MPA Global: A Database of the World's Marine Protected Areas. Sea Around Us Project, UNEP-WCMC & WWF, Vancouver, Canada. Http://www.mpaglobal.org [accessed 5 July 2007].Google Scholar
Worm, B., Lotze, H.K. & Myers, R.A. (2003) Predator diversity hotspots in the blue ocean. Proceedings of the National Academy of Sciences, 100, 98849888.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 The global distribution of (a) all and (b) no-take marine protected areas designated by 31 December 2006. In (b) shaded polygons show protected areas that are entirely no-take; unshaded polygons show protected areas that include one or more no-take zones.

Figure 1

Fig. 2 Area-frequency distribution of the world's marine protected areas, showing recommended sizes using marine larval dispersal distances: a, 10–100 km2 (Halpern & Warner, 2003); b, minimum 3.14 km2, preferable 12.5–28.5 km2 (Shanks et al., 2003).

Figure 2

Table 1 Total and marine areas of the 10 largest marine protected areas globally.

Figure 3

Table 2 Percentage of the world's marine protected areas by number and area that are within the area and minimum area recommendations made by (a) Halpern & Warner (2003) and (b) Shanks et al. (2003).

Figure 4

Fig. 3 Combined area (left axis, bars) and relative frequency (right axis, dots) of marine protected areas exhibiting variable individual levels of connectedness, as measured by the relative frequency occurring (a) 10–20 km, and (b) 20–150 km away from each protected area.

Figure 5

Table 3 Percentage of the world's marine protected areas by number and area that meet both minimum size and inter-marine protected area distance recommendations made by (a) Halpern & Warner (2003) (b) Shanks et al. (2003) and (c) Palumbi (2003).

Figure 6

Fig. 4 Marine area protected as a function of distance from the coast, as area (bars) and number (dots). The world's 10 largest marine protected areas are shown separately (see Table 1). The limits for territorial sea (12 nm) and Exclusive Economic Zone (200 nm) are indicated for clarity.

Figure 7

Fig. 5 Distribution of marine protected areas (by number and mean area) as a function of distance from the Equator. (a) Absolute area protected, with the world's 10 largest protected areas shown separately (see Table 1). (b) The proportion of ocean area that is protected.

Figure 8

Table 4 Summary statistics for marine protected areas (MPA) by number and area in high latitudes (> 50°).

Figure 9

Fig. 6 Estimated proportion of marine habitats protected within the current global marine protected area network, for habitat types where global distribution data are available.

Figure 10

Fig. 7 Proportion of (a) Large Marine Ecosystem and (b) 200 nm Exclusive Economic Zones of maritime countries and territories that is protected.

Figure 11

Fig. 8 Growth in cumulative global marine area protected for: total (solid circles), log(total) (open circles), and no-take (squares) area.

Figure 12

Fig. 9 Projection of the annual rate of increase (4.6%, r2=0.96) of global marine area protected between 1984 and 2006 and into the future, in relation to attainment of marine protection targets adopted by the Convention on Biological Diversity (CBD) and the World Parks Congress (WPC).

Figure 13

Table 5 Summary of the annual rates of increase in global marine protected area (MPA) coverage required to meet various Convention on Biological Diversity (CBD) and World Parks Congress (WPC) marine protection targets on time, both at the time the targets were made and as of 31 December 2006.

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