87 research outputs found

    “Rights for Life” scenario to reach biodiversity targets and social equity for indigenous peoples and local communities

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    Scenarios are a powerful way in which the scientific community can inform future policies for transformative change. Forthcoming scenario work holds promise for the Nature Futures Framework, which through the concept of relational values, seeks to recognize a multiplicity of value positions on human-environment relations, including those of Indigenous Peoples and Local Communities (IPLCs). The objective of this Perspective paper is to propose a novel scenario skeleton titled "Rights for Life", which holds promise to achieve ambitious biodi-versity targets in a socially-equitable ways by focusing on the Nature's and IPLCs' rights. We demonstrate, through the case of Arctic reindeer (Rangifer tarandus tarandus) herding, that the "Rights for Life" scenario seems to deliver better social equity outcomes than the recently proposed "Half Earth" and "Sharing the Planet" sce-narios that have been designed to achieve ambitious conservation and biodiversity targets. The "Rights for Life" scenario is particularly fit for sparsely-populated indigenous homelands and rural regions where local commu-nities depend on culturally important nature-based livelihoods for their well-being. We recommend that future scenarios targeting human-environment relations should not only consider non-western and relational value perspectives, but also recognize the importance of Nature's and IPLCs' rights for ensuring transformative change for equity and the environment. Clear recognition of such rights can function as a basis for new regulations, market-based governance instruments, policies, and participatory governance instruments ensuring that viola-tion of Nature's and IPLCs' rights by societal developments is recognized, avoided, minimized, or at least compensated for.Peer reviewe

    Coping with policy errors in an era of chronic socio-environmental crises

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    Since large-scale environmental disruptions have become chronic, policymakers need to consider the long-term consequences of urgent crisis decisions. We develop design principles for a decision platform addressing strategic environmental crisis management, by which we mean coordinated decisions during an environmental urgency that are sensitive to long-term path dependencies and policy errors. To enhance critical questioning of formal doctrines, the decision platform includes policymakers and sectoral experts as equal participants. The agenda for decisionmaking is structured around future scenarios to encourage the participants to imagine alternative ways of framing the decision problem. The agenda also discourages defensive heuristics with which decision-makers attempt to preserve their short-term reputation. The design principles for strategic environmental crisis management are based on urban experimentation. The barrier of implementation for similar experiments in other contexts is low because they assume no major overhaul in existing administrationPeer reviewe

    To continue to burn something? : Technological, economic and political path dependencies in district heating in Helsinki, Finland

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    The transition away from fossil fuel based infrastructure for heating and cooling has to happen on a scale and timetable with no historical precedent. As the systems are large and networked, path-dependencies constrain the transition that is further complicated by the diversity of stakeholders. Here we analyze the case of transitioning the district heating system in the city of Helsinki, Finland, within the target of a carbon neutral metropolitan area. Despite relatively advanced climate policies, path-dependencies on the political, technological-material and economical levels interact in creating a "wicked" problem with no obvious solution and potential for backsliding. It is in this context that a possibility of a green paradox arises: despite the explicit commitment of all stakeholders toward carbon dioxide emission reductions, the combination of the path-dependencies may result in a transition that increases emissions. Our results highlight policy implications of path-dependencies for researchers, government and business.Peer reviewe

    Climatic effects on niche evolution in a passerine bird clade depend on paleoclimate reconstruction method

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    Climatic niches describe the climatic conditions in which species can persist. Shifts in climatic niches have been observed to coincide with major climatic change, suggesting that species adapt to new conditions. We test the relationship between rates of climatic niche evolution and paleoclimatic conditions through time for 65 Old-World flycatcher species (Aves: Muscicapidae). We combine niche quantification for all species with dated phylogenies to infer past changes in the rates of niche evolution for temperature and precipitation niches. Paleoclimatic conditions were inferred independently using two datasets: a paleoelevation reconstruction and the mammal fossil record. We find changes in climatic niches through time, but no or weak support for a relationship between niche evolution rates and rates of paleoclimatic change for both temperature and precipitation niche and for both reconstruction methods. In contrast, the inferred relationship between climatic conditions and niche evolution rates depends on paleoclimatic reconstruction method: rates of temperature niche evolution are significantly negatively related to absolute temperatures inferred using the paleoelevation model but not those reconstructed from the fossil record. We suggest that paleoclimatic change might be a weak driver of climatic niche evolution in birds and highlight the need for greater integration of different paleoclimate reconstructions.Peer reviewe

    Evolution of Neogene Mammals in Eurasia: Environmental Forcing and Biotic Interactions

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    The relative weights of physical forcing and biotic interaction as drivers of evolutionary change have been debated in evolutionary theory. The recent finding that species, genera, clades, and chronofaunas all appear to exhibit a symmetrical pattern of waxing and waning lends support to the view that biotic interactions shape the history of life. Yet, there is similarly abundant evidence that these primary units of biological evolution arise and wane in coincidence with major climatic change. We review these patterns and the process-level explanations offered for them. We also propose a tentative synthesis, characterized by interdependence between physical forcing and biotic interactions. We suggest that species with evolutionary novelties arise predominantly in "species factories" that develop under harsh environmental conditions, under dominant physical forcing, whereas exceptionally mild environments give rise to "oases in the desert," characterized by strong competition and survival of relics

    The rise and fall of the Old World savannah fauna and the origins of the African savannah biome

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    Author correction: vol 2, pg, 402, 2018 DOI:10.1038/s41559-018-0468-8Despite much interest in the ecology and origins of the extensive grassland ecosystems of the modern world, the biogeographic relationships of savannah palaeobiomes of Africa, India and mainland Eurasia have remained unclear. Here we assemble the most recent data from the Neogene mammal fossil record in order to map the biogeographic development of Old World mammalian faunas in relation to palaeoenvironmental conditions. Using genus-level faunal similarity and mean ordinated hypsodonty in combination with palaeoclimate modelling, we show that savannah faunas developed as a spatially and temporally connected entity that we term the Old World savannah palaeobiome. The Old World savannah palaeobiome flourished under the influence of middle and late Miocene global cooling and aridification, which resulted in the spread of open habitats across vast continental areas. This extensive biome fragmented into Eurasian and African branches due to increased aridification in North Africa and Arabia during the late Miocene. Its Eurasian branches had mostly disappeared by the end of the Miocene, but the African branch survived and eventually contributed to the development of Plio-Pleistocene African savannah faunas, including their early hominins. The modern African savannah fauna is thus a continuation of the extensive Old World savannah palaeobiome.Peer reviewe

    Mammalian body size evolution was shaped by habitat transitions as an indirect effect of climate change

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    Aim: Body size evolution has long been hypothesized to have been driven by factors linked to climate change, but the specific mechanisms are difficult to disentangle due to the wide range of functional traits that covary with body size. In this study, we investigated the impact of regional habitat changes as a potential indirect effect of climate change on body size evolution. Location: Europe and North America. Time period: The Neogene (similar to 23-2 million years ago). Major taxa: Five orders of terrestrial mammals: Artiodactyla, Carnivora, Perissodactyla, Proboscidea and Primates. Methods: We compared the two continental faunas, which have exceptional fossil records of terrestrial mammals and underwent different processes of habitat transition during the Neogene. Using Bayesian multilevel regression models, we assessed the variation in the temporal dynamics of body size diversity among ecographic groups, defined by their continent of occurrence and dietary preference. Results: Model comparisons unanimously supported a combined effect of diet and continent on all metrics of body size frequency distributions, rejecting the shared energetic advantage of larger bodies in colder climates as a dominant mechanism of body size evolution. Rather, the diet-specific dynamics on each continent pinpointed an indirect effect of climate change - change in habitat availability, and thus the resource landscape as a key driver of mammalian evolution. Main conclusions: Our study highlights dietary preference as a mechanistic link between mammalian evolution and habitat transition mediating an indirect climate-change effect and demonstrates the complexity of climatic influence on biodiversity. Our findings suggest that the intensified habitat modification today likely poses a bigger threat than climate change in itself to living mammals, and perhaps all endotherms.Peer reviewe
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