122 research outputs found
Ko-Automobilität. Heutige Nutzungsformen und Nutzungsmuster in Deutschland und Verbreitungspotenziale als alternatives Mobilitätsangebot
Das Projekt "Autoteilen" beschäftigt sich mit den Möglichkeiten der gemeinschaftlichen/geteilten Nutzung des Pkws. Einhergehend mit der fortschreitenden Digitalisierung und Informations- und Kommunikationstechnologien (KIT) entwickelt sich eine Vielfalt neuer Nutzungsformen im Bereich Peer-2-Peer-Sharing. Im Rahmen des Projekts werden die verschiedenen Formen des Pkw-P2P-Sharings untersucht, die Nutzer sowie ihre Motive und Anforderungen bzw. Nutzungsbarrieren betrachtet und eine Aussage zum künftigen Verbreitungspotenzial getroffen
Lebensmittel vom Dach
Der Wettbewerb um Ressourcen und frucht baren Boden sowie steigende Energiepreise verteuern zunehmend die Nahrungsmittelproduktion. Daher gewinnt die gebäudegebundene Landwirtschaft, kurz „ZFarming“, seit etwa zehn Jahren an Bedeutung. Dieser weltweite Trend setzt der aktuellen Lebensmittelproduktion vielversprechende Ansätze entgegen
Farming in and on urban buildings: present practice and specific novelties of Zero-Acreage Farming (ZFarming)
Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG geförderten) Allianz- bzw. Nationallizenz frei zugänglich.This publication is with permission of the rights owner freely accessible due to an Alliance licence and a national licence (funded by the DFG, German Research Foundation) respectively.Considering global trends such as climate change and resource scarcity, a major challenge of future cities will be to reduce urban footprints. Moreover, cities have to become or remain livable for their inhabitants and offer social and economic opportunities. Thus, reconnecting food production and cities offers promising potential. The diffusion of urban farming reflects a rising awareness of how food and farming can shape our cities. A growing number of urban farming projects exist in and on urban buildings, including open rooftop farms, rooftop greenhouses and indoor farming. These projects are characterized by the non-use of land or acreage for farming activities. We use the term ‘Zero-Acreage Farming’ (ZFarming) to represent these farms. The objective of this paper is to: (1) illustrate and systemize present practices of ZFarming and (2) discuss specific novelties of ZFarming in the wider context of urban agriculture. We analyzed 73 ZFarms in cities of North America, Asia, Australia and Europe using a set of criteria, and developed a typology of ZFarming, complemented by in-depth interviews with pioneers in rooftop farming in New York. The results illustrate that ZFarming generates innovative practices that may contribute to a sustainable urban agriculture. Besides growing food, it produces a range of non-food and non-market goods. It involves new opportunities for resource efficiency, new farming technologies, specific implementation processes and networks, new patterns of food supply and new urban spaces
An Aggregated Stakeholder Perspective on Potential Benefits and Challenges
How can buildings be combined with agricultural production and what are the
major potential benefits and challenges for the introduction of zero-acreage
farming (ZFarming) in Berlin from the relevant stakeholders’ perspectives?
These questions were explored through a series of interviews and stakeholder
workshops held between 2011 and 2013. The aim was to identify the most
suitable building-integrated farming model for the Berlin metropolitan area
and to develop guidelines for the model’s successful and sustainable
implementation through a stakeholder-driven approach. This paper provides an
aggregated synthesis of the outcomes derived from the qualitative interviews
and stakeholder workshops. As the results reveal, the stakeholders perceive
potential benefits and challenges related to the issue of ZFarming in all
dimensions (economic, social, environmental and political). They largely
agreed on the importance of focusing on local resources, using energy-
efficient production—including social and educational aspects—and developing
new market structures when introducing ZFarming to the city of Berlin. The
stakeholders identified urban rooftop greenhouses (RTG) as the most promising
farming model for Berlin. In a joint collaboration of all stakeholders, a
manual for RTG was developed within the participatory innovation process that
addresses the identified problems and challenges associated with future
implementation and governance of RTG in Berlin and beyond
Von der ko-kreativen Stadtentwicklung bis zum Transfer
Welche Bedarfe, Ideen und Lösungen sehen hochqualifizierte Migrant/innen für eine nachhaltigeStadtentwicklung? Inwiefern eignet sich Urban Design Thinking als ko-kreative Methode und Impuls für städtische Transformationsprozesse? In einem Fallbeispiel in Mannheim wurden ersteAnsätze erprobt
Farming in and on urban buildings: Present practice and specific novelties of Zero-Acreage Farming (ZFarming)
Techniques and crops for efficient rooftop gardens in Bologna, Italy
Urban rooftop farming favours local food production. Although rooftop farming is perceived as 33 a sustainable system, there is a lack of quantitative studies on rooftop farming. There we set up 34 experiments in the community rooftop garden of a public housing building in Bologna, Italy, 35 between 2012 and 2014. We grew lettuce, a leafy vegetable, using three techniques: nutrient 36 film, floating hydroponic and soil cultivation. We also grew tomato, chilli pepper, eggplant, 37 melon, watermelon on soils. Data was analysed by life cycle assessment for environmental and 38 economic performance. Results reveal that the best techniques of lettuce cultivation to address 39 global warming were floating in the summer, with 65-85% less environmental impact per kg 40 than nutrient film; and soil production in the winter, with 85-95% less environmental impact. 41 Furthermore, floating production was 25% cheaper in summer and soil was 65% cheaper in 42 winter, compared to the nutrient film technique. For soil production, eggplants and tomatoes 43 showed the best environmental performances of about 74 g CO2 per kg. Eggplant production in 44 soil gave in the cheapest crop of 0.13 € per kg
Aquaponics in the Built Environment
Aquaponics’ potential to transform urban food production has been documented in a rapid increase of academic research and public interest in the field. To translate this publicity into real-world impact, the creation of commercial farms and their relationship to the urban environment have to be further examined. This research has to bridge the gap between existing literature on growing system performance and urban metabolic flows by considering the built form of aquaponic farms. To assess the potential for urban integration of aquaponics, existing case studies are classified by the typology of their building enclosure, with the two main categories being greenhouses and indoor environments. This classification allows for some assumptions about the farms’ performance in their context, but a more in-depth life cycle assessment (LCA) is necessary to evaluate different configurations. The LCA approach is presented as a way to inventory design criteria and respective strategies which can influence the environmental impact of aquaponic systems in the context of urban built environments
Recommended from our members
Chapter six - transformation of agricultural landscapes in the Anthropocene: nature's contributions to people, agriculture and food security
Multiple anthropogenic challenges threaten nature's contributions to human well-being. Agricultural expansion and conventional intensification are degrading biodiversity and ecosystem functions, thereby undermining the natural foundations on which agriculture is itself built. Averting the worst effects of global environmental change and assuring ecosystem benefits, requires a transformation of agriculture. Alternative agricultural systems to conventional intensification exist, ranging from adjustments to efficiency (e.g. sustainable intensification) to a redesign (e.g. ecological intensification, climate-smart agriculture) of the farm management system. These alternatives vary in their reliance on nature or technology, the level of systemic change required to operate, and impacts on biodiversity, landscapes and agricultural production. Different socio-economic, ecological and political settings mean there is no universal solution, instead there are a suite of interoperable practices that can be adapted to different contexts to maximise efficiency, sustainability and resilience. Social, economic, technological and demographic issues will influence the form of sustainable agriculture and effects on landscapes and biodiversity. These include: (1) the socio-technical-ecological architecture of agricultural and food systems and trends such as urbanisation in affecting the mode of production, diets, lifestyles and attitudes; (2) emerging technologies, such as gene editing, synthetic biology and 3D bioprinting of meat; and (3) the scale or state of the existing farm system, especially pertinent for smallholder agriculture. Agricultural transformation will require multifunctional landscape planning with cross-sectoral and participatory management to avoid unintended consequences and ultimately depends on people's capacity to accept new ways of operating in response to the current environmental crisis
- …