Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Marine and Freshwater Research Marine and Freshwater Research Society
Advances in the aquatic sciences
RESEARCH ARTICLE (Open Access)

Policy considerations for managing wetlands under a changing climate

C. M. Finlayson A B O , S. J. Capon C , D. Rissik D , J. Pittock E , G. Fisk F , N. C. Davidson A G , K. A. Bodmin H , P. Papas I , H. A. Robertson J , M. Schallenberg K , N. Saintilan L , K. Edyvane M and G. Bino N
+ Author Affiliations
- Author Affiliations

A Institute for Land, Water and Society, Charles Sturt University, Albury, NSW 2640, Australia.

B UNESCO-IHE, Institute for Water Education, NL-2601 DA, Delft, Netherlands.

C Australian Rivers Institute, Griffith University, Nathan, Qld 4111, Australia.

D National Climate Change Adaptation Research Facility, Griffith University, Gold Coast, Qld 4217, Australia.

E Fenner School of Environment and Society, The Australian National University, Canberra, ACT 2601, Australia.

F BMT WBM Pty Ltd, Brisbane, Qld 4000, Australia.

G Nick Davidson Environmental, Wigmore HR6 9UN, UK.

H National Institute of Water and Atmospheric Research, Hamilton 3216, New Zealand.

I Arthur Rylah Institute for Environmental Research, Department of Environment, Land, Water and Planning, Heidelberg, Vic. 3084, Australia.

J Department of Conservation, Nelson 7010, New Zealand.

K Department of Zoology, University of Otago, Dunedin 9016, New Zealand.

L Department of Environmental Sciences, Macquarie University, NSW 2109, Australia.

M Research Institute for the Environment and Livelihoods, Charles Darwin University, Darwin, NT 0810, Australia.

N Centre for Ecosystem Science, School of Biological, Earth & Environmental Sciences, University of New South Wales, Sydney, NSW 2052, Australia.

O Corresponding author. Email: mfinlayson@csu.edu.au

Marine and Freshwater Research 68(10) 1803-1815 https://doi.org/10.1071/MF16244
Submitted: 5 July 2016  Accepted: 28 December 2016   Published: 3 March 2017

Journal Compilation © CSIRO 2017 Open Access CC BY-NC-ND

Abstract

Drawing on the experience and lessons of wetland researchers and managers in Australia and New Zealand, we examined the implications of climate change for wetland policy and management, and identified potential adaptation responses and the information needed to support these. First, we considered wetland vulnerability to climate change, focusing on wetland exposure and sensitivity. We then outlined the existing policy context for dealing with climate change, with an emphasis on the Ramsar Convention on Wetlands. We then considered how the objectives and targets for wetland management can be set in the face of climate change, how management can be adapted to climate change given the uncertainties involved, and how we can monitor and evaluate wetland condition in the face of climate change. We concluded with a set of principles to guide adaptation of wetland conservation and management policy to climate change.

Additional keywords: adaptation, inland wetland ecosystems, vulnerability, Ramsar Convention.

Introduction

Wetlands throughout the world have long been subject to high levels of degradation and loss caused by human activities (Finlayson and D’Cruz 2005; Davidson 2014; Gardner et al. 2015). Since it came into force in 1975, the Ramsar Convention on Wetlands has been the principal policy instrument for protecting wetlands globally by committing Contracting Parties (i.e. national governments) to designate sites as Wetlands of International Importance (Ramsar Sites) and to monitor and effectively manage these, so as to maintain their ecological character, as well as making wise use of all wetlands (Gardner and Davidson 2011). The juxtaposition of the extent of wetland loss alongside the activities of the Convention led Finlayson (2012) to question the effectiveness of the policy setting for wetlands.

It is increasingly recognised that wetlands are highly vulnerable to anthropogenic climate change and this is likely to have significant consequences for their ecological character (Finlayson et al. 2006; Capon et al. 2013; Junk et al. 2013). Although it is also acknowledged that wetlands respond to changes in climate over different timescales, the focus in the present paper when referring to climate change is on changes resulting from human activities. Within this context, climate change can affect the ecological character of wetlands both directly (e.g. by the effects of warming) and indirectly through interactions with other pressures and stressors (Finlayson et al. 2006; Capon and Bunn 2015). This has considerable ramifications for existing policy and management for maintaining the ecological character of wetlands because non-climatic anthropogenic pressures can further affect wetland responses to the climate (Pittock et al. 2010) and adds further support for the question raised by Finlayson (2012) about the policy settings for wetlands.

Whereas the Ramsar Convention covers a wide range of wetland types, we focus specifically on non-marine wetlands, including both inland wetlands and coastal and estuarine wetlands influenced by tides, but not primarily marine. Wetlands dominated by marine influences, such as, for example, coral reefs and kelp forests, are excluded from our analysis because their vulnerability to climate change and appropriate adaptation actions are likely to differ in many cases. However, many of the general principles we discuss here will still be applicable. In doing this, we have not provided an overview of wetland policies or more generic conservation or natural resource policies that cover wetland management, but point to recent interest in such policies and, in particular, to Peimer et al. (2017) who have recently reviewed national-level wetland policy settings and identified strengths and gaps.

Although there are existing conceptual frameworks for assessing change in the ecological character of wetlands (Finlayson et al. 2005; Davis and Brock 2008, DEWHA 2008; Ramsar Convention Secretariat 2010a, 2010b), identifying and evaluating these changes, and their drivers, in the context of climate change, is particularly problematic. Wetland-policy makers and managers, therefore, require guidance on how to assess and respond to the actual or potential consequences of climate change, especially given the formal obligation of Contracting Parties under the Ramsar Convention to report any adverse changes in Wetlands of International Importance, and the ongoing degradation of wetlands globally.

In the past, the Ramsar Convention has considered its position on climate change in relation to other international treaties (e.g. the United Nations Framework Convention on Climate Change) as well as the various policy positions held by individual Contracting Parties, but has not delivered specific guidance on how to respond to the obligations under the Convention in the face of such change (Finlayson et al. 2016; Gell et al. 2016). There is a need for the Ramsar Convention to develop a consistent and in-depth approach for dealing with the global phenomenon of anthropogenic climate change because this will affect the ecological character of many, if not all, wetlands (Finlayson 2013).

Policy and management for the conservation of wetlands under a changing climate, therefore, require a review of how objectives and targets are set as well as the actions employed to achieve these. Monitoring and evaluation of wetland policy and management interventions also need to be developed with awareness of climate change and its implications for ecosystems. Although such changes may ultimately be transformative for wetland policy and management, adaptations must be developed in the first instance that consider the existing policy context of the Ramsar Convention and the relevant policies and national legislation of Contracting Parties that give effect to this.

Here, we examine the implications of climate change for wetland policy and management to identify potential adaptation responses and the information needed to support these. First, we consider wetland vulnerability to climate change, focusing on exposure and sensitivity. We then outline the existing policy context for wetland conservation and management, including current approaches dealing with anthropogenic climate change, with an emphasis on global wetland policy. Where relevant, we draw on the case studies of Australia and New Zealand, which collectively represent a wide range of climatic zones and contain a high diversity of wetland types.

Against this background, we then consider

  1. how can objectives and targets for wetland conservation and management be set and revised in light of climate change;

  2. how can wetland management best address the uncertainties caused by climate change; and

  3. how can we monitor and evaluate the condition of wetlands that are responding to climate change?

We conclude with a set of key principles to guide adaptation of wetland conservation and management policy to climate change.


Wetland vulnerability to climate change

Although virtually all species and ecosystems are expected to experience the effects of climate change, wetlands are recognised as among the most vulnerable (Hughes 2011, Capon et al. 2013). In this sense, vulnerability is expressed as the relationship between the exposure and sensitivity of wetlands to changes in the climate (Gitay et al. 2011). Because of their low-lying position in the landscape, wetlands are typically subject to high levels of exposure to climatic changes because they experience both local changes and the cumulative effects of changes in the surrounding landscape, as well as being exposed to a wide range of extreme climatic events (such as, e.g. floods, droughts, intense storms and fires; Capon et al. 2013). They also tend to have a high degree of sensitivity to climatic changes because of their responsiveness to changes in water regimes (Capon and Bunn 2015) and temperature (Hamilton et al. 2013). High levels of modification and degradation of wetlands may increase their sensitivity to climate change and limit their capacity to adapt, further increasing their vulnerability. However, highly modified and simplified wetlands may be less sensitive to climate-change effects if their values have been significantly degraded already. Although there is a prevalent view that the probable impacts of climate change on wetlands may be relatively minor in comparison with other anthropogenic stressors (e.g. river regulation), the interaction of climate change with existing threats is of widespread concern, particularly given the uncertainties involved (Finlayson et al. 2006; Kingsford et al. 2011).

Exposure of wetlands to climate change depends on their regional and topographic position, as well as the emissions scenario that will unfold. Wetlands throughout the world are exposed to increasing concentrations of atmospheric carbon dioxide, as well as warming to varying degrees. Changes to precipitation are particularly important drivers of climate-change impacts in wetlands, with systems reliant on rainfall and runoff likely to be more vulnerable than groundwater-fed systems (Winter 2000). Projected changes to precipitation are highly variable both regionally and among global climate models and emission scenarios.

Effects on water quantity are likely from changes in rainfall and increased temperature and evaporation. Hydrological changes and increased temperature will also affect most biogeochemical processes, in turn altering water quality. Drying, for example, may transform some wetlands from sinks to sources of potentially damaging solutes, e.g. nitrate, sulfate, sodium (Freeman et al. 1993). Turbidity and the physical form of wetlands are also susceptible to climate-change impacts because patterns of erosion and sedimentation are highly sensitive to changes in precipitation. Fine-grained alluvial systems are likely to be particularly vulnerable (Goudie 2006).

Wetlands in coastal regions are likely to be further affected by sea-level rise and increased frequency and intensity of extreme storm-surge events (Finlayson et al. 2006; Day et al. 2008). Coastal wetlands in areas with low relief, such as the extensive freshwater wetlands of Kakadu in northern Australia, are particularly susceptible to saltwater intrusion, with large areas likely to be affected as a result of relatively small increases in the sea level (Bayliss et al. 1997; Eliot et al. 1999; BMT WBM 2010). Changes in salinity following sea-level rise will then affect the community structure of wetland plants and animals (Schallenberg et al. 2003; Finlayson et al. 2013). Sea-level rise may further affect changes to geomorphological processes triggered by precipitation change and shifts in vegetation structure.

Wetlands will also be exposed to increases in the intensity of many extreme climatic events, such as fires and cyclones. These processes are likely to affect the natural zonation of many wetland assemblages. In coastal wetlands, for example, the distribution of mangroves, saltmarsh and transitional coastal vegetation communities are likely to shift, although, in some cases, the physical nature of the landscape or built infrastructure will limit such expansion (Rogers et al. 2014).

Climate change affects wetland biota both directly and indirectly as a result of secondary effects on the abiotic character of wetlands. Collectively, these changes may mean that the environmental requirements of many species are no longer met or that their tolerance levels are exceeded in their present habitats (Schallenberg et al. 2003; Steffen et al. 2009). Some species may be able to adapt in situ, whereas others may respond by moving or retreating into refugial habitats (James et al. 2013). However, the rapid pace of current climate change is likely to exceed the capacity of many organisms to adapt in these ways (Visser 2008). Some wetland biota, including cosmopolitan and invasive species, may benefit from climate change and increase their abundances or ranges as a result. Nonetheless, changes to wetland species composition and extinctions are anticipated (Steffen et al. 2009).

The sensitivity of wetland ecosystems and their components and processes to climate change can be aggravated, or, in some cases, alleviated, by other stressors. Drying trends, for instance, are typically occurring in regions where human pressures on water resources are already high. Similarly, climate-change impacts may influence the sensitivity of wetland ecosystems to existing stressors. For example, lowland swamps are exposed to greater disturbance from altered water regimes in situations where they are already associated with flood-protection infrastructure (Dudley et al. 2010). The resilience of wetland systems, or the capacity to recover once a pressure is reduced, to different disturbances also varies considerably. Wetlands that have developed under dynamic and variable climatic conditions, e.g. desert wetlands, are often perceived as being more able to adapt to climate change (Füssel and Klein 2006). However, the intrinsic adaptive capacity of many wetland species and ecosystems to climatic changes, either by in situ adaptation (e.g. behavioural change or genetic adaptation) or through range shifts (e.g. contraction of population distributions to refuges), is likely to be significantly constrained by the many non-climatic human pressures to which many wetlands are subject (Capon et al. 2013; Finlayson et al. 2013; Saintilan et al. 2013; Bodmin et al. 2016).


Current policy context

Most existing international and national environmental institutions were established under the assumption that the environment is largely stationary, with natural variation in hydrology and other biophysical factors centring on a static mean (Milly et al. 2008). Consequently, inter-governmental conventions such as Ramsar, along with most national environmental laws, commonly have set targets for conservation policy and management either for specific sites, with defined boundaries, or populations of particular species, within certain ranges or abundances, or both. The Ramsar Convention has established the world’s largest network of protected areas with over 2240 sites, covering over 2.16 × 106 km2, given in the List of Wetlands of International Importance as of 2015 (www.ramsar.org; accessed 12 November 2016). Under the Convention, Contracting Parties are required to prepare and implement appropriate management plans for listed wetland sites and to report on adverse changes in their ecological character, which is defined as the combination of ecosystem components, processes and benefits/services that characterise a wetland at a given point in time (Finlayson et al. 2011). Conservation of wetland species is addressed by the Ramsar Convention through a focus on maintaining their habitats, especially areas important for the completion of life cycles and for migratory fauna. To conserve a representative range of wetland types, the Convention also relies on a classification system that defines wetland types on the basis of structural and functional categories (Finlayson 2017). However, listing of sites as Wetlands of International Importance has also led some Contracting Parties to emphasise the maintenance of the conservation values at the time of listing, rather than the restoration of previous values or consideration of the history of change in the wetland (Finlayson et al. 2016; Gell et al. 2016).

Increasing recognition that the past is no longer sufficient for understanding the future, is exposing institutional gaps in Australia, especially with regards to the provisions for managing important wetlands affected by climate change in the Ramsar Conventions (Pittock et al. 2010). In particular, Pittock et al. (2010) pointed to the Australian Government policy decision whereby a report of an adverse change in ecological character would not be made where climate change is the principal cause of a change until such time as the Convention provided guidance on an approach to this issue. Pittock et al. (2010) further contended that because climate change is human-induced, it should be treated in the same manner as other human-induced pressures, in line with the requirements under the Convention to report human-induced changes in the ecological character of Ramsar sites.

In addition to the conservation of internationally and nationally important wetland sites, many countries and institutions also have ‘no net loss’ wetland policies, requiring sites that are to be lost for development or other reasons to be off-set by wetland conservation elsewhere (Gardner et al. 2012). This concept has been adopted by the Ramsar Convention in relation to sites lost ‘in the urgent national interest’ or that have irretrievably lost the values for which they were listed. However, replacing wetland sites with ‘like for like’ is practically, politically and socially, very challenging (Pittock et al. 2010; Gardner et al. 2012). In recognition of the high level of wetland loss, a further global policy initiative has seen many national governments agree, under the Aichi Targets process of the Convention on Biological Diversity, to conserve at least 17% of the area of inland water ecosystems by 2020 (CBD 2010). However, in Australia (and at the global level), the conservation of existing freshwater protected areas and conservation planning continue to lag far behind the terrestrial and marine realms (Fitzsimons and Robertson 2005; Suski and Cooke 2007; Nel et al. 2009).

The Global Biodiversity Outlook and Global Environmental Outlook assessments position climate change, along with growing population, wealth and consumption, as one of several major global changes affecting the environment (SCBD 2010; UNEP 2012). However, although Contracting Parties to the Ramsar Convention have legal obligations to protect wetlands against negative, anthropogenic changes in ecological character, many climate-change impacts on wetlands and their species are beyond the influence of local wetland managers, e.g. changes in inter-continental habitat of migratory waterbirds (Pittock et al. 2010; Lukasiewicz et al. 2016). Furthermore, in contrast to those associated with non-climatic pressures, objectives and targets for wetland conservation in relation to climate change and climate adaptation are currently flexible and largely dependent on the regional policy position of Contracting Parties.

In addition to the policy direction provided by the Ramsar Convention, some Contracting Parties have policies that provide for climate-change planning for wetlands. Within New Zealand, the Resource Management Act (1991) and the recent National Policy Statement (NPS) for Freshwater Management (2014) both have provisions for decision makers to have regard for climate change. For example, the NPS directs municipal councils to consider the ‘reasonably foreseeable impacts of climate change’ when setting freshwater objectives and limits. Within Australia, the Water Act 2007 supports sustainable development of the water resources of the Murray–Darling Basin and other matters of national interest. The Act includes some consideration of climate-change adaptation, such as identification of climate change as a risk to water resources in the Basin, and identifies strategies to manage those risks. The Basin Plan that was developed as one component of the Act considers risks from climate change, aiming to improve knowledge on the impact of climate change on environmental water requirements, and ensuring that water-dependent ecosystems are resilient to climate change and variability, including extreme weather events. Although the Plan further aims to reduce consumptive diversions so as to buffer the impacts to the environment until more is known about the implications of climate change, this strategy has been criticised as inadequate (Pittock and Finlayson 2011; Pittock et al. 2015).


Setting objectives and targets for wetlands under climate change

The implications of climate change for wetland ecology necessitate a major review of conservation objectives and targets (Matthews and Wickel 2009; Catford et al. 2013). For the Ramsar Convention, the overarching issues raised by climate change concern what wetland policy and management should aim for, given that change in ecological character is highly probable under a changing climate. Solutions will differ depending on the broad adaptation strategy adopted by decision-makers (Table 1). The Convention has adopted an avoid–mitigate–compensate framework for maintaining the ecological character of wetlands (Gardner et al. 2012; Ramsar Convention 2012). This is supported by several decisions that recognise this three-stage approach, while imperatively avoiding wetland loss. Although not all Contracting Parties use the avoid–mitigate–compensate framework, they do often have a similar framework. However, the Ramsar Convention did not specifically link this framework with efforts to address the impacts of climate change on wetlands, possibly as a consequence of the reticence of the Convention to produce specific guidelines for addressing climate change (Finlayson 2013; Gell et al. 2016). The three broad steps in the avoid–mitigate–compensate framework in the context of climate change are outlined below.


Table 1.  Broad adaptation strategies and their implications for setting conservation objectives and targets
Click to zoom

(1) Avoiding climate change

In some cases, managers may seek to avoid the effects of climate-change impacts and, thereby, maintain existing objectives and targets. However, given the actual and projected impacts of climate change, this strategy is increasingly untenable, not to mention being expensive and risky (e.g. Capon et al. 2013; Kopf et al. 2015). Nevertheless, such an approach may be particularly appropriate in the short term for very high-value assets, whereas longer-term strategies can be developed and implemented.

(2) Accommodating or mitigating climate change

The intermediate strategy is to accommodate or mitigate climate change by choosing strategic, proactive interventions to retain a broader area and range of wetland types, more species and a greater diversity and value of ecosystem services. Setting objectives and targets for conservation that compensate for climate change involve significant societal choices regarding the ecological values for protection (or enhancement) and, therefore, the nature and scale of species and ecosystem types to be targeted. Consequently, transitioning to targets for wetland conservation policy and management that compensate for climate change requires deciding on what should be conserved, at what scale, and with what levels of uncertainty, for example, with respect to timing and impacts (Kopf et al. 2015).

(3) Accepting and compensating for climate change

An alternative strategy for setting conservation objectives and targets under a changing climate, in many ways diametrically opposed to the avoidance strategy, is to accept and compensate for the inevitability of changes or loss of values. Many of the probable ecological impacts of climate change, such as changes in species distributions, are largely beyond management control and, to some degree, must be accepted by society (e.g. Catford et al. 2013; Kopf et al. 2015). An acceptance strategy promotes the development of ‘open-ended’ conservation objectives that allow for a range of possible futures and support minimal levels of management intervention (Hughes 2011; Kopf et al. 2015). However, such an approach might be criticised for abandoning aspirational target-driven conservation goals and ignoring negative outcomes of human pressures (Hughes 2011). In this context, the acceptance of significant impacts from climate change may discourage wetland managers from taking direct action to rescue or otherwise defend these natural assets.

Even within the context of the avoid–mitigate–compensate framework, climate change will inevitably bring change to wetlands. Although climate change is affecting the character and distribution of wetlands, a similar diversity of wetland types as that which exists today is likely to persist under a changing climate, although some novel wetland types may also emerge (e.g. Catford et al. 2013). For example, although some coastal wetlands may be lost to sea-level rise or peat wetlands may be lost to drying, new wetlands of the same types may spontaneously develop (Pethick 2002; Acreman et al. 2009). Accommodating climate change, therefore, necessitates a greater emphasis on setting conservation targets at landscape, regional and even continental scales, such as, for example, protection of a range of wetland types, and the adoption of systematic conservation-planning principles such as those proposed by Margules and Pressey (2000) and Pressey et al. (2007). In such scenarios, at a site-scale, where most wetland management interventions necessarily occur, more open-ended, ‘acceptance’ conservation targets may be appropriate (Table 1). However, where a wetland is both highly valued and highly vulnerable to climate change, such as isolated, persistent desert lakes, highly interventional ‘avoid’ type targets may be appropriate, at least in the short term. With respect to wetland biota, this broadening of scale may require a focus on maintaining or restoring corridors for movement in response to shifting conditions, such as, for example, along rivers to cooler, higher altitudes (Lukasiewicz et al. 2013) and networks of wintering and migratory staging areas for migratory species (MacLean et al. 2008). Protection of refuges that enable wetland biota to persist in contracted ranges is also likely to be important (Davies 2010; Olden and Naiman 2010). However, some wetland species are unlikely to be able to migrate or survive in new locations because of barriers or the disappearance of suitable habitat (e.g. Bayliss et al. 1997; Davies 2010). In such cases, conservation targets may need either to accept some level of biodiversity loss or to conserve species through assisted translocation or ex situ conservation actions (e.g. seed banks; Capon et al. 2013).

Climate change also compels a broadening in the scope, as well as the scale, of wetland conservation targets. In particular, holistic approaches to adaptation necessitate a greater emphasis on ecological function rather than ecosystem structure alone, and social goals, including livelihoods, cultural values, community engagement and education, also require consideration. There is also a critical need to redress the current lack of indigenous participation in wetland management, including water allocation and catchment management in the intact, cultural landscapes of central and northern Australia (Jackson et al. 2005). Conservation targets for wetlands should include ecological functions and ecosystem services as well as key species, given that the Convention has included these within its definition of ecological character. An emphasis on ecological functions and ecosystem services can promote integrative adaptation strategies that incorporate a broader range of values and actions and limit the potential for maladaptation arising from overly narrow goals (Capon and Bunn 2015). In this sense, actions that are taken to avoid or reduce vulnerability in one system can often be maladaptive where they lead to greater vulnerability in other systems, sectors or social groups.


Adapting wetland management

In developing adaptation strategies for wetland management, decision-makers are faced with a confusing array of potential options (e.g. Pittock et al. 2012; Capon et al. 2013). However, whereas some of these might be considered transformative (e.g. species translocations), the majority of proposed adaptation measures are incremental and tend to involve existing tools and strategies presented within a framework of risk and uncertainty and may even be maladaptive in some contexts (Lukasiewicz et al. 2013, 2016).

The spatial extent or scope of existing management efforts, for example, may vary in relation to predicted climate-change impacts, such as, for example, greater focus on specific pest species that are likely to become more prevalent under climate change or protection of areas predicted to become future biodiversity hotspots. In general, proposed adaptation actions are designed either to build resilience to climate change through the management of existing threats, strengthening of protected area networks or ecosystem restoration, or are otherwise designed to address specific issues associated with exposure and sensitivity to climate change through ‘hard’ or ecological engineering actions (Capon et al. 2013; Lukasiewicz et al. 2013, 2016). Although there are limits to what protected-area design can achieve in terms of climate-change adaptation, enhancing protected-area management can help reduce non-climatic stresses and increase resilience of the ecosystem, as well as enabling efficient adaptive management (Pittock et al. 2008, Olds et al. 2014). ‘Soft’ adaptation measures that promote cultural and institutional change, for example, education, are also likely to be essential for effective adaptation to climate change.

Determining adaptation priorities presents a major challenge for wetland managers and requires a flexible, reflective and responsive approach to planning and management. Key factors influencing the selection of adaptation measures include their cost, likely efficacy, potential benefits (including additional benefits beyond adaptation), reversibility, stakeholder support, risk of failure and risk of maladaptation or perverse outcomes (Lukasiewicz et al. 2013). Because climate-change risks and uncertainties change over time as new information becomes available or the biophysical and socio-political context shifts, these considerations will also change, necessitating different adaptation decisions at different times. Consequently, we recommend that in developing a toolkit of adaptation options for Ramsar wetland managers, potential actions might be considered in relation to three broad phases or timeframes (i.e. now, soon and eventually) that may also accord with a growing severity of climate-change impacts (Table 2).


Table 2.  Adaptation phases for wetland management, with examples of relevant adaptation measures and information needs
Click to zoom

(1) Adapting now

In the first phase (‘now’), adaptation actions should focus on building wetland resilience to predicted climate-change impacts. In particular, adaptation strategies might have at their core the early implementation of ‘no-regret’ actions that protect or restore ecological character and contribute to ecological resilience or resistance against future climate-change impacts. For wetlands, such measures will include actions that address existing, non-climatic pressures (e.g. pollution; Robertson and Funnell 2012) and, in many cases, restore or rehabilitate major ecosystem components subject to human modification, such as, for example, flow regimes, physical morphology and vegetation structure (Schallenberg et al. 2010; Bino et al. 2014a). At regional scales, actions associated with improved catchment management, especially the protection and restoration of connectivity within and among wetland habitats, will also build climate resilience for individual wetlands as well as for ecological processes that occur over landscape scales.

Flexible governance (i.e. the ability of institutions and communities to adapt in a changing environment) and rigorous adaptive co-management are essential for the effective management of complex, socio-ecological systems (Armitage et al. 2009; Plummer 2013). In many cases, planning and implementation of actions in the first phase of an adaptation strategy will necessitate supporting changes in governance to improve alignment in policy, reduce redundancy in planning and maximise cross-sectoral efficiencies and benefits. Similarly, developing adaptive co-management frameworks can facilitate a pathway through highly complex, multilevel, hydrological, ecological and social processes (and institutional arrangements). Whereas watershed- or catchment-scale management remains the key spatial framework, ultimately, integration of governance, legislative and regulatory frameworks across sectors and scales is essential for effective wetland management (Kingsford et al. 2011).

Local-scale, ‘bottom-up’, co-management frameworks also provide an effective approach to developing integrated, participatory and adaptive governance arrangements, particularly because they can be tailored to specific socio-ecological contexts (Berkes 2009). These may be particularly effective for managing wetlands in remote, decentralised regions, such as many of the indigenous cultural estates in central and northern Australia where socio-ecological systems are highly varied and complex, and local cultural and livelihood values and community management aspirations are high (Jackson et al. 2005). These community-based, participatory adaptation planning arrangements can also facilitate the consideration of a wider range of climate-change impacts and adaptation options and further enable the development of ‘bottom-up’ vulnerability assessments, management strategies and monitoring designs (e.g. Bino et al. 2014a).

Implementing governance arrangements that ensure the timely collection and assessment of information regarding wetland vulnerability, climate-change impacts and other pressures is also likely to be critical in the first phase of any adaptation strategy. Decisions made in later phases will strongly depend on ecological response models based on appropriate observations and understanding of long-term changes in the ecological character (Finlayson et al. 2016). Knowledge of ecosystem services provided by wetlands, and the ecological patterns and processes underpinning these, will also be crucial for decisions regarding the priorities for adaptation action (Capon and Bunn 2015).

(2) Adapting soon

In the second phase (‘soon’), actions will need to be more closely related to particular climate-change effects occurring within the specific biophysical context of concern. Wetland managers will have to grapple with impacts that transpire despite global mitigation efforts, while also addressing new and stronger anthropogenic pressures that occur in response to climate change (e.g. higher demand for water resources; Capon et al. 2013). The use of formal decision support systems such as Bayesian belief networks (Ticehurst et al. 2007, Gawne et al. 2012) and multi-criteria decision analysis (Zsuffa et al. 2013), which are easily iterated with updated information, may prove useful in the adaptive management of wetlands within the context of climate change.

Existing management approaches for dealing with such pressures may need to be substantially revised where threats are exacerbated by climate change directly or indirectly as a result of interactions among multiple stressors. If adaptive management strategies, including monitoring, and other flexible governance arrangements, have been effectively implemented in phase one, decision-making in this second phase of adaptation should be informed by a greater understanding of wetland vulnerabilities and likely responses to impacts. This may enable more direct attention to climate-change effects in wetland management and the consideration of more explicit adaptation actions such as land acquisition in areas adjacent to wetlands or significant changes to water management regimes.

(3) Adapting eventually

In the third phase (‘eventually’), more transformative adaptation options may be required to protect highly valued wetland components and services where these are also highly threatened by direct and indirect climate-change impacts. This may involve the use of hard infrastructure to protect some wetland assets, ecological-engineering techniques that promote in situ transformation (e.g. over-restoration such as planting riparian zones with fast-growing, high-shade species) or the assisted translocation of wetland assets (e.g. species; Capon et al. 2013). In each of these cases, actions to protect specific high-value wetland assets or ecosystem services are likely to entail a magnified risk to non-targeted assets and services, as well as a higher degree of failure, and thus should be implemented with safety margins and regular reviews (Capon et al. 2013; Capon and Bunn 2015). These risks are illustrated by the negative consequences of the ‘environmental works and measures’ (infrastructure) being implemented in the Murray–Darling Basin (Pittock et al. 2012). In other cases, threats to wetlands may be so great that such adaptation options are perceived to exceed reasonable levels of expense and risk. Consequently, sacrifice of some wetlands may be required, such as, for example, delisting Ramsar Sites from the Ramsar Convention or relinquishing previous management regimes, although these are very likely to be seen as measures of last resort, such as outlined by the Ramsar Convention for delisting of sites (Pittock et al. 2010). Investment may be more effectively directed in these instances, by offset programs, to areas that are less vulnerable to climate change or that support new or improved ecosystem services.

In sequencing adaptation options through these three phases, it is important that trigger points and thresholds are identified through monitoring to help determine when new actions should be implemented. This helps keep options open and avoids path dependency, but importantly too, avoids unnecessary expenditure. Thresholds can account for the ability of a wetland to survive in its current form and may define particular wetland conditions, which, once attained, indicate that a different management approach or phase is required (Barnett et al. 2014; Wise et al. 2014).


Monitoring and evaluation

Monitoring and evaluation are two essential inter-related prerequisites of any management-planning framework for wetlands (Finlayson 1996a, 1996b; Ramsar Convention Secretariat 2010a), and are expected to be more critical under a climate-affected future where assessing change and responses to adaptation will be important (Pittock et al. 2010). Set up properly, monitoring and evaluation underpin the feedback loops of management frameworks to track the success and failure of management strategies and the ability to achieve agreed conservation objectives. Although the Ramsar Convention provides guidance for establishing monitoring programs and management plans (Finlayson 1996a; Ramsar Convention Secretariat 2010a), these have not specifically considered the projected impacts of climate change.

The Ramsar Convention defines monitoring as a hypothesis-based exercise, to differentiate it from the more general ‘surveillance’ and ‘survey’ activities that are often conducted in many wetlands (Finlayson 1996b; Finlayson et al. 1999; Ramsar Convention Secretariat 2010a). Monitoring is based on the selection of indicators that are used to determine the extent of change that has occurred in a wetland and whether this exceeds either an ecological or a management threshold. However, because there can be significant uncertainties about how the climate will change over time, and how those changes will manifest themselves on wetlands, it may prove difficult to identify plausible thresholds that can then be tested. These uncertainties are likely to be minor in the short term and increase over time; however, uncertainties will are likely to vary, given that climate projections indicate a range of possible scenarios for wetlands.

The use of indicators suitable for reporting on multiple stressors, including climate change, could promote greater efficiency and broader adoption by natural resource-management agencies. For example, national monitoring of water quality in New Zealand lakes is required for State of the Environment reports and enables long-term assessment of temperature-induced changes on lake systems (Hamilton et al. 2013). However, experience in the Murray–Darling Basin in south-eastern Australia has shown that data collected for one purpose may not be suitable for addressing other aims, at times being inconclusive or punctuated by gaps, and open to contradictory interpretations (Colloff et al. 2015; Kingsford et al. 2015).

When considering what to monitor, or what indicators to use, a variety of social, economic and environmental criteria should be considered. The choice of an ecological indicator is a critical step for supporting management actions, because a failure to detect thresholds in an ecosystem or species can significantly affect decision making and ignore important information (Eiswerth and Haney 2001). Given limited resources, biotic surrogates of wetland condition have often been used, and these should be easily detectable, measurable and sensitive to ecological change. Waterbirds, among the more conspicuous of wetland animals, are a vital component of wetland function, and have been regularly used as indicators of the condition of a wetland (Kingsford and Auld 2005; Bino et al. 2014b). Native freshwater fish and invertebrate communities are also directly influenced by changes in flow regimes (Death et al. 2016), making them potential climate response indicators. Wetland vegetation is strongly influenced by hydrological changes and is commonly used as an indicator of the condition of a wetland (Clarkson et al. 2004; DSE 2007). Physico-chemical indicators that are used to monitor trends in ecological processes, such as water regimes, are important for evaluating the cause of biotic shifts (Schallenberg et al. 2003, 2010).

The Ramsar Convention has recommended monitoring early warning indicators whenever feasible, but also points out that many indicators with high ecological relevance, such as waterbirds or fish, may not provide sufficient early warning (van Dam et al. 1999; Ramsar Convention Secretariat 2010b). Indicators that provide early detection capabilities (e.g. physiological indicators) may be different from ecological indicators that would be selected to monitor the state of key ecological values of wetlands (see Table 3). This is an important consideration and, given limited resources to address wetland management issues, may provide a basis for a clear understanding of the value of monitoring and the capacity to understand both the extent and cause of change and its significance. The Convention has considered the limits of acceptable change in wetlands (Ramsar Convention Secretariat 2012), but has not provided guidance for the establishment of such limits.


Table 3.  Link between the ecological relevance and early warning capability of indicators used for measuring change in wetlands
Adapted from van Dam et al. (1999)
Click to zoom

Identifying trigger levels and thresholds indicating when new actions should be implemented, is also required. Trigger levels should include consideration of the lead-up times required for the actions to come into effect, including time for engagement with stakeholders and accessing funding. As actions become more transformative and potentially controversial, longer lead-up times for stakeholder engagement may be required. Engaging with stakeholders and realising the benefits that can accrue from citizen science can assist with obtaining the information needed for identifying limits of change and triggers. The Convention has also recognised the importance of engaging with local communities and indigenous peoples to support wetland management and monitoring, as has occurred in both Australia and New Zealand (Townsend et al. 2004; Ens et al. 2012).

There has been increasing interest in the use of conceptual models to determine how and when changes in wetlands may become obvious and to illustrate the links between cause and effect. Models of ecosystem behaviour, such as state and transition models (STMs or S&T models), can provide flexible conceptual frameworks of change (Westoby et al. 1989) and are fully compatible with approaches suggested by the Convention for describing the ecological character of a wetland and evaluating the extent or importance of any change. STMs are grounded on the concept of a collection of possible alternative states, each with a domain of requirements, separated by thresholds of transitions between states (Briske et al. 2008). State and transition models are particularly useful to communicate understanding of ecosystem dynamics among scientists, managers and policy makers (Ludwig et al. 1996), as well as in identifying alternative management opportunities (Czembor and Vesk 2009; Bino et al. 2013). There is a real need for selecting indicators and monitoring approaches that can signal that a system is nearing a threshold or tipping point (Capon et al. 2015).

As climate change intensifies, potentially surpassing those changes brought about by river regulation or agriculture-induced nutrient loading, established adaptive management approaches will need to be revised because changes from climate may become apparent faster than changes as a result of management.

This requires a change in attitude towards ongoing quantitative monitoring, aimed at assessing the outcomes of management actions and to continuously improve ecological response models. Through the application of vulnerability and risk-assessment approaches, it is feasible to focus on those biogeographical regions where the projected impacts caused by climate change are cause for concern. For example, reduced rainfall is expected to occur in the northern and eastern areas of New Zealand and the predicted reductions in rainfall are most likely to affect bog and gumland wetland types in New Zealand (Bodmin et al. 2016). In Australia, greatest rainfall reduction is expected to occur in southern Australia (CSIRO and Bureau of Meteorology 2015). Conceptualisation of the risk of climate change has been used to consider the consequences for wetlands along the Murray River, located in this region. (Pittock and Finlayson 2011). The Ramsar Convention has provided guidance for risk and vulnerability assessment (van Dam et al. 1999; Gitay et al. 2011) within an integrated framework for inventory, assessment and monitoring (Ramsar Convention Secretariat 2010b).

Evaluation provides an opportunity to integrate the results from monitoring, along with feedback from stakeholders about particular wetlands within the scope of an appropriate management plan. It enables decisions to be made about what has been achieved, what changes should be implemented, and what information is available for sharing with stakeholders. The evaluation process can be broken up into three cycles with varying time-scales, dependent on the inherent dynamics of the system. The first relates to the evaluation of whether management actions are successful in achieving set goals, and either re-validating management strategies or developing new ones accordingly. The second evaluates the accuracy of the underlying model of the system, on which management strategies were initially developed. The third evaluates the success or failure to reach desired states and whether there is a need to change goals and objectives to more tangible ones. The outcomes of the evaluation will also inform, for Ramsar Sites, the urgency in responding to likely or actual human-induced changes in the ecological character of a wetland.


Principles for adapting wetland policy and management under climate change

Our examination of the implications of climate change for wetland policy and management was based on the three questions presented in the Introduction. We conclude with a set of key principles to inform wetland conservation and management policy within the context of climate change; these are as follows:

  1. Objectives and targets for wetland management should look mainly (but not exclusively) to accommodate and compensate for climate change, rather than accepting or avoiding impacts, especially in early phases of adaptation.

  2. Given expected changes in wetland species and habitats this is more likely to be achievable by emphasising the benefits that can accrue by protecting wetland functions and ecosystem services as well as (or instead of) key species.

  3. Objectives for wetland management under climate change should include ecological, social and economic targets across multiple scales and consider ecological issues including representativeness, connectivity and refugial values.

  4. Setting such objectives and targets will involve significant societal choices and will rest on decisions concerning what should be conserved and at what scale. In some cases, it may be necessary to accept some level of biodiversity loss.

  5. Flexible, governance and adaptive co-management frameworks across multiple scales and sectors are essential to managing wetlands under climate change.

  6. Such frameworks should each be specific to a given situation, reflecting the diversity and complexity of social-ecological systems.

  7. Easily reversed, no-regret or low-regret adaptation options with multiple, cross-sectoral benefits should be implemented in the initial phases of adapting wetland management.

  8. This should be in concert with the introduction or strengthening of adaptive management frameworks, especially relevant monitoring and spatial decision-support tools (to explore trade-offs and build consensus).

  9. Long-term management strategies should identify triggers for new actions, including novel or high-risk adaptation options (e.g. species translocations) and should plan for such eventualities.

  10. It may be difficult to identify such triggers, given significant uncertainties about the rates and directions of climate change as well as the particular responses of wetlands. Conceptual modelling may assist with the identification of triggers.

  11. Scientific monitoring and evaluation of management strategies are needed.

  12. This is to enable decisions to be made about what has been achieved, what changes and trade-offs should be implemented, whether there is a need to modify goals and objectives, and what information is available for sharing with stakeholders.

Research should focus on determining relationships between ecological patterns and processes and wetland values and ecosystem services and how these may respond to climate change and management actions. Although the Ramsar Convention has prepared extensive guidance for Contracting Parties on how to implement appropriate management plans for listed wetlands and to report on adverse change in their ecological character, it has not delivered specific guidance on how to respond to these in the context of climate change. With this in mind, the above-described principles are intended as a step to address this gap and provide wetland managers with guidance on responding to the increasingly dire condition of wetlands worldwide, which, in many cases, will be exacerbated by climate change.



Acknowledgements

This paper was developed through a workshop organised by the Society for Wetland Scientists Oceania (SWSO) with financial support from the National Climate Change Adaptation Research Facility (NCCARF), logistical support from the Institute for Land, Water and Society (ILWS) at Charles Sturt University, and the Arthur Rylah Institute (ARI) which assisted with local arrangements and provided the venue.


References

Acreman, M. C., Blake, J. R., Booker, D. J., Harding, R. J., Reynard, N., Mountford, J. O., and Stratford, C. J. (2009). A simple framework for evaluating regional wetland ecohydrological response to climate change with case studies from Great Britain. Ecohydrology 2, 1–17.
A simple framework for evaluating regional wetland ecohydrological response to climate change with case studies from Great Britain.Crossref | GoogleScholarGoogle Scholar |

Armitage, D. R., Plummer, R., Berkes, F., Arthur, R. I., Davidson-Hunt, I. J., Diduck, A., Doubleday, N. C., Johnson, D. S., Marschke, M., McConney, P., Pinkerton, E. W., and Wollenberg, E. K. (2009). Adaptive co-management for social-ecological complexity. Frontiers in Ecology and the Environment 7, 95–102.
Adaptive co-management for social-ecological complexity.Crossref | GoogleScholarGoogle Scholar |

Barnett, J., Graham, S., Mortreux, C., Fincher, R., Waters, E., and Hurlimann, A. (2014). A local coastal adaptation pathway. Nature Climate Change 4, 1103–1108.
A local coastal adaptation pathway.Crossref | GoogleScholarGoogle Scholar |

Bayliss, B. L., Brennan, K. G., Eliot, I., Finlayson, C. M., Hall, R. N., House, T., Pidgeon, R. W. J., Walden, D., and Waterman, P. (1997). Vulnerability assessment of the possible effects of predicted climate change and sea level rise in the Alligator Rivers Region, Northern Territory, Australia. Supervising Scientist Report 123, Supervising Scientist, Canberra, ACT, Australia.

Berkes, F. (2009). Evolution of co-management: role of knowledge generation, bridging organizations and social learning. Journal of Environmental Management 90, 1692–1702.
Evolution of co-management: role of knowledge generation, bridging organizations and social learning.Crossref | GoogleScholarGoogle Scholar |

Bino, G., Jenkins, K., and Kingsford, R. (2013). ‘Adaptive Management of Ramsar Wetlands.’ (National Climate Change Adaptation Research Facility: Gold Coast, Qld, Australia.)

Bino, G., Kingsford, R., and Porter, J. (2014a). ‘Setting Waterbird Objective and Priorities for the Basin-wide Environmental Watering Strategy.’ (Murray–Darling Basin Authority: Canberra, ACT, Australia.)

Bino, G., Steinfeld, C., and Kingsford, R. T. (2014b). Maximizing colonial waterbirds’ breeding events using identified ecological thresholds and environmental flow management. Ecological Applications 24, 142–157.
Maximizing colonial waterbirds’ breeding events using identified ecological thresholds and environmental flow management.Crossref | GoogleScholarGoogle Scholar |

BMT WBM (2010). Kakadu – vulnerability to climate change impacts. A report to the Australian Government Department of Climate Change and Energy Efficiency. Department of Climate Change and Energy Efficiency, Canberra, ACT, Australia.

Bodmin, K., Ausseil, A.-G., and Zammit, C. (2016). Wetland ecosystems. In ‘Freshwater Conservation under a Changing Climate, Proceedings of a Workshop Hosted by Department of Conservation’, 10–11 December 2013, Wellington, New Zealand. (Eds H. Robertson, S. Bowie, R. Death, and D. Collins.) pp. 31–35. (Department of Conservation: Wellington, New Zealand.)

Briske, D., Bestelmeyer, B., Stringham, T., and Shaver, P. (2008). Recommendations for development of resilience-based state-and-transition models. Rangeland Ecology and Management 61, 359–367.
Recommendations for development of resilience-based state-and-transition models.Crossref | GoogleScholarGoogle Scholar |

Capon, S. J., and Bunn, S. E. (2015). Assessing climate change risks and prioritising adaptation options using a water ecosystem services-based approach. In ‘Water Ecosystem Services’. (Eds J. Martin-Ortega, R. C. Ferreir, I. J. Gordon, and S. Kahn.) pp. 17–26. (Cambridge University Press: Cambridge, UK.)

Capon, S. J., Chambers, L. E., MacNally, R., Naiman, R. J., Davies, P., Marshall, N., Pittock, J., Reid, M., Capon, T., Douglas, M., and Catford, J. (2013). Riparian ecosystems in the 21st century: hotspots for climate change adaptation? Ecosystems 16, 359–381.
Riparian ecosystems in the 21st century: hotspots for climate change adaptation?Crossref | GoogleScholarGoogle Scholar |

Capon, S. J., Lynch, A. J., Bond, N., Chessman, B. C., Davis, J., Davidson, N., Finlayson, M., Gell, P. A., Hohnberg, D., Humphrey, C., and Kingsford, R. T. (2015). Regime shifts, thresholds and multiple stable states in freshwater ecosystems; a critical appraisal of the evidence. The Science of the Total Environment 534, 122–130.
Regime shifts, thresholds and multiple stable states in freshwater ecosystems; a critical appraisal of the evidence.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC2MXivVCns70%3D&md5=df6051721de199bdb295fad372f9ce9cCAS |

Catford, J., Naiman, R., Chambers, L., Roberts, J., Douglas, M., and Davies, P. (2013). Predicting novel riparian ecosystems in a changing climate. Ecosystems 16, 382–400.
Predicting novel riparian ecosystems in a changing climate.Crossref | GoogleScholarGoogle Scholar |

CBD (2010). Aichi biodiversity targets. In ‘Convention on Biological Diversity’ (Secretariat of the Convention on Biological Diversity: Montreal, QC, Canada.) Available at https://www.cbd.int/sp/targets/ [Verified 4 February 2017].

Clarkson, B. R., Sorrell, B. K., Reeves, P. N., Champion, P. D., Partridge, T. R., and Clarkson, B. D. (2004). ‘Handbook for Monitoring Wetland Condition. Coordinated Monitoring of New Zealand Wetlands.’ (Ministry for the Environment: Wellington, New Zealand.)10.7931/J2Z60KZ3

Colloff, M. J., Caley, P., Saintilan, N., Pollino, C. A., and Crossman, N. D. (2015). Long-term ecological trends of flow-dependent ecosystems in a major regulated river basin. Marine and Freshwater Research 66, 957–969.
Long-term ecological trends of flow-dependent ecosystems in a major regulated river basin.Crossref | GoogleScholarGoogle Scholar |

CSIRO and Bureau of Meteorology (2015). Climate change in Australia information for Australia’s natural resource management regions: Technical report, CSIRO and Bureau of Meteorology, Canberra, ACT, Australia.

Czembor, C. A., and Vesk, P. A. (2009). Incorporating between-expert uncertainty into state-and-transition simulation models for forest restoration. Forest Ecology and Management 259, 165–175.
Incorporating between-expert uncertainty into state-and-transition simulation models for forest restoration.Crossref | GoogleScholarGoogle Scholar |

Davidson, N. C. (2014). How much wetland has the world lost? Long-term and recent trends in global wetland area. Marine and Freshwater Research 65, 934–941.
How much wetland has the world lost? Long-term and recent trends in global wetland area.Crossref | GoogleScholarGoogle Scholar |

Davies, P. M. (2010). Climate change implications for river restoration in global biodiversity hotspots. Restoration Ecology 18, 261–268.
Climate change implications for river restoration in global biodiversity hotspots.Crossref | GoogleScholarGoogle Scholar |

Davis, J., and Brock, M. (2008). Detecting unacceptable change in the ecological character of Ramsar wetlands. Ecological Management & Restoration 9, 26–32.
Detecting unacceptable change in the ecological character of Ramsar wetlands.Crossref | GoogleScholarGoogle Scholar |

Day, J. W., Christian, R. R., Boesch, D. M., Yáñez-Arancibia, A., Morris, J., Twilley, R. R., Naylor, L., and Schaffner, L. (2008). Consequences of climate change on the ecogeomorphology of coastal wetlands. Estuaries and Coasts 31, 477–491.
Consequences of climate change on the ecogeomorphology of coastal wetlands.Crossref | GoogleScholarGoogle Scholar |

Death, D., Bowie, S., and O’Donnell, C. (2016). River ecosystems. In ‘Freshwater Conservation under a Changing Climate: Proceedings of a Workshop Hosted by Department of Conservation’, 10–11 December 2013, Wellington, New Zealand. (Eds H. Robertson, S. Bowie, R. Death, and D. Collins.) pp. 14–23. (Department of Conservation: Wellington, New Zealand.)

DEWHA (2008). ‘National Framework and Guidance for Describing the Ecological Character of Australia’s Ramsar Wetlands: Module 2 of the National Guidelines for Ramsar Wetlands – Implementing the Ramsar Convention in Australia.’ (Australian Government Department of the Environment, Water, Heritage and the Arts: Canberra, ACT, Australia.)

DSE (2007). ‘Index of Wetland Condition: Review of Wetland Assessment Methods.’ (Department of Sustainability and Environment: Melbourne, Vic., Australia.)

Dudley, N., Stolton, S., Belokurov, A., Krueger, L., Lopoukhine, N., MacKinnon, K., Sandwith, T., and Sekhran, N. (2010). ‘Natural Solutions: Protected Areas Helping People Cope with Climate Change.’ (International Union for Conservation of Nature World Commission on Protected Areas: Gland, Switzerland; The Nature Conservancy: Arlington, VA, USA; United Nations Development Programme: New York, NY, USA; Wildlife Conservation Society: New York, NY, USA; The World Bank: Washington, DC, USA; and World Wide Fund For Nature: Gland, Switzerland.)

Eiswerth, M. E., and Haney, J. C. (2001). Maximizing conserved biodiversity: why ecosystem indicators and thresholds matter. Ecological Economics 38, 259–274.
Maximizing conserved biodiversity: why ecosystem indicators and thresholds matter.Crossref | GoogleScholarGoogle Scholar |

Eliot, I., Finlayson, C. M., and Waterman, P. (1999). Predicted climate change, sea level rise and wetland management in the Australian wet–dry tropics. Wetlands Ecology and Management 7, 63–81.
Predicted climate change, sea level rise and wetland management in the Australian wet–dry tropics.Crossref | GoogleScholarGoogle Scholar |

Ens, E. J., Finlayson, M., Preuss, K., Jackson, S., and Holcombe, S. (2012). Australian approaches for managing ‘country’ using Indigenous and non-Indigenous knowledge. Ecological Management & Restoration 13, 100–107.
Australian approaches for managing ‘country’ using Indigenous and non-Indigenous knowledge.Crossref | GoogleScholarGoogle Scholar |

Finlayson, C. M. (1996a). The Montreux Record: a mechanism for supporting the wise use of wetlands. In ‘Proceedings of the 6th Meeting of the Conference of the Contracting Parties of the Convention on Wetlands. Technical Sessions: Reports and Presentations’, 19–27 March 1996, Brisbane, Qld, Australia. Vol. 10/12 B, pp. 32–37. (Ramsar Convention Bureau: Gland, Switzerland.)

Finlayson, C. M. (1996b). Framework for designing a monitoring programme. In ‘Monitoring Mediterranean Wetlands: a Methodological Guide’. (Ed. P. T. Vives.) pp. 25–34. (MedWet Publication, Wetlands International: Slimbridge, UK; and ICN: Lisbon, Portugal.)

Finlayson, C. M. (2012). Forty years of wetland conservation and wise use. Aquatic Conservation: Marine and Freshwater Ecosystems 22, 139–143.
Forty years of wetland conservation and wise use.Crossref | GoogleScholarGoogle Scholar |

Finlayson, C. M. (2013). Climate change and the wise use of wetlands: information from Australian wetlands. Hydrobiologia 708, 145–152.
Climate change and the wise use of wetlands: information from Australian wetlands.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3sXls1eis7c%3D&md5=8f51eb6507734fbb7832a7882a7be183CAS |

Finlayson, C. M. (2017). Ramsar Convention typology of wetlands. In ‘The Wetland Book I: Structure and Function, Management and Methods’. (Eds C. M. Finlayson, M. Everard, K. Irvine, R. J. McInnes, B. A. Middleton, A. A. van Dam, and N. C. Davidson.) (Springer Publishers: Dordrecht, Netherlands.)10.1007/978-94-007-6172-8_339-1

Finlayson, C. M., and D’Cruz, R. (2005). Inland water systems. In ‘Ecosystems and Human Well-being: Current State and Trends: Findings of the Condition and Trends Working Group’. (Eds R. Hassan, R. Scholes, and N. Ash.) pp. 551–583. (Island Press: Washington, DC, USA.)

Finlayson, C., Davidson, N., Spiers, A., and Stevenson, N. (1999). Global wetland inventory: current status and future priorities. Marine and Freshwater Research 50, 717–727.
Global wetland inventory: current status and future priorities.Crossref | GoogleScholarGoogle Scholar |

Finlayson, C. M., Bellio, M., and Lowry, J. B. (2005). A conceptual basis for the wise use of wetlands in northern Australia: linking information needs, integrated analyses, drivers of change and human well-being. Marine and Freshwater Research 56, 269–277.
A conceptual basis for the wise use of wetlands in northern Australia: linking information needs, integrated analyses, drivers of change and human well-being.Crossref | GoogleScholarGoogle Scholar |

Finlayson, C. M., Gitay, H., Bellio, M., van Dam, R. A., and Taylor, I. (2006). Climate variability and change and other pressures on wetlands and waterbirds: impacts and adaptation. In ‘Water Birds around the World’. (Eds G. Boere, C. Gailbraith, and D. Stroud.) pp. 88–97. (Scottish Natural Heritage: Edinburgh, UK.)

Finlayson, C. M., Davidson, N., Pritchard, D., Milton, G. R., and MacKay, H. (2011). The Ramsar Convention and ecosystem-based approaches to the wise use and sustainable development of wetlands. Journal of International Wildlife Law and Policy 14, 176–198.

Finlayson, C. M., Davis, J. A., Gell, P. A., Kingsford, R. T., and Parton, K. A. (2013). The status of wetlands and the predicted effects of global climate change: the situation in Australia. Aquatic Sciences 75, 73–93.
The status of wetlands and the predicted effects of global climate change: the situation in Australia.Crossref | GoogleScholarGoogle Scholar |

Finlayson, C. M., Clarke, S. J., Davidson, N. C., and Gell, P. (2016). Role of palaeoecology in describing the ecological character of wetlands. Marine and Freshwater Research 67, 687–694.
Role of palaeoecology in describing the ecological character of wetlands.Crossref | GoogleScholarGoogle Scholar |

Fitzsimons, J. A., and Robertson, H. A. (2005). Freshwater reserves in Australia: directions and challenges for the development of a comprehensive, adequate and representative system of protected areas. Hydrobiologia 552, 87–97.
Freshwater reserves in Australia: directions and challenges for the development of a comprehensive, adequate and representative system of protected areas.Crossref | GoogleScholarGoogle Scholar |

Freeman, C., Lock, M. A., and Reynolds, B. (1993). Climatic change and the release of immobilized nutrients from Welsh riparian wetland soils. Ecological Engineering 2, 367–373.
Climatic change and the release of immobilized nutrients from Welsh riparian wetland soils.Crossref | GoogleScholarGoogle Scholar |

Füssel, H.-M., and Klein, R. J. T. (2006). Climate change vulnerability assessments: an evolution of conceptual thinking. Climatic Change 75, 301–329.
Climate change vulnerability assessments: an evolution of conceptual thinking.Crossref | GoogleScholarGoogle Scholar |

Gardner, R. C., and Davidson, N. C. (2011). The Ramsar Convention. In ‘Wetlands: Integrating Multidisciplinary Concepts’. (Ed. B. Lepage.) pp. 189–203. (Springer: Dordrecht, Netherlands.)

Gardner, R. C., Bonells, M., Okuno, E., and Zarama, J. M. (2012). Avoiding, mitigating, and compensating for loss and degradation of wetlands in national laws and policies. Ramsar scientific and technical briefing note number 3. Ramsar Convention Secretariat, Gland, Switzerland.

Gardner, R. C., Barchiesi, S., Beltrame, C., Finlayson, C. M., Galewski, T., Harrison, I., Paganini, M., Perennou, C., Pritchard, D. E., Rosenqvist, A., and Walpole, M. (2015). State of the World’s Wetlands and their services to people: a compilation of recent analyses. Ramsar scientific and technical briefing note number 7. Ramsar Convention Secretariat, Gland, Switzerland.

Gawne, B., Price, A., Koehn, J. D., King, A. J., Nielson, D. L., Meredith, S., Beesley, L., and Vilizzi, L. (2012). A Bayesian belief network decision support tool for watering wetlands to maximise native fish outcomes. Wetlands 32, 277–287.
A Bayesian belief network decision support tool for watering wetlands to maximise native fish outcomes.Crossref | GoogleScholarGoogle Scholar |

Gell, P. A., Finlayson, C. M., and Davidson, N. C. (2016). Understanding change in the ecological character of Ramsar wetlands: perspectives from a deeper time: synthesis. Marine and Freshwater Research 67, 869–879.
Understanding change in the ecological character of Ramsar wetlands: perspectives from a deeper time: synthesis.Crossref | GoogleScholarGoogle Scholar |

Gitay, H., Finlayson, C. M., and Davidson, N. C. (2011). A framework for assessing the vulnerability of wetlands to climate change. Ramsar technical report number 5/CBD technical series number 57. Ramsar Convention Secretariat, Gland, Switzerland; and Secretariat of the Convention on Biological Diversity, Montreal, QC, Canada.

Goudie, A. S. (2006). Global warming and fluvial geomorphology. Geomorphology 79, 384–394.
Global warming and fluvial geomorphology.Crossref | GoogleScholarGoogle Scholar |

Hamilton, D. P., McBride, C. G., Özkundakci, D., Schallenberg, M., Verburg, P., de Winton, M., Kelly, D., Hendy, C., and Ye, W. (2013). Effects of climate change on New Zealand Lakes. In ‘Climate Change and Inland Waters: Impacts and Mitigation for Ecosystems and Societies’. (Eds C. R. Goldman, M. Kumagai, and R. D. Robarts.) pp. 337–366. (Wiley: Oxford, UK.)

Hughes, L. (2011). Climate change and Australia: key vulnerable regions. Regional Environmental Change 11, 189–195.
Climate change and Australia: key vulnerable regions.Crossref | GoogleScholarGoogle Scholar |

Jackson, S., Storrs, M., and Morrison, J. (2005). Recognition of Aboriginal rights, interests and values in river research and management: perspectives from northern Australia. Ecological Management & Restoration 6, 105–110.
Recognition of Aboriginal rights, interests and values in river research and management: perspectives from northern Australia.Crossref | GoogleScholarGoogle Scholar |

James, C., Van Der Wal, J., Capon, S., Hodgson, L., Waltham, N., Ward, D., Anderson, B., and Pearson, R. (2013). ‘Identifying Climate Refuges for Freshwater Biodiversity across Australia.’ (National Climate Change Adaptation Research Facility: Gold Coast, Qld, Australia.)

Junk, W. J., An, S., Finlayson, C. M., Gopal, B., Květ, J., Mitchell, S. A., Mitsch, W. J., and Robarts, R. D. (2013). Current state of knowledge regarding the world’s wetlands and their future under global climate change: a synthesis. Aquatic Sciences 75, 151–167.
Current state of knowledge regarding the world’s wetlands and their future under global climate change: a synthesis.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3sXjtVagtw%3D%3D&md5=65d5a06130ce9f51b1d08bb0873c678dCAS |

Kingsford, R. T., and Auld, K. (2005). Waterbird breeding and environmental flow management in the Macquarie Marshes, arid Australia. River Research and Applications 21, 187–200.
Waterbird breeding and environmental flow management in the Macquarie Marshes, arid Australia.Crossref | GoogleScholarGoogle Scholar |

Kingsford, R. T., Biggs, H. C., and Pollard, S. R. (2011). Strategic adaptive management in freshwater protected areas and their rivers. Biological Conservation 144, 1194–1203.
Strategic adaptive management in freshwater protected areas and their rivers.Crossref | GoogleScholarGoogle Scholar |

Kingsford, R. T., MacNally, R., King, A., Walker, K. F., Bino, G., Thompson, R., Wassens, S., and Humphries, P. (2015). A commentary on ‘Long-term ecological trends of flow-dependent ecosystems in a major regulated river basin’, by Matthew J. Colloff, Peter Caley, Neil Saintilan, Carmel A. Pollino and Neville D. Crossman. Marine and Freshwater Research 66, 970–980.
A commentary on ‘Long-term ecological trends of flow-dependent ecosystems in a major regulated river basin’, by Matthew J. Colloff, Peter Caley, Neil Saintilan, Carmel A. Pollino and Neville D. Crossman.Crossref | GoogleScholarGoogle Scholar |

Kopf, R. K., Finlayson, C. M., Humphries, P., Sims, N. C., and Hladyz, S. (2015). Anthropocene baselines: assessing change and managing biodiversity in human-dominated aquatic ecosystems. Bioscience 65, 798–811.
Anthropocene baselines: assessing change and managing biodiversity in human-dominated aquatic ecosystems.Crossref | GoogleScholarGoogle Scholar |

Ludwig, J., Tongway, D., Hodgkinson, K., Freudenberger, D., and Noble, J. (1996). ‘Landscape Ecology, Function and Management: Principles from Australia’s Rangelands.’ (CSIRO Publishing: Melbourne, Vic., Australia.)

Lukasiewicz, A., Finlayson, C. M., and Pittock, J. (2013). ‘Identifying Low Risk Climate Change Adaptation in Catchment Management while Avoiding Unintended Consequences.’ (National Climate Change Adaptation Research Facility: Gold Coast, Qld, Australia.)

Lukasiewicz, A., Pittock, J., and Finlayson, C. M. (2016). Institutional challenges of adopting ecosystem based adaptation to climate change. Regional Environmental Change 16, 487–499.
Institutional challenges of adopting ecosystem based adaptation to climate change.Crossref | GoogleScholarGoogle Scholar |

MacLean, I. M. D., Austin, G. E., Rehfisch, M. M., Blew, J., Crowe, O., Delany, S., Devos, K., Deceuninck, B., Günther, K., Laursen, K., van Roomen, M., and Wahl, J. (2008). Climate change causes rapid changes in the distribution and site abundance of birds in winter. Global Change Biology 14, 2489–2500.

Margules, C. R., and Pressey, R. L. (2000). Systematic conservation planning. Nature 405, 243–253.
Systematic conservation planning.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3cXjsFyjsLg%3D&md5=8d66576d7d2888a7cca8b88eb5069077CAS |

Matthews, J. H., and Wickel, B. (2009). Embracing uncertainty in freshwater climate change adaptation: a natural history approach. Climate and Development 1, 269–279.
Embracing uncertainty in freshwater climate change adaptation: a natural history approach.Crossref | GoogleScholarGoogle Scholar |

Milly, P. C. D., Betancourt, J., Falkenmark, M., Hirsch, R. M., Kundzewicz, Z. W., Lettenmaier, D. P., and Stouffer, R. J. (2008). Stationarity is dead: whither water management? Science 319, 573–574.
Stationarity is dead: whither water management?Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1cXhvVamtLY%3D&md5=3ac351a2b2ac290af50583b656b24cb9CAS |

Nel, J. L., Roux, D. J., Abell, R., Ashton, P. J., Cowling, R. M., Higgins, J. V., Thieme, M., and Viers, J. H. (2009). Progress and challenges in freshwater conservation planning. Aquatic Conservation: Marine and Freshwater Ecosystems 19, 474–485.
Progress and challenges in freshwater conservation planning.Crossref | GoogleScholarGoogle Scholar |

Olden, J. D., and Naiman, R. J. (2010). Incorporating thermal regimes into environmental flows assessments: modifying dam operations to restore freshwater ecosystem integrity. Freshwater Biology 55, 86–107.
Incorporating thermal regimes into environmental flows assessments: modifying dam operations to restore freshwater ecosystem integrity.Crossref | GoogleScholarGoogle Scholar |

Olds, A. D., Pitt, K. A., Maxwell, P. S., Babcock, R. C., Rissik, D., and Connolly, R. M. (2014). Marine reserves help coastal ecosystems cope with extreme weather. Global Change Biology 20, 3050–3058.
Marine reserves help coastal ecosystems cope with extreme weather.Crossref | GoogleScholarGoogle Scholar |

Peimer, A. W., Krzywicka, A. E., Cohen, D. B., Van den Bosch, K., Buxton, V. L., Stevenson, N. A., and Matthews, J. W. (2017). National level wetland policy specificity and goals vary according to political and economic indicators. Environmental Management 59, 141.
National level wetland policy specificity and goals vary according to political and economic indicators.Crossref | GoogleScholarGoogle Scholar |

Pethick, J. (2002). Estuarine and tidal wetland restoration in the United Kingdom: policy versus practice. Restoration Ecology 10, 431–437.
Estuarine and tidal wetland restoration in the United Kingdom: policy versus practice.Crossref | GoogleScholarGoogle Scholar |

Pittock, J., and Finlayson, C. M. (2011). Australia’s Murray–Darling Basin: freshwater ecosystem conservation options in an era of climate change. Marine and Freshwater Research 62, 232–243.
Australia’s Murray–Darling Basin: freshwater ecosystem conservation options in an era of climate change.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXjsVKksbo%3D&md5=04e38de4a6b7bf69d86ddbfd69e5ed5bCAS |

Pittock, J., Hansen, L. J., and Abell, R. (2008). Running dry: freshwater biodiversity, protected areas and climate change. Biodiversity 9, 30–38.
Running dry: freshwater biodiversity, protected areas and climate change.Crossref | GoogleScholarGoogle Scholar |

Pittock, J., Finlayson, C. M., Gardner, A., and McKay, C. (2010). Changing character: the Ramsar Convention on Wetlands and climate change in the Murray–Darling Basin, Australia. Environmental and Planning Law Journal 27, 401–425.

Pittock, J., Finlayson, C. M., and Howitt, J. A. (2012). Beguiling and risky: ‘environmental works and measures’ for wetlands conservation under a changing climate. Hydrobiologia 70, 111–131.

Pittock, J., Williams, J., and Grafton, R. Q. (2015). The Murray–Darling Basin plan fails to deal adequately with climate change. Water 42, 26–30.

Plummer, R. (2013). Can adaptive comanagement help to address the challenges of climate change adaptation? Ecology and Society 18, art2.
Can adaptive comanagement help to address the challenges of climate change adaptation?Crossref | GoogleScholarGoogle Scholar |

Pressey, R. L., Cabeza, M., Watts, M. E., Cowling, R. M., and Wilson, K. A. (2007). Conservation planning in a changing world. Trends in Ecology & Evolution 22, 583–592.
Conservation planning in a changing world.Crossref | GoogleScholarGoogle Scholar |

Ramsar Convention (2012). An integrated framework and guidelines for avoiding, mitigating and compensating for wetland losses. Resolution XI.9. Available at http://www.ramsar.org/sites/default/files/documents/library/cop11-res09-e.pdf [Verified 13 April 2016].

Ramsar Convention Secretariat (2010a). ‘Managing Wetlands: Frameworks for Managing Wetlands of International Importance and other Wetland Sites. Ramsar Handbooks for the Wise use of Wetlands’, 4th edn, vol. 18. (Ramsar Convention Secretariat: Gland, Switzerland.)

Ramsar Convention Secretariat (2010b). ‘Inventory, Assessment, and Monitoring: an Integrated Framework for Wetland Inventory, Assessment, and Monitoring. Ramsar Handbooks for the Wise use of Wetlands’, 4th edn, vol. 13. (Ramsar Convention Secretariat: Gland, Switzerland.)

Ramsar Convention Secretariat (2012). Limits of acceptable change. The definition and operation of concepts and approaches for ‘limits of acceptable change’ which may be applicable to the Ramsar context of defining and detecting change in the ecological character of wetlands. Ramsar COP11 DOC. 24. Available at http://www.ramsar.org/sites/default/files/documents/pdf/cop11/doc/cop11-doc24-e-limits.pdf [Verified 13 April 2016].

Robertson, H. A., and Funnell, E. P. (2012). Aquatic plant dynamics of Waituna Lagoon, New Zealand: trade-offs in managing opening events of a Ramsar site. Wetlands Ecology and Management 20, 433–445.
Aquatic plant dynamics of Waituna Lagoon, New Zealand: trade-offs in managing opening events of a Ramsar site.Crossref | GoogleScholarGoogle Scholar |

Rogers, K., Saintilan, N., and Copeland, C. (2014). Managed retreat of saline coastal wetlands: challenges and opportunities identified from the Hunter River Estuary, Australia. Estuaries and Coasts 37, 67–78.
Managed retreat of saline coastal wetlands: challenges and opportunities identified from the Hunter River Estuary, Australia.Crossref | GoogleScholarGoogle Scholar |

Saintilan, N., Rogers, K., and Ralph, T. (2013). Matching research and policy tools to scales of climate change adaptation in the Murray–Darling Basin, Australia. Hydrobiologia 708, 97–109.
Matching research and policy tools to scales of climate change adaptation in the Murray–Darling Basin, Australia.Crossref | GoogleScholarGoogle Scholar |

SCBD (2010). ‘Global Biodiversity Outlook 3.’ (Secretariat of the Convention on Biological Diversity: Montreal, QC, Canada.)

Schallenberg, M., Hall, C. J., and Burns, C. W. (2003). Consequences of climate-induced salinity increases on zooplankton abundance and diversity in coastal lakes. Marine Ecology Progress Series 251, 181–189.
Consequences of climate-induced salinity increases on zooplankton abundance and diversity in coastal lakes.Crossref | GoogleScholarGoogle Scholar |

Schallenberg, M., Larned, S. T., Hayward, S., and Arbuckle, C. (2010). Contrasting effects of managed opening regimes on water quality in two intermittently closed and open coastal lakes. Estuarine, Coastal and Shelf Science 86, 587–597.
Contrasting effects of managed opening regimes on water quality in two intermittently closed and open coastal lakes.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXhsVSru7Y%3D&md5=90adcf4e5a824303f93f34f80c59b23bCAS |

Steffen, W., Burbidge, A. A., Hughes, L., Kitchin, R., Lindenmayer, D., Musgrave, W., Stafford Smith, M., and Werner, P. A. (2009). ‘Australia’s Biodiversity and Climate Change.’ (CSIRO Publishing: Melbourne, Vic., Australia.)

Suski, C. D., and Cooke, S. J. (2007). Conservation of aquatic resources through the use of freshwater protected areas: opportunities and challenges. Biodiversity and Conservation 16, 2015–2029.
Conservation of aquatic resources through the use of freshwater protected areas: opportunities and challenges.Crossref | GoogleScholarGoogle Scholar |

Ticehurst, J. L., Newham, L. T. H., Rissik, D., Letcher, R. A., and Jakeman, A. J. (2007). A Bayesian network approach to assess the sustainability of coastal lakes. Environmental Modelling & Software 22, 1129–1139.
A Bayesian network approach to assess the sustainability of coastal lakes.Crossref | GoogleScholarGoogle Scholar |

Townsend, C. R., Tipa, G., Teirney, L. D., and Niyogi, D. K. (2004). Development of a tool to facilitate participation of Maori in the management of stream and river health. EcoHealth 1, 184–195.
Development of a tool to facilitate participation of Maori in the management of stream and river health.Crossref | GoogleScholarGoogle Scholar |

UNEP (2012). ‘GEO5. Global Environmental Outlook. Environment for the Future We Want.’ (United Nations Environment Programme: Nairobi, Kenya.)

van Dam, R. A., Finlayson, C. M., and Humphrey, C. L. (1999). Wetland risk assessment: a framework and methods for predicting and assessing change in ecological character. In ‘Techniques for Enhanced Wetland Inventory, Assessment and Monitoring’. (Eds C. M. Finlayson and A. G. Spiers.) Supervising Scientist Report 147, pp. 83–118. (Supervising Scientist Group: Canberra, ACT, Australia.)

Visser, M. E. (2008). Keeping up with a warming world; assessing the rate of adaptation to climate change. Proceedings of the Royal Society of London – B. Biological Sciences 275, 649–659.
Keeping up with a warming world; assessing the rate of adaptation to climate change.Crossref | GoogleScholarGoogle Scholar |

Westoby, M., Walker, B. H., and Noy-Meir, I. (1989). Opportunistic management for rangelands not at equilibrium. Journal of Range Management 42, 266–274.
Opportunistic management for rangelands not at equilibrium.Crossref | GoogleScholarGoogle Scholar |

Winter, T. C. (2000). The vulnerability of wetlands to climate change: a hydrologic landscape perspective. Journal of the American Water Resources Association 36, 305–311.
The vulnerability of wetlands to climate change: a hydrologic landscape perspective.Crossref | GoogleScholarGoogle Scholar |

Wise, R. M., Fazey, I., Stafford Smith, M., Park, S. E., Eakin, H. C., Archer Van Garderen, E. R. M., and Campbell, B. (2014). Reconceptualising adaptation to climate change as part of pathways of change and response. Global Environmental Change 28, 325–336.
Reconceptualising adaptation to climate change as part of pathways of change and response.Crossref | GoogleScholarGoogle Scholar |

Zsuffa, I., Morardet, S., Cools, J., Liersch, S., Johnston, R., D’Haeyer, T., Hattermann, F. F., Kone, B., and Diallo, M. (2013). Guidance for the application of vulnerability assessment and multicriteria decision analysis in integrated wetland management. Report prepared under the European Commission 7th Framework Project. Available at http://www.wetwin.eu/downloads/D9-1.pdf [Verified 20 April 2016].