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| === Cancun === | | === Cancun === |
| | | |
− | Under the Cancun Adaptation Framework (2010) parties are encouraged to build the resilience of ecological systems, and slow onsetting events such as biodiversity loss, forest degradation and desertification are addressed. In this context, UNCCD has been engaged in enhancing the adaptive capacities of dryland populations to highly variable environmental conditions.</font> <font size="2">After several years of discussion on definitions and content, current efforts strive to provide information on the implementation and financing of EbA measures and to fill knowledge gaps on the links between climate change and biodiversity (see recent decisions at CBD COP 10). A database on EbA approaches was mandated in the context of the UNFCCC Nairobi work programme in 2011. Under the same programme a workshop on ecosystem-based approaches for adaptation is to be held in 2013 in cooperation with the CBD and UNCCD, which will consider the synergies and lessons learned through the implementation of the three Rio Conventions.</font> | + | Under the Cancun Adaptation Framework (2010) parties are encouraged to build the resilience of ecological systems, and slow onsetting events such as biodiversity loss, forest degradation and desertification are addressed. In this context, UNCCD has been engaged in enhancing the adaptive capacities of dryland populations to highly variable environmental conditions.</font> <font size="2">After several years of discussion on definitions and content, current efforts strive to provide information on the implementation and financing of EbA measures and to fill knowledge gaps on the links between climate change and biodiversity (see recent decisions at CBD COP 10). A database on EbA approaches was mandated in the context of the UNFCCC Nairobi work programme in 2011. Under the same programme a workshop on ecosystem-based approaches for adaptation is to be held in 2013 in cooperation with the CBD and UNCCD, which will consider the synergies and lessons learned through the implementation of the three Rio Conventions.</font> |
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− | = <font size="2">Concept and Methodology</font> = | + | = Concept and Methodology = |
| | | |
− | == <font size="2">Conceptual Background</font> == | + | == Conceptual Background == |
| | | |
| <font size="2">Ecosystem-based adaptation was defined as reducing the vulnerability to climate change of people through the sustainable use and conservation of ecosystems. In contrast to common natural resources and biodiversity management approaches, EbA purposefully assesses and selects measures in the context of an overall adaptation strategy. Although EbA measures use ecosystems to adapt to climate change, EbA still is an anthropogenic approach which particularly utilizes the ability of ecosystems to provide so called ecosystem services. They are also referred to as "Green Infrastructure" and can be seen as complementary to or substitutes of hard ("grey") infrastructural measures. For example, ecosystems are able to generate direct services such as food and building material, as well as indirect services like water purification or pollination. An overview of ecosystem services has been described by The Economics of Ecosystems and Biodiversity, TEEB<ref>TEEB is a global Initiative hosted by UNEP: www.teebtest.org. Apart from the intended outcomes, EbA measures tend to generate additional co-benefits such as carbon sequestration or biodiversity conservation, improved livelihood conditions and are generally considered no-regret options. To determine the specific requirements of maintaining or restoring an ecosystem and its services, EbA ideally draws on studies of climate change impacts or integrated climate analyses which make use of climate scenarios and models.fckLRfckLRWorldwide surveys have shown that restoration and conservation of ecosystems are generally very cost effective and highly profitable for maintaining ecosystem services. In comparison to the economic loss caused by loss of ecosystem services, the cost-benefit ratio of return of investment of appropriate restoration of ecosystems may be as high as 3 to 75, depending on the ecosystem context and the measures taken (UNEP 2010, 6). For example, a study in Vietnam shows that planting or maintaining mangrove forests to act as breakwaters for coastal protection is significantly cheaper (costing 1.1 million USD for 12,000 hectares) than mechanical repair of wave-induced dike erosion (costing 3.7 million USD annually) (IFRC: World Disasters Report 2002, 95). Climate change manifests itself in many different ways, such as changed patterns in temperature, precipitation or seasons. Adaptation approaches therefore have to regard the interdependencies between the climatic, ecological, social and economic dimensions. The proposed EbA approach, being based on elaborate cause-and-effect chains, as explained in the following section, enables the integration of adaptation benefits right from the planning phase. Thus it is drawing adaptive capacity from ecosystem and ecosystem services as well as strengthening their resilience against climate change. It is important to differentiate between utilizing ecosystem services for an adaptation purpose (EbA) and adapting ecosystems and ecosystem management to climate change in order to maintain their services (adaptation of ecosystems). The latter can be neccessary to sustain ecosystem services under the pressure of a changing climate.fckLRfckLR== Mainstreaming EbA ==fckLRfckLRThe EbA mainstreaming cycle explains how to integrate EbA into a project, policy or planning process. Following the different steps is closely related to the step-by-step approach of the tool "Climate Proofing for Development", pinpointing the particularities of EbA.fckLRIn the beginning, the exposure unit (region, sector, etc.) is screened by by applying a climatefckLRlens. fckLRTo be able to sustain development efforts also in a context of climate change, adaptation needs are being assessed in step 2. The vulnerability assessment considers exposure, sensitivity and adaptive capacity. To identify interdependencies the DPSIR framework can be of help. EbA specifies are most prominent in the following steps: identification, selection and implementation of adaptation options. fckLRIn step 3 EbA options should be considered next to other adaptation options. fckLRIn step 4 decision makers will need arguments for choosing EbA measures. A proactive communication concept for EbA will be helpful in familiarizing stakeholders with potential advantages. fckLROnce EbA options have been chosen another question arises for the implementation (step 5). Only functioning ecosystems and their services can be used for the purpose of adaptation. However, they are often affected by anthropogenic pressures and there might be additional threats from climate change which are becoming more and more important. Thus, within an EbA approach, activities to adapt ecosystems to the effects of climate change can be of importance to secure the EbA options which have been chosen. fckLRThe evaluation concludes the cycle. Monitoring instead is a process coherent in every stagefckLR(see “Adaptation made to measure”).fckLRfckLR= EbA in Practice =fckLRfckLR== Must-haves and Nice-to-haves ==fckLRfckLRThe knowledge on EbA implementation is constantly being refined and complemented. While some elements in project design are seen as a necessity in EbA measures and must be included (“must haves”), others are additional steps that complement the measure (“nice to have”), a categorisation which is still to be elaborated further. In the following, EbA “must haves” and “nice to have” will be explained with the aid of a concrete project example, the project “Adaptation to climate change by promoting the biodiversity in province Bac Lieu”, Vietnam”. The Mekong Delta was identified by the Worldbank and the IPCC as one of the regions most threated by climate change. Different climate scenarios predict increasing flooding events, tropical storms, a rise in sea level and soil salination in the near future. At the samefckLRtime, natural protection systems against these threats, such as mangrove forests, are heavily degraded through intensive monocultures, shrimp farming and unsustainable use of resources. The main objective of the project is to increase the protective function of the coastal forests through sustainable resource management and the promotion of biodiversity. fckLRMoreover, additional complementary measures can be taken, so-called “nice to haves”. These include:fckLRfckLRQuantification of ecosystem services and cost-benefitfckLRanalyses (for more information see manual IntegratingfckLREcosystem Services into Development Planning).fckLRExamples for opportunity costs (EbA infrastructurefckLRmeasures): Mangrove reforestation and renaturation, for example, greatly reduces costs of dike construction andfckLRmaintenance.fckLRSustainably functioning financing mechanisms, forfckLRinstance Payments for Ecosystem Services (PES): landownersfckLRand users are offered monetary or non-monetaryfckLRincentives in exchange for managing their land to provide certain quantity or quality of ecosystem services,fckLRe.g. payments of downstream river users to upstreamfckLRusers for proper waste management to reduce river pollution.fckLRfckLRBearing these aspects in mind when designing and implementing an EbA project is an important step towards avoiding pitfalls, such as the accidental introduction of non-native invasive species, inadequate integration of stakeholders and socio-economic issues or improper and partial restoration resulting in monocultures with little ecosystem service capacity.fckLRfckLR== EbA Measures ==fckLRfckLRThe implementation of EbA measures can be based on either a certain ecosystem service (e.g. water retention), part of an ecosystem or one or several ecosystems. Each sector, on the other hand, should regard its relevant ecosystem services and the underlying ecosystems in the water sector, for example groundwater recharge can be provided by a range of ecosystems such grassland, peatlands or rivers. All of those should be included in the process of selecting the best measures for adaptation. In general the type and state of the ecosystem as well as the intended outcome determine the measures to choose. The following table gives an overview of some ecosystems, a selection of services they provide, measures that can be applied and outcomes they may achieve.fckLRfckLR== Guidebooks and Manuals for EbA Measures ==fckLRfckLRAAK Net (2013): Using Ecosystem-based Adaptation to tackle Food insecurityfckLREnvirocare (2008): Training Manual on Good Forest Governance at Community LevelfckLRIUCN (2006): Coral Reef Resilience and Resistance to Bleaching.fckLRUSAID (2009): Adapting to coastal climate change – a guidebook for development planners.fckLRSchuhmann, M., Joosten, H. (2008): Global Peatland Restoration Manual.fckLRTrees for the Future (2008): Agroforestry Training Program.fckLRGIZ (2012): Integrating Adaptation Measures into Forest Management (internal working document)fckLRfckLR= See Also =fckLR</ref></font> | | <font size="2">Ecosystem-based adaptation was defined as reducing the vulnerability to climate change of people through the sustainable use and conservation of ecosystems. In contrast to common natural resources and biodiversity management approaches, EbA purposefully assesses and selects measures in the context of an overall adaptation strategy. Although EbA measures use ecosystems to adapt to climate change, EbA still is an anthropogenic approach which particularly utilizes the ability of ecosystems to provide so called ecosystem services. They are also referred to as "Green Infrastructure" and can be seen as complementary to or substitutes of hard ("grey") infrastructural measures. For example, ecosystems are able to generate direct services such as food and building material, as well as indirect services like water purification or pollination. An overview of ecosystem services has been described by The Economics of Ecosystems and Biodiversity, TEEB<ref>TEEB is a global Initiative hosted by UNEP: www.teebtest.org. Apart from the intended outcomes, EbA measures tend to generate additional co-benefits such as carbon sequestration or biodiversity conservation, improved livelihood conditions and are generally considered no-regret options. To determine the specific requirements of maintaining or restoring an ecosystem and its services, EbA ideally draws on studies of climate change impacts or integrated climate analyses which make use of climate scenarios and models.fckLRfckLRWorldwide surveys have shown that restoration and conservation of ecosystems are generally very cost effective and highly profitable for maintaining ecosystem services. In comparison to the economic loss caused by loss of ecosystem services, the cost-benefit ratio of return of investment of appropriate restoration of ecosystems may be as high as 3 to 75, depending on the ecosystem context and the measures taken (UNEP 2010, 6). For example, a study in Vietnam shows that planting or maintaining mangrove forests to act as breakwaters for coastal protection is significantly cheaper (costing 1.1 million USD for 12,000 hectares) than mechanical repair of wave-induced dike erosion (costing 3.7 million USD annually) (IFRC: World Disasters Report 2002, 95). Climate change manifests itself in many different ways, such as changed patterns in temperature, precipitation or seasons. Adaptation approaches therefore have to regard the interdependencies between the climatic, ecological, social and economic dimensions. The proposed EbA approach, being based on elaborate cause-and-effect chains, as explained in the following section, enables the integration of adaptation benefits right from the planning phase. Thus it is drawing adaptive capacity from ecosystem and ecosystem services as well as strengthening their resilience against climate change. It is important to differentiate between utilizing ecosystem services for an adaptation purpose (EbA) and adapting ecosystems and ecosystem management to climate change in order to maintain their services (adaptation of ecosystems). The latter can be neccessary to sustain ecosystem services under the pressure of a changing climate.fckLRfckLR== Mainstreaming EbA ==fckLRfckLRThe EbA mainstreaming cycle explains how to integrate EbA into a project, policy or planning process. Following the different steps is closely related to the step-by-step approach of the tool "Climate Proofing for Development", pinpointing the particularities of EbA.fckLRIn the beginning, the exposure unit (region, sector, etc.) is screened by by applying a climatefckLRlens. fckLRTo be able to sustain development efforts also in a context of climate change, adaptation needs are being assessed in step 2. The vulnerability assessment considers exposure, sensitivity and adaptive capacity. To identify interdependencies the DPSIR framework can be of help. EbA specifies are most prominent in the following steps: identification, selection and implementation of adaptation options. fckLRIn step 3 EbA options should be considered next to other adaptation options. fckLRIn step 4 decision makers will need arguments for choosing EbA measures. A proactive communication concept for EbA will be helpful in familiarizing stakeholders with potential advantages. fckLROnce EbA options have been chosen another question arises for the implementation (step 5). Only functioning ecosystems and their services can be used for the purpose of adaptation. However, they are often affected by anthropogenic pressures and there might be additional threats from climate change which are becoming more and more important. Thus, within an EbA approach, activities to adapt ecosystems to the effects of climate change can be of importance to secure the EbA options which have been chosen. fckLRThe evaluation concludes the cycle. Monitoring instead is a process coherent in every stagefckLR(see “Adaptation made to measure”).fckLRfckLR= EbA in Practice =fckLRfckLR== Must-haves and Nice-to-haves ==fckLRfckLRThe knowledge on EbA implementation is constantly being refined and complemented. While some elements in project design are seen as a necessity in EbA measures and must be included (“must haves”), others are additional steps that complement the measure (“nice to have”), a categorisation which is still to be elaborated further. In the following, EbA “must haves” and “nice to have” will be explained with the aid of a concrete project example, the project “Adaptation to climate change by promoting the biodiversity in province Bac Lieu”, Vietnam”. The Mekong Delta was identified by the Worldbank and the IPCC as one of the regions most threated by climate change. Different climate scenarios predict increasing flooding events, tropical storms, a rise in sea level and soil salination in the near future. At the samefckLRtime, natural protection systems against these threats, such as mangrove forests, are heavily degraded through intensive monocultures, shrimp farming and unsustainable use of resources. The main objective of the project is to increase the protective function of the coastal forests through sustainable resource management and the promotion of biodiversity. fckLRMoreover, additional complementary measures can be taken, so-called “nice to haves”. These include:fckLRfckLRQuantification of ecosystem services and cost-benefitfckLRanalyses (for more information see manual IntegratingfckLREcosystem Services into Development Planning).fckLRExamples for opportunity costs (EbA infrastructurefckLRmeasures): Mangrove reforestation and renaturation, for example, greatly reduces costs of dike construction andfckLRmaintenance.fckLRSustainably functioning financing mechanisms, forfckLRinstance Payments for Ecosystem Services (PES): landownersfckLRand users are offered monetary or non-monetaryfckLRincentives in exchange for managing their land to provide certain quantity or quality of ecosystem services,fckLRe.g. payments of downstream river users to upstreamfckLRusers for proper waste management to reduce river pollution.fckLRfckLRBearing these aspects in mind when designing and implementing an EbA project is an important step towards avoiding pitfalls, such as the accidental introduction of non-native invasive species, inadequate integration of stakeholders and socio-economic issues or improper and partial restoration resulting in monocultures with little ecosystem service capacity.fckLRfckLR== EbA Measures ==fckLRfckLRThe implementation of EbA measures can be based on either a certain ecosystem service (e.g. water retention), part of an ecosystem or one or several ecosystems. Each sector, on the other hand, should regard its relevant ecosystem services and the underlying ecosystems in the water sector, for example groundwater recharge can be provided by a range of ecosystems such grassland, peatlands or rivers. All of those should be included in the process of selecting the best measures for adaptation. In general the type and state of the ecosystem as well as the intended outcome determine the measures to choose. The following table gives an overview of some ecosystems, a selection of services they provide, measures that can be applied and outcomes they may achieve.fckLRfckLR== Guidebooks and Manuals for EbA Measures ==fckLRfckLRAAK Net (2013): Using Ecosystem-based Adaptation to tackle Food insecurityfckLREnvirocare (2008): Training Manual on Good Forest Governance at Community LevelfckLRIUCN (2006): Coral Reef Resilience and Resistance to Bleaching.fckLRUSAID (2009): Adapting to coastal climate change – a guidebook for development planners.fckLRSchuhmann, M., Joosten, H. (2008): Global Peatland Restoration Manual.fckLRTrees for the Future (2008): Agroforestry Training Program.fckLRGIZ (2012): Integrating Adaptation Measures into Forest Management (internal working document)fckLRfckLR= See Also =fckLR</ref></font> |
| | | |
− | Apart from the intended outcomes, EbA measures tend to | + | Apart from the intended outcomes, EbA measures tend to generate additional co-benefits such as carbon sequestration or biodiversity conservation, improved livelihood conditions and are generally considered no-regret options. To determine the specific requirements of maintaining or restoring an ecosystem and its services, EbA ideally draws on studies of climate change impacts or integrated climate analyses, which make use of climate scenarios and models. Worldwide surveys have shown that restoration and conservation of ecosystems are generally very cost effective and highly profitable for maintaining ecosystem services. In comparison to the economic loss caused by loss of ecosystem services, the cost-benefit ratio of return of investment of appropriate restoration of ecosystems may be as high as 3 to 75, depending on the ecosystem context and the measures taken (UNEP 2010, 6). For example, a study in Vietnam shows that planting or maintaining mangrove forests to act as breakwaters for coastal protection is significantly cheaper (costing 1.1 million USD for 12,000 hectares) than mechanical repair of wave-induced dike erosion (costing 3.7 million USD annually) (IFRC: World Disasters Report 2002, 95). Climate change manifests itself in many different ways, such as changed patterns in temperature, precipitation or seasons. |
− | generate additional co-benefits such as carbon sequestration | + | |
− | or biodiversity conservation, improved livelihood conditions | + | |
− | and are generally considered no-regret options. | + | |
− | To determine the specific requirements of maintaining or | + | |
− | restoring an ecosystem and its services, EbA ideally draws | + | |
− | on studies of climate change impacts or integrated climate | + | |
− | analyses, which make use of climate scenarios and models. | + | |
− | Worldwide surveys have shown that restoration and conservation | + | |
− | of ecosystems are generally very cost effective and | + | |
− | highly profitable for maintaining ecosystem services. In | + | |
− | comparison to the economic loss caused by loss of ecosystem | + | |
− | services, the cost-benefit ratio of return of investment of | + | |
− | appropriate restoration of ecosystems may be as high as 3 to | + | |
− | 75, depending on the ecosystem context and the measures | + | |
− | taken (UNEP 2010, 6). For example, a study in Vietnam | + | |
− | shows that planting or maintaining mangrove forests to act | + | |
− | as breakwaters for coastal protection is significantly cheaper | + | |
− | (costing 1.1 million USD for 12,000 hectares) than mechanical | + | |
− | repair of wave-induced dike erosion (costing 3.7 million | + | |
− | USD annually) (IFRC: World Disasters Report 2002, 95). | + | |
− | Climate change manifests itself in many different ways, such | + | |
− | as changed patterns in temperature, precipitation or seasons. | + | |
| | | |
− | Adaptation approaches therefore have to regard the interdependencies | + | Adaptation approaches therefore have to regard the interdependencies between the climatic, ecological, social and economic dimensions. The proposed EbA approach, being based on elaborate cause-and-effect chains, as explained in the following section, enables the integration of adaptation benefits right from the planning phase. Thus it is drawing adaptive capacity from ecosystem and ecosystem services as well as strengthening their resilience against climate change. |
− | between the climatic, ecological, social and | + | |
− | economic dimensions. The proposed EbA approach, being | + | |
− | based on elaborate cause-and-effect chains, as explained in | + | |
− | the following section, enables the integration of adaptation | + | |
− | benefits right from the planning phase. Thus it is drawing | + | |
− | adaptive capacity from ecosystem and ecosystem services | + | |
− | as well as strengthening their resilience against climate | + | |
− | change. | + | |
| | | |
− | It is important to differentiate between utilizing ecosystem | + | It is important to differentiate between utilizing ecosystem services for an adaptation purpose (EbA) and adapting ecosystems and ecosystem management to climate change in order to maintain their services (adaptation of ecosystems). The latter can be neccessary to sustain ecosystem services under the pressure of a changing climate. |
− | services for an adaptation purpose (EbA) and adapting ecosystems | + | |
− | and ecosystem management to climate change in | + | |
− | order to maintain their services (adaptation of ecosystems). | + | |
− | The latter can be neccessary to sustain ecosystem services | + | |
− | under the pressure of a changing climate. | + | |
| | | |
| = Analytical Framework = | | = Analytical Framework = |
| | | |
− | EbA measures need to be founded on a sound analysis of | + | EbA measures need to be founded on a sound analysis of the complex interdependencies between ecosystems, the flow of ecosystem services and dependent communities. In order to distinguish the cause-and-effect relationships of driving forces, pressures, states, impacts and responses within these spheres, the DPSIR conceptual framework is being applied. |
− | the complex interdependencies between ecosystems, the | + | |
− | flow of ecosystem services and dependent communities. In | + | |
− | order to distinguish the cause-and-effect relationships of | + | |
− | driving forces, pressures, states, impacts and responses within | + | |
− | these spheres, the DPSIR conceptual framework is being | + | |
− | applied. | + | |
| | | |
− | In the following, this framework will be explained and illustrated | + | In the following, this framework will be explained and illustrated with the aid of two GIZ projects from Vietnam. The example is simplified for better understanding. The projects “Sustainable Management of Coastal Forest Ecosystems in Bac Lieu Province” (2009-2011) and “Management of Natural Resources in the Coastal Zone of Soc Trang Province”4 (ongoing since 2007) contain exemplary EbA measures and have already shown positive results. Both projects support the protection of coastal zones through the restoration and management of coastal mangrove forests. The pressure of climate change threatens the coastal regions of Vietnam with a sea level rise of up to 0.6 m by 2100, increased temperatures, changed seasonal patterns, and more intense and more frequent tropical cyclones. Additional anthropogenic pressures are economical (intensive rice farming, rapid expansion of lucrative shrimp farms directly bordering on mangrove sanctuaries), political (overlapping responsibilities and lack of administrational capacities of authorities) and social (poverty, lack of cooperation of different actors) causes. |
− | with the aid of two GIZ projects from Vietnam. | + | |
− | The example is simplified for better understanding. | + | |
− | The projects “Sustainable Management of Coastal Forest | + | |
− | Ecosystems in Bac Lieu Province” (2009-2011) and “Management | + | |
− | of Natural Resources in the Coastal Zone of Soc | + | |
− | Trang Province”4 (ongoing since 2007) contain exemplary | + | |
− | EbA measures and have already shown positive results. Both | + | |
− | projects support the protection of coastal zones through the | + | |
− | restoration and management of coastal mangrove forests. | + | |
− | The pressure of climate change threatens the coastal regions | + | |
− | of Vietnam with a sea level rise of up to 0.6 m by | + | |
− | 2100, increased temperatures, changed seasonal patterns, | + | |
− | and more intense and more frequent tropical cyclones. Additional | + | |
− | anthropogenic pressures are economical (intensive | + | |
− | rice farming, rapid expansion of lucrative shrimp farms | + | |
− | directly bordering on mangrove sanctuaries), political (overlapping | + | |
− | responsibilities and lack of administrational capacities | + | |
− | of authorities) and social (poverty, lack of cooperation | + | |
− | of different actors) causes. | + | |
| | | |
− | In a healthy state, coastal mangrove forests provide nurseries | + | In a healthy state, coastal mangrove forests provide nurseries and habitats for fish, molluscs, crustaceans, birds, insects, mammals and reptiles, protection of the landward zone, flood mitigation and stabilization of the groundwater level. The special root system of mangrove trees slows the water flow, traps sediment, thus stabilizing the soil and alleviating storm and wave damage. Further, they shelter bacteria which break down ammonium and nitrate, allowing for a higher stocking density of shrimps without the use of chemical additives and consequently reduce the total default risk. Their shade also helps to moderate heat spells in shrimp ponds. However, due to anthropogenic and climate- related pressures, the mangrove ecosystem is partially degraded and increasingly vulnerable, subsequently causing the ecosystem services to decline. The impact is present in the decreased protection of settlements and agriculture, the receding shoreline, the advance of salty sea water further inland, causing groundwater and soil to become saline and eventually leading to hypersaline flats. In turn, the production of biomass as well as growth and seedling recruitment are declining, likely leading to a change in species composition. The continuous decline of mangrove forests and resulting salination of agricultural land pushes land use changes from rice to shrimp farming. The already little diversified local economy is even more at risk of income losses through shrimp epidemics. As a response, in Vietnam the EbA measures focus on rehabilitation and conservation activities as well as the promotion of sustainable management practices. The rehabilitation of degraded coastal forests through afforestation and seedling protection restores declined ecosystem services. The indication of protected zones where logging and shrimp farming is not allowed, contributes to conserves the ecosystems. Further, management schemes for mangrove forests and shrimp farms have been introduced. They include fishing regulations and promote alternative income opportunities for local communities. These measures strengthen the resilience of local communities by reducing the drivers of ecosystem degradation and maintaining the ecosystem services. |
− | and habitats for fish, molluscs, crustaceans, birds, | + | |
− | insects, mammals and reptiles, protection of the landward | + | |
− | zone, flood mitigation and stabilization of the groundwater | + | |
− | level. The special root system of mangrove trees slows | + | |
− | the water flow, traps sediment, thus stabilizing the soil and | + | |
− | alleviating storm and wave damage. Further, they shelter | + | |
− | bacteria which break down ammonium and nitrate, allowing | + | |
− | for a higher stocking density of shrimps without the | + | |
− | use of chemical additives and consequently reduce the total | + | |
− | default risk. Their shade also helps to moderate heat spells | + | |
− | in shrimp ponds. However, due to anthropogenic and climate- | + | |
− | related pressures, the mangrove ecosystem is partially | + | |
− | degraded and increasingly vulnerable, subsequently causing | + | |
− | the ecosystem services to decline. | + | |
− | The impact is present in the decreased protection of settlements | + | |
− | and agriculture, the receding shoreline, the advance | + | |
− | of salty sea water further inland, causing groundwater and | + | |
− | soil to become saline and eventually leading to hypersaline | + | |
− | flats. In turn, the production of biomass as well as growth | + | |
− | and seedling recruitment are declining, likely leading to a change in species composition. The continuous decline of | + | |
− | mangrove forests and resulting salination of agricultural | + | |
− | land pushes land use changes from rice to shrimp farming. | + | |
− | The already little diversified local economy is even more at | + | |
− | risk of income losses through shrimp epidemics. | + | |
− | As a response, in Vietnam the EbA measures focus on rehabilitation | + | |
− | and conservation activities as well as the promotion | + | |
− | of sustainable management practices. The rehabilitation | + | |
− | of degraded coastal forests through afforestation and seedling | + | |
− | protection restores declined ecosystem services. The indication | + | |
− | of protected zones where logging and shrimp farming | + | |
− | is not allowed, contributes to conserves the ecosystems. | + | |
− | Further, management schemes for mangrove forests and | + | |
− | shrimp farms have been introduced. They include fishing | + | |
− | regulations and promote alternative income opportunities | + | |
− | for local communities. These measures strengthen the resilience | + | |
− | of local communities by reducing the drivers of ecosystem | + | |
− | degradation and maintaining the ecosystem services. | + | |
| | | |
| == Helpful Documents on EbA | | == Helpful Documents on EbA |
| | | |
− | BfN (2011): Ecosystem–based approaches to | + | BfN (2011): Ecosystem–based approaches to adaptation and mitigation — good practice examples and lessons learned in Europe. IUCN (2009): Ecosystem–based Adaptation: A natural response to climate change. Jones, Hole and Zavaleta (2012): Harnessing nature to help people to adapt to climate change, in Perspective. Nature climate change, 504-509. Proact Network (2008): The Role of Environmental Management and eco-engineering in Disaster Risk Reduction and Climate Change Adaptation. UNEP, SREP (2012): A comparative analysis of ecosystem–based adaptation and engineering options for Lami Town, Fiji. UNEP (2012): Ecosystem-Based Adaptation Guidance, Moving from Principles to Practice. UNEP, UNDP, IUCN, BMU (2012): Making the case for ecosystem-based adaptation. Building resilience to climate change. Worldbank (2009): Convenient Solutions to an Inconvenient Truth: Ecosystem–based Approaches to Climate Change. |
− | adaptation and mitigation — good practice examples | + | |
− | and lessons learned in Europe. | + | |
− | IUCN (2009): Ecosystem–based Adaptation: | + | |
− | A natural response to climate change. | + | |
− | Jones, Hole and Zavaleta (2012): Harnessing nature | + | |
− | to help people to adapt to climate change, in | + | |
− | Perspective. Nature climate change, 504-509. | + | |
− | Proact Network (2008): The Role of Environmental | + | |
− | Management and eco-engineering in Disaster Risk | + | |
− | Reduction and Climate Change Adaptation. | + | |
− | UNEP, SREP (2012): A comparative analysis of | + | |
− | ecosystem–based adaptation and engineering options | + | |
− | for Lami Town, Fiji. | + | |
− | UNEP (2012): Ecosystem-Based Adaptation | + | |
− | Guidance, Moving from Principles to Practice. | + | |
− | UNEP, UNDP, IUCN, BMU (2012): Making the case for | + | |
− | ecosystem-based adaptation. Building resilience to | + | |
− | climate change. | + | |
− | Worldbank (2009): Convenient Solutions to an | + | |
− | Inconvenient Truth: Ecosystem–based Approaches to | + | |
− | Climate Change. | + | |
| | | |
| == Mainstreaming of EbA == | | == Mainstreaming of EbA == |
| | | |
− | = <font size="2">Guidebooks and manuals for EbA measures</font> = | + | The EbA mainstreaming cycle explains how to integrate |
| + | EbA into a project, policy or planning process. Following |
| + | the different steps is closely related to the step-by-step approach |
| + | of the tool “Climate Proofing for Development”, |
| + | pinpointing the particularities of EbA. Figure 2 visualizes |
| + | the EbA mainstreaming cycle and gives some examples of |
| + | tools, methods and approaches that can be utilized at each |
| + | step (still work in progress). In the beginning, the exposure |
| + | unit (region, sector, etc.) is screened by applying a climate |
| + | lens. To be able to sustain development efforts also in a context |
| + | of climate change, adaptation needs are being assessed |
| + | in step 2. The vulnerability assessment considers exposure, |
| + | sensitivity and adaptive capacity. To identify interdependencies |
| + | the DPSIR framework can be of help. EbA specifies are |
| + | most prominent in the following steps: identification, selection |
| + | and implementation of adaptation options. In step |
| + | 3 EbA options should be considered next to other adaptation |
| + | options. In step 4 decision makers will need arguments |
| + | for choosing EbA measures. A proactive communication |
| + | concept for EbA will be helpful in familiarizing stakeholders |
| + | with potential advantages. Once EbA options have been |
| + | chosen another question arises for the implementation (step |
| + | 5). Only functioning ecosystems and their services can be |
| + | used for the purpose of adaptation. However, they are often |
| + | affected by anthropogenic pressures and there might be |
| + | additional threats from climate change which are becoming |
| + | more and more important. Thus, within an EbA approach, |
| + | activities to adapt ecosystems to the effects of climate |
| + | change can be of importance to secure the EbA options |
| + | which have been chosen. The evaluation concludes the cycle. |
| + | Monitoring instead is a process coherent in every stage |
| + | (see “Adaptation made to measure”). |
| + | |
| + | = EbA in Practice = |
| + | |
| + | == Must haves and nice to haves == |
| + | |
| + | The knowledge on EbA implementation is constantly being |
| + | refined and complemented. While some elements in project |
| + | design are seen as a necessity in EbA measures and must |
| + | be included (“must haves”), others are additional steps that |
| + | complement the measure (“nice to have”), a categorisation |
| + | which is still to be elaborated further. In the following, EbA |
| + | “must haves” and “nice to have” will be explained with the |
| + | aid of a concrete project example, the project “Adaptation |
| + | to climate change by promoting the biodiversity in province |
| + | Bac Lieu”, Vietnam”. The Mekong Delta was identified by |
| + | the Worldbank and the IPCC as one of the regions most |
| + | threated by climate change. Different climate scenarios |
| + | predict increasing flooding events, tropical storms, a rise in |
| + | sea level and soil salination in the near future. At the same |
| + | time, natural protection systems against these threats, such as mangrove forests, are heavily degraded through intensive |
| + | monocultures, shrimp farming and unsustainable use of resources. |
| + | The main objective of the project is to increase the |
| + | protective function of the coastal forests through sustainable |
| + | resource management and the promotion of biodiversity. |
| + | Moreover, additional complementary measures can be taken, |
| + | so-called “nice to haves”. These include: |
| + | • Quantification of ecosystem services and cost-benefit |
| + | analyses (for more information see manual Integrating |
| + | Ecosystem Services into Development Planning). |
| + | • Examples for opportunity costs (EbA infrastructure |
| + | measures): Mangrove reforestation and renaturation, for |
| + | example, greatly reduces costs of dike construction and |
| + | maintenance. |
| + | • Sustainably functioning financing mechanisms, for |
| + | instance Payments for Ecosystem Services (PES): landowners |
| + | and users are offered monetary or non-monetary |
| + | incentives in exchange for managing their land to provide |
| + | certain quantity or quality of ecosystem services, |
| + | e.g. payments of downstream river users to upstream |
| + | users for proper waste management to reduce river pollution. |
| + | |
| + | Bearing these aspects in mind when designing and implementing |
| + | an EbA project is an important step towards avoiding |
| + | pitfalls, such as the accidental introduction of non-native |
| + | invasive species, inadequate integration of stakeholders |
| + | and socio-economic issues or improper and partial restoration |
| + | resulting in monocultures with little ecosystem service |
| + | capacity. |
| + | |
| + | == EbA Measures == |
| + | |
| + | The implementation of EbA measures can be based on either |
| + | a certain ecosystem service (e.g. water retention), part |
| + | of an ecosystem or one or several ecosystems. Each sector, |
| + | on the other hand, should regard its relevant ecosystem |
| + | services and the underlying ecosystems in the water sector, |
| + | for example groundwater recharge can be provided by |
| + | a range of ecosystems such grassland, peatlands or rivers. |
| + | All of those should be included in the process of selecting |
| + | the best measures for adaptation. In general the type and |
| + | state of the ecosystem as well as the intended outcome determine |
| + | the measures to choose. The following table gives |
| + | an overview of some ecosystems, a selection of services they |
| + | provide, measures that can be applied and outcomes they |
| + | may achieve. |
| + | |
| + | = Guidebooks and manuals for EbA measures = |
| | | |
| <font size="2">AAK Net (2013): Using Ecosystem-based Adaptation to tackle Food insecurity<br/>Envirocare (2008): Training Manual on Good Forest Governance at Community Level<br/>IUCN (2006): Coral Reef Resilience and Resistance to Bleaching.<br/>USAID (2009): Adapting to coastal climate change – a guidebook for development planners.<br/>Schuhmann, M., Joosten, H. (2008): Global Peatland Restoration Manual.<br/>Trees for the Future (2008): Agroforestry Training Program.<br/>GIZ (2012): Integrating Adaptation Measures into Forest Management (internal working document)</font> | | <font size="2">AAK Net (2013): Using Ecosystem-based Adaptation to tackle Food insecurity<br/>Envirocare (2008): Training Manual on Good Forest Governance at Community Level<br/>IUCN (2006): Coral Reef Resilience and Resistance to Bleaching.<br/>USAID (2009): Adapting to coastal climate change – a guidebook for development planners.<br/>Schuhmann, M., Joosten, H. (2008): Global Peatland Restoration Manual.<br/>Trees for the Future (2008): Agroforestry Training Program.<br/>GIZ (2012): Integrating Adaptation Measures into Forest Management (internal working document)</font> |
“Ecosystem-based adaptation is the use of biodiversity and ecosystem services as part of an overall adaptation strategy to help people to adapt to the adverse effects of climate change.” CBD 2009
People worldwide depend on functioning ecosystems and the services they provide, such as soil fertility, clean water and food. This is especially true for poor people in developing countries, whose livelihoods are closely linked to natural resources. Climate change is one of the major causes of changes and deterioration in ecosystem services and its impact will most likely increase in the future (Millennium Ecosystem Assessment 2005). At the same time, functioning ecosystems help people to mitigate and more importantly to adapt to climate change – this is referred to as “ecosystem-based adaptation” (EbA). For instance, moors act as natural water storages, buffering increasing amounts of sudden rainfalls and mangroves act as natural barriers against storms and floods in coastal regions. In the UK, for example, more than 3.000 ha of farmland were converted back into moors and wetlands as a means of reducing flooding events.[1]
While humans have always benefited from nature and used ecosystem services to adapt to changing conditions, the concept of EbA is fairly new. The related “ecosystem based management” rose in relevance and gained support after the Millennium Ecosystem Assessment (2005). The idea of ecosystem-based adaptation originally arose in NGO and intergovernmental organization circles as “natural solutions to climate change”.
EbA has evolved into an important link between the three Rio Conventions: the United Nations Framework Convention on Climate Change (UNFCCC), the Convention on Biological Diversity (CBD) and the United Nations Convention to Combat Desertification (UNCCD). Of the three Rio conventions, the CBD concerns itself the most with EbA. Parties to the CBD first committed to adaptation activities during COP 5 held in 2000. In particular, decision V/3 on marine and coastal biodiversity included adaptation to climate change within the framework of ‘priority areas for action on coral bleaching’. Another important milestone is the agreement on the Aichi Biodiversity Targets in 2010, which include the commitment to minimize “the multiple
anthropogenic pressures on vulnerable ecosystems” (target 10) and enhance “ecosystem resilience and the contribution of biodiversity to climate change mitigation and adaptation” (target 15). The concept of EbA was first introduced into the UNFCCC in 2008 at the COP 14, with the issue being pushed by NGOs such as IUCN, TNC and others.
Under the Cancun Adaptation Framework (2010) parties are encouraged to build the resilience of ecological systems, and slow onsetting events such as biodiversity loss, forest degradation and desertification are addressed. In this context, UNCCD has been engaged in enhancing the adaptive capacities of dryland populations to highly variable environmental conditions.</font> After several years of discussion on definitions and content, current efforts strive to provide information on the implementation and financing of EbA measures and to fill knowledge gaps on the links between climate change and biodiversity (see recent decisions at CBD COP 10). A database on EbA approaches was mandated in the context of the UNFCCC Nairobi work programme in 2011. Under the same programme a workshop on ecosystem-based approaches for adaptation is to be held in 2013 in cooperation with the CBD and UNCCD, which will consider the synergies and lessons learned through the implementation of the three Rio Conventions.
The most important donors for EbA-related activities in Germany are the Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU) and the Federal Ministry for Economic Cooperation and Development (BMZ). Adaptation to climate change is part of the BMZ portfolio on "climate policy and climate financing" and of growing interest due to its strong interlinkage with poverty alleviation. Funding is mostly provided by the Energy and Climate Fund (EKF) and the International Climate Change Initiative (IKI). Within IKI the BMU has focused on the "green sector" since 2008 and EbA was consequently introduced to the funding portfolios as a priority area in 2010 and 2011 (see selection procedure).</font> In GIZ the implementation of EbA varies from EbA as a cross-sectoral issue in mainstreaming adaptation to climate change into development to single EbA components, measures or specific EbA projects. Already several ongoing GIZ projects practice EbA measures in the context of natural resource management without labelling them as such (see section "Must haves and nice to haves").
Apart from the intended outcomes, EbA measures tend to generate additional co-benefits such as carbon sequestration or biodiversity conservation, improved livelihood conditions and are generally considered no-regret options. To determine the specific requirements of maintaining or restoring an ecosystem and its services, EbA ideally draws on studies of climate change impacts or integrated climate analyses, which make use of climate scenarios and models. Worldwide surveys have shown that restoration and conservation of ecosystems are generally very cost effective and highly profitable for maintaining ecosystem services. In comparison to the economic loss caused by loss of ecosystem services, the cost-benefit ratio of return of investment of appropriate restoration of ecosystems may be as high as 3 to 75, depending on the ecosystem context and the measures taken (UNEP 2010, 6). For example, a study in Vietnam shows that planting or maintaining mangrove forests to act as breakwaters for coastal protection is significantly cheaper (costing 1.1 million USD for 12,000 hectares) than mechanical repair of wave-induced dike erosion (costing 3.7 million USD annually) (IFRC: World Disasters Report 2002, 95). Climate change manifests itself in many different ways, such as changed patterns in temperature, precipitation or seasons.
Adaptation approaches therefore have to regard the interdependencies between the climatic, ecological, social and economic dimensions. The proposed EbA approach, being based on elaborate cause-and-effect chains, as explained in the following section, enables the integration of adaptation benefits right from the planning phase. Thus it is drawing adaptive capacity from ecosystem and ecosystem services as well as strengthening their resilience against climate change.
It is important to differentiate between utilizing ecosystem services for an adaptation purpose (EbA) and adapting ecosystems and ecosystem management to climate change in order to maintain their services (adaptation of ecosystems). The latter can be neccessary to sustain ecosystem services under the pressure of a changing climate.
EbA measures need to be founded on a sound analysis of the complex interdependencies between ecosystems, the flow of ecosystem services and dependent communities. In order to distinguish the cause-and-effect relationships of driving forces, pressures, states, impacts and responses within these spheres, the DPSIR conceptual framework is being applied.
In the following, this framework will be explained and illustrated with the aid of two GIZ projects from Vietnam. The example is simplified for better understanding. The projects “Sustainable Management of Coastal Forest Ecosystems in Bac Lieu Province” (2009-2011) and “Management of Natural Resources in the Coastal Zone of Soc Trang Province”4 (ongoing since 2007) contain exemplary EbA measures and have already shown positive results. Both projects support the protection of coastal zones through the restoration and management of coastal mangrove forests. The pressure of climate change threatens the coastal regions of Vietnam with a sea level rise of up to 0.6 m by 2100, increased temperatures, changed seasonal patterns, and more intense and more frequent tropical cyclones. Additional anthropogenic pressures are economical (intensive rice farming, rapid expansion of lucrative shrimp farms directly bordering on mangrove sanctuaries), political (overlapping responsibilities and lack of administrational capacities of authorities) and social (poverty, lack of cooperation of different actors) causes.
In a healthy state, coastal mangrove forests provide nurseries and habitats for fish, molluscs, crustaceans, birds, insects, mammals and reptiles, protection of the landward zone, flood mitigation and stabilization of the groundwater level. The special root system of mangrove trees slows the water flow, traps sediment, thus stabilizing the soil and alleviating storm and wave damage. Further, they shelter bacteria which break down ammonium and nitrate, allowing for a higher stocking density of shrimps without the use of chemical additives and consequently reduce the total default risk. Their shade also helps to moderate heat spells in shrimp ponds. However, due to anthropogenic and climate- related pressures, the mangrove ecosystem is partially degraded and increasingly vulnerable, subsequently causing the ecosystem services to decline. The impact is present in the decreased protection of settlements and agriculture, the receding shoreline, the advance of salty sea water further inland, causing groundwater and soil to become saline and eventually leading to hypersaline flats. In turn, the production of biomass as well as growth and seedling recruitment are declining, likely leading to a change in species composition. The continuous decline of mangrove forests and resulting salination of agricultural land pushes land use changes from rice to shrimp farming. The already little diversified local economy is even more at risk of income losses through shrimp epidemics. As a response, in Vietnam the EbA measures focus on rehabilitation and conservation activities as well as the promotion of sustainable management practices. The rehabilitation of degraded coastal forests through afforestation and seedling protection restores declined ecosystem services. The indication of protected zones where logging and shrimp farming is not allowed, contributes to conserves the ecosystems. Further, management schemes for mangrove forests and shrimp farms have been introduced. They include fishing regulations and promote alternative income opportunities for local communities. These measures strengthen the resilience of local communities by reducing the drivers of ecosystem degradation and maintaining the ecosystem services.
BfN (2011): Ecosystem–based approaches to adaptation and mitigation — good practice examples and lessons learned in Europe. IUCN (2009): Ecosystem–based Adaptation: A natural response to climate change. Jones, Hole and Zavaleta (2012): Harnessing nature to help people to adapt to climate change, in Perspective. Nature climate change, 504-509. Proact Network (2008): The Role of Environmental Management and eco-engineering in Disaster Risk Reduction and Climate Change Adaptation. UNEP, SREP (2012): A comparative analysis of ecosystem–based adaptation and engineering options for Lami Town, Fiji. UNEP (2012): Ecosystem-Based Adaptation Guidance, Moving from Principles to Practice. UNEP, UNDP, IUCN, BMU (2012): Making the case for ecosystem-based adaptation. Building resilience to climate change. Worldbank (2009): Convenient Solutions to an Inconvenient Truth: Ecosystem–based Approaches to Climate Change.
The EbA mainstreaming cycle explains how to integrate
EbA into a project, policy or planning process. Following
the different steps is closely related to the step-by-step approach
of the tool “Climate Proofing for Development”,
pinpointing the particularities of EbA. Figure 2 visualizes
the EbA mainstreaming cycle and gives some examples of
tools, methods and approaches that can be utilized at each
step (still work in progress). In the beginning, the exposure
unit (region, sector, etc.) is screened by applying a climate
lens. To be able to sustain development efforts also in a context
of climate change, adaptation needs are being assessed
in step 2. The vulnerability assessment considers exposure,
sensitivity and adaptive capacity. To identify interdependencies
the DPSIR framework can be of help. EbA specifies are
most prominent in the following steps: identification, selection
and implementation of adaptation options. In step
3 EbA options should be considered next to other adaptation
options. In step 4 decision makers will need arguments
for choosing EbA measures. A proactive communication
concept for EbA will be helpful in familiarizing stakeholders
with potential advantages. Once EbA options have been
chosen another question arises for the implementation (step
5). Only functioning ecosystems and their services can be
used for the purpose of adaptation. However, they are often
affected by anthropogenic pressures and there might be
additional threats from climate change which are becoming
more and more important. Thus, within an EbA approach,
activities to adapt ecosystems to the effects of climate
change can be of importance to secure the EbA options
which have been chosen. The evaluation concludes the cycle.
Monitoring instead is a process coherent in every stage
(see “Adaptation made to measure”).
The knowledge on EbA implementation is constantly being
refined and complemented. While some elements in project
design are seen as a necessity in EbA measures and must
be included (“must haves”), others are additional steps that
complement the measure (“nice to have”), a categorisation
which is still to be elaborated further. In the following, EbA
“must haves” and “nice to have” will be explained with the
aid of a concrete project example, the project “Adaptation
to climate change by promoting the biodiversity in province
Bac Lieu”, Vietnam”. The Mekong Delta was identified by
the Worldbank and the IPCC as one of the regions most
threated by climate change. Different climate scenarios
predict increasing flooding events, tropical storms, a rise in
sea level and soil salination in the near future. At the same
time, natural protection systems against these threats, such as mangrove forests, are heavily degraded through intensive
monocultures, shrimp farming and unsustainable use of resources.
The main objective of the project is to increase the
protective function of the coastal forests through sustainable
resource management and the promotion of biodiversity.
Moreover, additional complementary measures can be taken,
so-called “nice to haves”. These include:
• Quantification of ecosystem services and cost-benefit
analyses (for more information see manual Integrating
Ecosystem Services into Development Planning).
• Examples for opportunity costs (EbA infrastructure
measures): Mangrove reforestation and renaturation, for
example, greatly reduces costs of dike construction and
maintenance.
• Sustainably functioning financing mechanisms, for
instance Payments for Ecosystem Services (PES): landowners
and users are offered monetary or non-monetary
incentives in exchange for managing their land to provide
certain quantity or quality of ecosystem services,
e.g. payments of downstream river users to upstream
users for proper waste management to reduce river pollution.
Bearing these aspects in mind when designing and implementing
an EbA project is an important step towards avoiding
pitfalls, such as the accidental introduction of non-native
invasive species, inadequate integration of stakeholders
and socio-economic issues or improper and partial restoration
resulting in monocultures with little ecosystem service
capacity.
The implementation of EbA measures can be based on either
a certain ecosystem service (e.g. water retention), part
of an ecosystem or one or several ecosystems. Each sector,
on the other hand, should regard its relevant ecosystem
services and the underlying ecosystems in the water sector,
for example groundwater recharge can be provided by
a range of ecosystems such grassland, peatlands or rivers.
All of those should be included in the process of selecting
the best measures for adaptation. In general the type and
state of the ecosystem as well as the intended outcome determine
the measures to choose. The following table gives
an overview of some ecosystems, a selection of services they
provide, measures that can be applied and outcomes they
may achieve.