Bibliography

Welcome to our interactive bibliography. Here you can explore publications relating to Nature-based Solutions and their potential to address societal challenges, including climate change adaptation & mitigation, disaster risk reduction, ecosystem health, food & water security, and human wellbeing & development. For papers and other outputs directly produced by the Nature-based Solutions Initiative please visit our outputs page.

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711 publications found

  • Achieving the national development agenda and the Sustainable Development Goals (SDGs) through investment in ecological infrastructure: A case study of South Africa

    Cumming T. L. et al. Ecosystem Services (2017). Review.
    https://doi.org/10.1016/j.ecoser.2017.05.005

    Abstract

    Ecological infrastructure (EI) refers to ecosystems that deliver services to society, functioning as a nature-based equivalent of, or complement to, built infrastructure. EI is critical for socio-economic development, supporting a suite of development imperatives at local, national and international scales. This paper presents the myriad of ways that EI supports sustainable development, using South Africa and the South African National Development Plan as a case study, linking to the Sustainable Development Goals on a global level. We show the need for EI across numerous development and sustainability issues, including food security, water provision, and poverty alleviation. A strategic and multi-sectoral approach to EI investment is essential for allocating scarce public and private resources for achieving economic and social-ecological priorities. Opportunities to unlock investment in EI, both internationally and on the national level, are identified. This includes leveraging private sector investment into landscape management and integrating the costs of managing EI into public sectors that benefit directly from ecosystem services, such as the water sector and infrastructure development. Additionally, investing in EI also aligns well with international development and climate change funds. Investment in EI from a range of innovative sources supports global and national development, while complementing other development investments.

    Area-based approachesEcosystem-based disaster risk reductionEcological restorationEcosystem-based adaptationEcosystem-based mitigationInfrastructure-related approachesClimate change adaptationClimate change mitigationDisaster risk reductionEcosystem healthFood and water securityHuman well-being & developmentArtificial Landscapes - TerrestrialForestGrasslandWetland
  • The role of fish and fisheries in recovering from natural hazards: Lessons learned from Vanuatu

    Eriksson H. et al. Environmental Science and Policy (2017). Original Research.
    http://dx.doi.org/10.1016/j.envsci.2017.06.012

    Abstract

    Coastal fisheries provide staple food and sources of livelihood in Pacific Island countries, and securing a sustainable supply is recognised as a critical priority for nutrition security. This study sought to better understand the role of fish for Pacific Island communities during disasters and in disaster recovery. To evaluate community impacts and responses after natural disasters, focus group discussions were held with men and women groups at ten sites across Shefa, Tafea, Malampa and Sanma provinces in Vanuatu. The combined impacts of category 5 Tropical Cyclone Pam (TC-Pam) in March 2015 and prolonged El-Niño induced drought have had a profound impact across much of Vanuatu. Terrestrial systems had been disproportionately impacted with substantial shortages in drinking water, garden crops, cash crops and damage to infrastructure. Localized impacts were noted on marine environments from TC-Pam and the drought, along with an earthquake that uplifted reef and destroyed fishing grounds in Malampa province. Communities in Malampa and Shefa provinces also noted a crown-of-thorns outbreak that caused coral mortality. The significant reduction in terrestrial-based food and income generation capacity generally led to increased reliance on marine resources to cope and a shift in diets from local garden food to rice. However, limited market access, lack of fishing skills and technology in many sectors of the community reduced the capacity for marine resources to support recovery. A flexible management approach allowed protected areas and species to be utilized as reservoirs of food and income when temporarily opened to assist recovery. These findings illustrate that fish and fisheries management is at the center of disaster preparedness and relief strategies in remote Pacific Island communities. High physical capital (e.g. infrastructure, water tanks and strong dwellings) is key for disaster preparedness, but supporting community social capital for the purpose of natural resource management and human capital for diverse adaptation skills can also improve community resilience. Recognizing the humanitarian value that well managed fisheries resources and skilled fishers can play to disaster relief adds another dimension to the imperative of improving management of coastal fisheries and aligning policies across sectors.

    Area-based approachesEcosystem-based disaster risk reductionNatural resource managementDisaster risk reductionFood and water securityHuman well-being & developmentMarine
  • Dune dynamics safeguard ecosystem services

    Van der Biest K. et al. Ocean and Coastal Management (2017). Original Research.
    https://doi.org/10.1016/j.ocecoaman.2017.10.005

    Abstract

    Intensively used coastal zones often know a history of hard defense structures to prevent erosion and protect infrastructure against floods. The interruption of sand transport between sea, beach and dunes however causes a domination of late successional stages such as dune shrub. With the decline of young, dynamic vegetation types, a change occurs in the provision of ecosystem services. In spite of the growing awareness on the role of dune dynamics to support human well-being and biodiversity, redynamisation of dunes is rarely implemented in coastal zone management. It has been argued in research documents that this may be caused by a failure to make those benefits tangible and specific. This study aims to underpin the added value of dynamic versus fixed dunes. Five different ecosystem services in a case-study in Belgium were quantified based on (compound) indicators and expressed in monetary units. The value of a natural, dynamic dune system covering the entire gradient of dune succession and dominated by young successional stages was compared with the value of a fixed dune system dominated by late successional stages. The results indicate that a dynamic dune complex may create up to ∼50% higher economic benefits, and that the main benefits are on account of recreation and coastal safety maintenance. The results underpin the statement that we can only continue benefitting from the services dunes provide if we accept their mobile nature, but that redynamisation requires a site-specific feasibility analysis.

    Ecosystem-based disaster risk reductionEcological restorationClimate change mitigationDisaster risk reductionFood and water securityHuman well-being & developmentCoastline
  • Marine reserves can mitigate and promote adaptation to climate change

    Roberts, C.M. et al. PNAS (2017). Perspective.
    https://doi.org/10.1073/pnas.1701262114

    Abstract

    Strong decreases in greenhouse gas emissions are required to meet the reduction trajectory resolved within the 2015 Paris Agreement. However, even these decreases will not avert serious stress and damage to life on Earth, and additional steps are needed to boost the resilience of ecosystems, safeguard their wildlife, and protect their capacity to supply vital goods and services. We discuss how well-managed marine reserves may help marine ecosystems and people adapt to five prominent impacts of climate change: acidification, sea-level rise, intensification of storms, shifts in species distribution, and decreased productivity and oxygen availability, as well as their cumulative effects. We explore the role of managed ecosystems in mitigating climate change by promoting carbon sequestration and storage and by buffering against uncertainty in management, environmental fluctuations, directional change, and extreme events. We highlight both strengths and limitations and conclude that marine reserves are a viable low-tech, cost-effective adaptation strategy that would yield multiple cobenefits from local to global scales, improving the outlook for the environment and people into the future

    Not applicableClimate change adaptationClimate change mitigationDisaster risk reductionEcosystem healthCoastlineMarine
  • Contribution of trees to the conservation of biodiversity and ecosystem services in agricultural landscapes

    Barrios, E. et al. International Journal of Biodiversity Science, Ecosystem Services & Management (2017). Original Research.
    https://doi.org/10.1080/21513732.2017.1399167

    Abstract

    The production of sufficient food for an increasing global population while conserving natural capital is a major challenge to humanity. Tree-mediated ecosystem services are recognized as key features of more sustainable agroecosystems but the strategic management of tree attributes for ecosystem service provision is poorly understood. Six agroforestry and tree cover transition studies, spanning tropical/subtropical forest zones in three continents, were synthesized to assess the contribution of tree cover to the conservation of biodiversity and ecosystem services. Loss of native earthworm populations resulted in 76% lower soil macroporosity when shade trees were absent in coffee agriculture. Increased tree cover contributed to 53% increase in tea crop yield, maintained 93% of crop pollinators found in the natural forest and, in combination with nearby forest fragments, contributed to as much as 86% lower incidence for coffee berry borer. In certain contexts, shade trees contributed to negative effects resulting from increases in abundance of white stem borer and lacebugs and resulted in 60% reduction of endangered tree species compared to forest. Managing trees for ecosystem services requires understanding which tree species to include and how to manage them for different socio-ecological contexts. This knowledge needs to be shared and translated into viable options with farming communities.

    Not applicableEcosystem healthFood and water securityHuman well-being & developmentArtificial Landscapes - TerrestrialForest
  • Agroforestry Can Enhance Food Security While Meeting Other Sustainable Development Goals

    Waldron, A. et al Tropical Conservation Science (2017). Perspective.
    https://doi.org/10.1177%2F1940082917720667

    Abstract

    To achieve global food security, we need to approximately double food production over the coming decades. Conventional agriculture is the mainstream approach to achieving this target but has also caused extensive environmental and social harms. The consensus is that we now need an agriculture that can “multi-functionally” increase food production while simultaneously enhancing social and environmental goals, as committed to in the sustainable development goals (SDGs). Farming also needs to become more resilient to multiple insecurities including climate change, soil degradation, and market unpredictability, all of which reduce sustainability and are likely to exacerbate hunger. Here, we illustrate how agroforestry systems can increase yield while also advancing multiple SDGs, especially for the small developing-world agriculturalists central to the SDG framework. Agroforestry also increases resilience of crops and farm livelihoods, especially among the most vulnerable food producers. However, conventional yield-enhancement strategies have naturally dominated the debate on food production, hindering implementation of more multifunctional alternatives. Governments and institutions now have the opportunity to rebalance agricultural policy and investment toward such multigoal approaches. In doing so, they could achieve important improvements on multiple international commitments around the interlinked themes of food security, climate change, biodiversity conservation, and social well-being.

    Not applicableEcosystem healthFood and water securityHuman well-being & developmentArtificial Landscapes - TerrestrialForest
  • Grazing exclusion to recover degraded alpine pastures needs scientific assessments across the Northern Tibetan Plateau

    Yu, C et al. Sustainability (2016). Original Research.
    http://www.mdpi.com/2071-1050/8/11/1162/htm

    Abstract

    The northern Tibetan Plateau is the most traditional and important semi-nomadic region in Tibet. The alpine vegetation is sensitive and vulnerable to climate change and human activities, and is also important as an ecological security in protecting the headwaters of major rivers in Asia. Therefore, the Tibetan alpine grasslands have fundamental significance to both Mainland China and South Asia. The pasture degradation, however, likely threatens the livelihood of residents and the habitats of wildlife on this plateau. Since 2004, the government has launched a series of ecological restoration projects and economic compensatory payment polices. Many fences were additionally built on degraded pastures to prevent new degradation, to promote functionality recovery, and to balance the stocking rate with forage productivity. The grazed vs. fenced paired pastures across different zonal grassland communities along evident environmental gradients provide us with a natural comparative experiment platform to test the relative contributions of natural and anthropogenic factors. This study critically reviews the background, significance of and debates on short-term grazing exclusion with fences in this region. We also aim to figure out scientific and standardized workflows for assessing the effectiveness of grazing exclusion and compensatory payments in the future.

    Ecological restorationNature-based agricultural systemsClimate change adaptationHuman well-being & developmentMontane
  • Conservation Effects on Soil Quality and Climate Change Adaptability of Ethiopian Watersheds

    Mengistu, D. et al. Land Degradation and Development (2016). Original Research.
    https://doi.org/10.1002/ldr.2376

    Abstract

    This study analyzes effects of soil and water conservation (SWC) on soil quality and implications to climate change adaptation and mitigation in the Upper Blue Nile River Basin of Ethiopia by using the Anjeni watershed as a case study site. Disturbed and undisturbed soil samples were collected from two sub-watersheds of Anjeni: the Minchet sub-watershed (with SWC measures) and the Zikrie sub-watershed (without SWC measures). Soil samples were taken from 30-cm depth from five representative landscape positions and analyzed following the standard soil lab analysis procedures. The results show that soils from the conserved sub-watershed had improved quality indicators compared with those from the non-conserved site. Significant improvement due to SWC measures was observed in the soil hydrological [total moisture content (+5·43%), field capacity (+5·35%), and available water capacity (+4·18%)] and chemical [cation exchange capacity (+4·40 cmol(+) kg-1 ), Mg2+ (+1·90 cmol(+) kg-1 ), Na+ (+0·10 cmol(+) kg-1 )] properties. SWC interventions significantly reduced soil erosion by 57–81% and surface runoff by 19–50% in the conserved sub-watershed. Reduction in soil erosion can maintain the soil organic carbon stock, reduce the land degradation risks, and enhance the C sequestration potential of soils. Therefore, adoption of SWC measures can increase farmers’ ability to offset emissions and adapt to climate change. However, SWC measures that are both protective and sufficiently productive have not yet been implemented in the conserved sub-watershed. Therefore, it is important that SWC structures be supplemented with other biological and agronomic measures in conjunction with soil fertility amendments appropriate to site-specific conditions.

    Ecological restorationClimate change adaptationHuman well-being & developmentForest
  • Climate Resilient Villages for Sustainable Food Security in Tropical India: Concept, Process, Technologies, Institutions, and Impacts

    Rao, C. S. et al. Advances in Agronomy (2016). Review.
    https://doi.org/10.1016/bs.agron.2016.06.003

    Abstract

    The world population is expected to increase by a further three billion by 2050 and 90% of the three billion will be from developing countries that rely on existing land, water, and ecology for food and well-being of human kind. The Intergovernmental Panel on Climate Change (IPCC) in its fifth assessment report (AR5) stated that warming of the climate system is unequivocal and is more pronounced since the 1950s. The atmosphere and oceans have warmed, the amounts of snow and ice have diminished, and sea level has risen. Each of the last three decades has been successively warmer at the earth’s surface than any preceding decade since 1850 and the globally averaged combined land and ocean surface temperature data as calculated by a linear trend show a warming of 0.85 degrees C (0.65-1.06 degrees C) over the period of 1880-2012. World Meteorological Organization (WMO) ranked 2015 as the hottest year on record. Climate change poses many challenges to growth and development in South Asia. The Indian agriculture production system faces the daunting task of feeding 17.5% of the global population with only 2.4% of land and 4% of water resources at its disposal. India is more vulnerable to climate change in view of the dependence of huge population on agriculture, excessive pressure on natural resources, and relatively weak coping mechanisms. The warming trend in India over the past 100 years has indicated an increase of 0.6 degrees C, which is likely to impact many crops, negatively impacting food and livelihood security of millions of farmers. There are already evidences of negative impacts on yield of wheat and paddy in some parts of India due to increased temperature, water stress, and reduction in number of rainy days. Significant negative impacts have been projected under medium-term (2020-39) climate change scenario, for example, yield reduction by 4.5-9%, depending on the magnitude and distribution of warming. Since agriculture currently contributes about 15% of India’s gross domestic product (GDP), a negative impact on production implies cost of climate change to roughly range from 0.7% to 1.35% of GDP per year. Indian agriculture, with 80% of farmers being smallholders (<0.5 ha) having diverse socioeconomic backgrounds, is monsoon-dependent rainfed agriculture (58%), about 30% of population undernourished, migration from rural to urban regions, child malnutrition etc., has become more vulnerable with changed climate or variability situations. During the past decade, frequency of droughts, cyclone, and hailstorms increased, with 2002, 2004, 2009, 2012, and 2014 being severe droughts. Frequent cyclones and severe hailstorms in drought prone areas have become common. Eastern part of the country is affected by seawater intrusion. Reduced food grain productivity, loss to vegetable and fruit crops, fodder scarcity, shortage of drinking water to animals during summer, forced migration of animals, severe loss to poultry and fishery sectors were registered, threatening the livelihoods of rural poor. Enhancing agricultural productivity, therefore, is critical for ensuring food and nutritional security for all, particularly the resource-poor, small, and marginal farmers who would be the most affected. In the absence of planned adaptation, the consequences of long-term climate change on the livelihood security of the poor could be severe. In India, the estimated countrywide agricultural loss in 2030 is expected to be over $ 7 billion that will severely affect the income of at least 10% of the population. However, this could be reduced by 80%, if cost-effective climate resilient measures are implemented. Climate risks are best addressed through increasing adaptive capacity and building resilience which can bring immediate benefits and can also reduce the adverse impacts of climate change. Climate resilient agriculture (CRA) encompasses the incorporation of adaptation and resilient practices in agriculture which increases the capacity of the system to respond to various climate-related disturbances by resisting damage and ensures quick recovery. Such disturbances include events such as drought, flood, heat/cold wave, erratic rainfall pattern, pest outbreaks, and other threats caused by changing climate. Resilience is the ability of the system to bounce back and essentially involves judicious and improved management of natural resources, land, water, soil, and genetic resources through adoption of best bet practices. CRA is a way to achieve short-and long-term agricultural development priorities in the face of climate change and serves as a bridge to other development priorities. It seeks to support countries and other actors in securing the necessary policy, technical and financial conditions to enable them to: (1) sustainably increase agricultural productivity and incomes in order to meet national food security and development goals, (2) build resilience and the capacity of agricultural and food systems to adapt to climate change, and (3) seek opportunities to mitigate emissions of greenhouse gases (GHGs) and increase carbon sequestration. These three conditions (food security, adaptation, and mitigation) are referred to as the 'triple win' of overall CRA. The concept of climate resilient village (CRV) has been taken up by Government of India, to provide stability to farm productivity and household incomes and resilience through livelihood diversification in the face of extreme climatic events like droughts, cyclones, floods, hailstorms, heat wave, frost, and seawater inundation. Development of CRVs warrants establishment of a host of enabling mechanisms to mobilize and empower communities in the decision-making process to manage and recover from climate risks. The overall program of establishing CRVs have structured village level institutions such as Village Climate Risk Management Committee (VCRMC), custom hiring center (CHC) for farm implements, community seed and fodder banks, commodity groups etc. The establishment of CRVs was based on bottom-up approach with village community taking a central role in decision making on institutional requirements, technological interventions and supporting systems with able support from experts. In our knowledge, the CRV network of National Initiative on Climate Resilient Agriculture (NICRA) is by far the largest outreach program involving farmer's participation ever undertaken in the field of climate change adaptation anywhere in the world. Planning, coordination, monitoring, and capacity building of the program at the country level is the responsibility of the research organization (ICAR-Central Research Institute for Dryland Agriculture). At the district level, Krishi Vigyan Kendra (KVK; Farm Science Centre) under the Division of Agricultural Extension under Indian Council of Agricultural Research (ICAR), All India Coordinated Research Project for Dryland Agriculture (AICRPDA) centers and Transfer of Technology divisions of various ICAR Institutions across the country are responsible in implementing the project at village level through farmers' participatory approach. To address the climate vulnerabilities of the selected villages, different interventions were planned under the four modules; however, the specific intervention under each module for a particular village was need based and decided based on climatic vulnerability and resource situation of the particular village. The four intervention modules being implemented are (1) Natural resource management (in situ moisture conservation, biomass mulching, residue recycling, manure management, soil health card-based nutrient application, water harvesting and recycling for supplementary or life saving irrigation, improved drainage in high rainfall/flood prone villages, conservation tillage, and water saving irrigation methods). (2) Crop production module consisting of introduction of short-duration and drought/flood-tolerant varieties, modifications in planting dates for postrainy (winter) season crops to cope with terminal heat stress, water saving paddy systems (System of Rice Intensification, aerobic, direct seeding), frost management in fruit/vegetables, community nursery in staggered dates to meet delay in onset of monsoon, energy-efficient farm machinery through village CHC with timely completion of farm operation in limited sowing window, location specific intercropping systems, and suitable agroforestry systems. (3) Module III covers livestock and fisheries interventions through augmentation of fodder production, fodder storage methods, prophylaxis, and improved shelters for reducing heat stress in livestock, management of fish ponds/tanks during water scarcity and excess water, and promotion of livestock as climate adaptation strategy. (4) Module IV consists of village level institutions, collective marketing groups, introduction of weather-based insurance, and climate literacy though establishment of automated weather stations. Impacts of these climate resilient interventions in the villages were assessed through various resilience indicators, importantly, improved farm productivity, farm income, livelihoods at household and village level. Environmental impacts were assessed on improved soil carbon sequestration, groundwater recharge, vegetation and forest cover, and measurements of GHG emissions which were correlated with ex ante assessment of village level carbon balance and overall contribution to global warming potential. These 151 CRVs are learning sites for further expanding resilient villages to adjoining clusters and districts so that large number of villages will become part of the overall adaptation-led climate change mitigation mission in the country.

    Ecosystem-based adaptationNature-based agricultural systemsClimate change adaptationFood and water securityHuman well-being & developmentArtificial Landscapes - Terrestrial
  • Knowing but not knowing: Systematic conservation planning and community conservation in the Sierra Norte of Oaxaca, Mexico

    van Vleet, E. et al. Land Use Policy (2016). Original Research.
    https://doi.org/10.1016/j.landusepol.2016.09.010

    Abstract

    Systematic conservation planning (SCP) seeks to propose new reserves through a scientifically rigorous process using databases and research selection algorithims. However, SCP exercises have been criticized for “knowing but not doing”, i.e. not implementing the proposed reserve. But there is an additional problem that can be called “knowing but not knowing”, knowing things from databases, but not knowing crucial contextual information about community-based social processes that have supported the high forest cover and biodiversity detected. Examined here is how a common property region of the Sierra Norte of Oaxaca, Mexico has maintained high forest cover in the absence of public protected areas, while multiple SCP exercises have advocated for the creation of public protected areas in communal tropical montane cloud forests and pine forests as strategies for biodiversity conservation and resilience to climate change. Methods included archival research, review of community documents, focus group interviews, semi-structured interviews, participant observation, land use transects, and GIS analysis and remote sensing. Conservation in the region originally occurred because of low population densities, steep slopes and a lack of agricultural subsidies, supported by locally adapted agricultural practices. In the 1990s, a transition from passive to active conservation took place with land use zoning plans, community conservation rules, community forestry enterprises and payments for environmental service programs that consolidated a trend towards high, unthreatened forest cover. Today, the study communities have an average of 88.3% forest cover, with 61% of that in informal conservation based on community land use zoning and rules and another 14% governed by forest management plans approved by the Mexican government. We argue thattruly systematic conservation plans would seek to understand how communities in the region are already managing forests for conservation. It is pointless and uninformed to advocate for top-down conservation interventions of forests that are already robustly conserved and resilient to climate change due to community action.

    Area-based approachesEcosystem-based mitigationNatural resource managementNature-based agricultural systemsClimate change adaptationClimate change mitigationEcosystem healthHuman well-being & developmentArtificial Landscapes - TerrestrialForestMontane
  • How rural land use management facilitates drought risk adaptation in a changing climate – A case study in arid northern China

    Lei, Y. D. et al. Science of the Total Environment (2016). Original Research.
    https://doi.org/10.1016/j.scitotenv.2016.01.098

    Abstract

    Under a warming climate, frequent drought and water scarcity in northern China have severely disrupted agricultural production and posed a substantial threat to farmers’ livelihoods. Based on first-hand data collected through in-depth interviews with local managers and farmer households, this study evaluated the effectiveness of rural land use management in mitigating drought risk, ensuring food security and improving farmers’ livelihoods. Our findings indicate that a) reforestation on low-yield cropland not only can improve the ecoenvironment but can also prominently mitigate the production risk to local farmers; b) replacing the traditional border irrigation with sprinkler irrigation has substantially curbed agricultural water usage and increased the per unit of output; and c) in recent years, instead of planting water-intensive grain crops, local farmers cultivated more forage crops to raise animals, which greatly diversified their income sources and reduced the drought risk of agricultural production. By performing an empirical case study in drought-prone Inner Mongolia, this study provides decision-makers with insights into how to strategically adapt to drought risk and reduce rural poverty within the broader context of climate change.

    Ecological restorationEcosystem-based adaptationNature-based agricultural systemsClimate change adaptationDisaster risk reductionFood and water securityHuman well-being & developmentArtificial Landscapes - TerrestrialForest
  • A quantitative evaluation of the multiple narratives of the recent Sahelian regreening

    Stith, M. et al. Weather Climate and Society (2016). Original Research.
    https://doi.org/10.1175/WCAS-D-15-0012.1

    Abstract

    A spatial analysis is presented that aims to synthesize the evidence for climate and social dimensions of the ‘regreening” of the Sahel. Using an independently constructed archival database of donor-funded interventions in Burkina Faso, Mali, Niger, and Senegal in response to the persistence of drought in the 1970s and 1980s, the spatial distribution of these interventions is examined in relation to population density and to trends in precipitation and in greenness. Three categories of environmental change are classified: 1) regions at the northern grassland/shrubland edge of the Sahel where NDVI varies interannually with precipitation, 2) densely populated cropland regions of the Sahel where significant trends in precipitation and NDVI decouple at interannual time scales, and 3) regions at the southern savanna edge of the Sahel where NDVI variation is independent of precipitation. Examination of the spatial distribution of environmental change, number of development projects, and population density brings to the fore the second category, covering the cropland areas where population density and regreening are higher than average. While few, regions in this category coincide with emerging hotspots of regreening in northern Burkina Faso and southern central Niger known from case study literature. In examining the impact of efforts to rejuvenate the Sahelian environment and livelihoods in the aftermath of the droughts of the 1970s and 1980s against the backdrop of a varying and uncertain climate, the transition from desertification to regreening discourses is framed in the context of adaptation to climate change.

    Ecological restorationEcosystem-based managementNature-based agricultural systemsDisaster risk reductionFood and water securityHuman well-being & developmentArtificial Landscapes - TerrestrialGrasslandSavanna
  • Linking agricultural adaptation strategies, food security and vulnerability: evidence from West Africa

    Douxchamps, S. et al. Regional Environmental Change (2016). Original Research.
    https://doi.org/10.1007/s10113-015-0838-6

    Abstract

    Adaptation strategies to reduce smallholder farmers’ vulnerability to climate variability and seasonality are needed given the frequency of extreme weather events predicted to increase during the next decades in sub-Saharan Africa, particularly in West Africa. We explored the linkages between selected agricultural adaptation strategies (crop diversity, soil and water conservation, trees on farm, small ruminants, improved crop varieties, fertilizers), food security, farm household characteristics and farm productivity in three contrasting agro-ecological sites in West Africa (Burkina Faso, Ghana and Senegal). Differences in land area per capita and land productivity largely explained the variation in food security across sites. Based on land size and market orientation, four household types were distinguished (subsistence, diversified, extensive, intensified), with contrasting levels of food security and agricultural adaptation strategies. Income increased steadily with land size, and both income and land productivity increased with degree of market orientation. The adoption of agricultural adaptation strategies was widespread, although the intensity of practice varied across household types. Adaptation strategies improve the food security status of some households, but not all. Some strategies had a significant positive impact on land productivity, while others reduced vulnerability resulting in a more stable cash flow throughout the year. Our results show that for different household types, different adaptation strategies may be ‘climate-smart’. The typology developed in this study gives a good entry point to analyse which practices should be targeted to which type of smallholder farmers, and quantifies the effect of adaptation options on household food security. Subsequently, it will be crucial to empower farmers to access, test and modify these adaptation options, if they were to achieve higher levels of food security.

    Ecosystem-based adaptationNature-based agricultural systemsClimate change adaptationFood and water securityHuman well-being & developmentArtificial Landscapes - Terrestrial
  • Are we adapting to climate change? A catchment-based adaptation assessment tool for freshwater ecosystems

    Lukasiewicz, A. et al. Climatic Change (2016). Methodological Article. Original Research.
    https://doi.org/10.1007/s10584-016-1755-5

    Abstract

    Freshwater ecosystems in many parts of the world have been severely affected by past management practices that have altered the volume, timing and quality of water flows and caused a decline in their ecological health. Some of these systems are also experiencing the negative impacts of climate change. Adaptation to climate change and the continual need to address existing ecological damage poses ongoing challenges for freshwater managers. In this paper we propose and discuss a Catchment Assessment Framework (CAF) that is used to evaluate existing and potential freshwater management actions, such as riparian revegetation and habitat connectivity, for their adaptation potential. The CAF was developed as a tool for prioritizing low risk climate change adaptation options in Australian catchment management. The CAF enables catchment managers and technical experts to assess management actions against seven inter-related criteria to provide a holistic assessment: relevance to the catchment; climate change adaptation potential, including potential for maladaptation and benefit under different climate scenarios; ecosystem service benefits; compatibility with other actions; implementation constraints; socio-economic consequences; and a risk assessment. It was developed and applied by assessing nine management options with stakeholders in three catchments within the Murray-Darling Basin in south-eastern Australia. We found that while management options are undertaken as a response to existing degradation, they can be used as building blocks for a climate change adaptation strategy that considers a range of different but complementary measures to better manage climate-related risk. The CAF enables practitioners to assess the advantages of a range of adaptation options and to subject them to their wider decision making and management planning.

    Ecosystem-based adaptationNatural resource managementClimate change adaptationEcosystem healthWetland
  • Can mangroves keep pace with contemporary sea level rise? A global data review

    Sasmito, S. D. et al. Wetlands Ecology and Management (2016). Meta-Analysis.
    https://doi.org/10.1007/s11273-015-9466-7

    Abstract

    Coastal vegetated wetlands such as mangrove forests provide multiple ecosystem services, though are potentially threatened by contemporary accelerated sea level rise (SLR), in addition to other immediate threats such as agriculture and coastal development. Several studies have revealed that mangroves are able to adapt to, and keep pace with local relative SLR through vertical surface elevation change (SEC), however data are lacking, with often only surface accretion rate (SAR) data available. We systematically review published studies of SEC and SAR from globally distributed monitoring sites using meta-analysis, and compare them with the Intergovernmental Panel on Climate Change Fifth Assessment Report (IPCC AR5) SLR scenarios. Hydro-geomorphic setting plays an important role, with basin mangroves potentially less vulnerable to SLR through land building processes. We find that SAR in both basin and fringe mangroves can cope with low SLR scenario (RCP 2.6) throughout the 100 years projection period. However, SAR can only keep pace with high SLR scenario (RCP 8.5) up to year 2070 and 2055 in basin and fringe mangrove settings respectively. These were associated with potential sediment accumulation of 41 cm and 29 cm respectively from the baseline. Mangrove degradation promoted lowering trends of SEC, while mangrove management such as rehabilitation practice stimulated positive trends of SEC. Mangrove ecosystems may be vulnerable to contemporary SLR in small island locations such as the Caribbean, East Africa and parts of the Indo-Pacific that are dominated by fringe mangroves and where SEC cannot keep pace with both low and high IPCC AR5 SLR scenarios. A global expansion of current mangrove surface elevation monitoring effort is urgently needed in order to better assess the vulnerability of mangroves, and the factors affecting their resiliency in the face of rising sea levels.

    Ecological restorationClimate change adaptationEcosystem healthCoastline
  • Ecosystem-Based Approaches Toward a Resilient Society in Harmony with Nature

    Takeuchi, K. et al. Ecosystem-Based Disaster Risk Reduction and Adaptation in Practice (2016). Book (chapter).
    https://link.springer.com/chapter/10.1007/978-3-319-43633-3_14

    Abstract

    Ecosystem-based approaches have proven effective and efficient in reducing disaster risks while ensuring continued benefits to people from ecosystem services. In this article, a new concept of Ecosystem-based Disaster Risk Reduction (Eco-DRR) for enhancing social-ecological resilience is proposed, based on analysis of several case studies. Field studies in developing countries such as Ghana and Myanmar have shown the benefits of Eco-DRR as implemented by local communities. These projects improve local livelihoods and social-ecological resilience. In Japan, after the massive damage from the 11 March 2011, Great East Japan earthquake and tsunami, ecosystem-based approaches were an important element of the national government’s DRR efforts. Analysis of these cases shows that Eco-DRR is a socially, economically and environmentally sustainable tool for DRR that creates new value for a region. It also shows the importance of multi-stakeholder participation in the process of promoting Eco-DRR. It is likely to become even more important in the future, as a means for addressing the increase in disasters resulting from climate and ecosystem change as well as demographic change. The contribution of Eco-DRR to maintaining and restoring ecosystems is particularly valuable for countries where there is reduced capacity for land management, as currently occurring in Japan due to rapid population decline and aging.

    Ecosystem-based disaster risk reductionEcosystem-based adaptationNature-based agricultural systemsDisaster risk reductionArtificial Landscapes - TerrestrialCoastline
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