This page has only limited features, please log in for full access.
Outi Tahvonen. Vesi-maa-kasvi -systeemi skaalautuvassa vihreässä infrastruktuurissa. Alue ja Ympäristö 2020, 49, 123 -125.
AMA StyleOuti Tahvonen. Vesi-maa-kasvi -systeemi skaalautuvassa vihreässä infrastruktuurissa. Alue ja Ympäristö. 2020; 49 (1):123-125.
Chicago/Turabian StyleOuti Tahvonen. 2020. "Vesi-maa-kasvi -systeemi skaalautuvassa vihreässä infrastruktuurissa." Alue ja Ympäristö 49, no. 1: 123-125.
Multifunctionality is seen as one of the key benefits delivered by sustainable urban drainage systems (SUDS). It has been promoted by both scientific research and practical guidelines. However, interrelations between different benefits are vaguely defined, thus highlighting a lack of knowledge on ways they could be promoted in the actual design process. In this research, multifunctionality has been studied with the help of scenario analysis. Three stormwater scenarios involving different range of SUDS elements have been designed for the case area of Kirstinpuisto in the city of Turku, Finland. Thereafter, the alternative design scenarios have been assessed with four criteria related to multifunctionality (water quantity, water quality, amenity, and biodiversity). The results showed that multifunctionality could be analyzed in the design phase itself, and thus provided knowingly. However, assessing amenity and biodiversity values is more complex and in addition, we still lack proper methods. As the four criteria have mutual interconnections, multifunctionality should be considered during the landscape architectural design, or else we could likely lose some benefits related to multifunctionality. This reinforces emerging understanding that an interdisciplinary approach is needed to combine ecological comprehension together with the system thinking into SUDS design, locating them not as individual elements or as a part of the treatment train, but in connection with wider social ecological framework of urban landscape.
Elisa Lähde; Ambika Khadka; Outi Tahvonen; Teemu Kokkonen. Can We Really Have It All?—Designing Multifunctionality with Sustainable Urban Drainage System Elements. Sustainability 2019, 11, 1854 .
AMA StyleElisa Lähde, Ambika Khadka, Outi Tahvonen, Teemu Kokkonen. Can We Really Have It All?—Designing Multifunctionality with Sustainable Urban Drainage System Elements. Sustainability. 2019; 11 (7):1854.
Chicago/Turabian StyleElisa Lähde; Ambika Khadka; Outi Tahvonen; Teemu Kokkonen. 2019. "Can We Really Have It All?—Designing Multifunctionality with Sustainable Urban Drainage System Elements." Sustainability 11, no. 7: 1854.
The planning, implementation, and everyday use of the built environment interweave the green and grey components of urban fabric tightly together. Runoff from grey and impermeable surfaces causes stormwater that is managed in permeable surfaces that simultaneously act as habitats for vegetation. Green infrastructure (GI) is one of the concepts that is used to perceive, manage, and guide the components of urban green spaces. Furthermore, GI pays special attention to stormwater management and urban vegetation at several scales at the same time. This study concentrated on scalable GI in domestic private gardens. A set of garden designs in Vuores, Finland were analyzed and developed by Research by Design. The aim was to study how garden scale choices and designs can enhance GI at the block and neighbourhood scales to rethink design practices to better integrate water and vegetation throughout the scales. As a result, we propose a checklist for designers and urban planners that ensures vegetation-integrated stormwater management to enhance habitat diversity in block scale and possibility to use blocks of private plots for ecological networks. The prerequisite for garden designers is to be capable to balance between water, vegetation, and soil, and their processes and flows in detail the scale.
Outi Tahvonen. Scalable Green Infrastructure—The Case of Domestic Private Gardens in Vuores, Finland. Sustainability 2018, 10, 4571 .
AMA StyleOuti Tahvonen. Scalable Green Infrastructure—The Case of Domestic Private Gardens in Vuores, Finland. Sustainability. 2018; 10 (12):4571.
Chicago/Turabian StyleOuti Tahvonen. 2018. "Scalable Green Infrastructure—The Case of Domestic Private Gardens in Vuores, Finland." Sustainability 10, no. 12: 4571.
Outi Tahvonen; Miimu Airaksinen. Low-density housing in sustainable urban planning – Scaling down to private gardens by using the green infrastructure concept. Land Use Policy 2018, 75, 478 -485.
AMA StyleOuti Tahvonen, Miimu Airaksinen. Low-density housing in sustainable urban planning – Scaling down to private gardens by using the green infrastructure concept. Land Use Policy. 2018; 75 ():478-485.
Chicago/Turabian StyleOuti Tahvonen; Miimu Airaksinen. 2018. "Low-density housing in sustainable urban planning – Scaling down to private gardens by using the green infrastructure concept." Land Use Policy 75, no. : 478-485.
Bioretention is a method of storm water management that includes several processes following the natural hydrological cycle. Bioretention, or variations of it, include rain gardens and bioswales, infiltrates, filtrates, evapotranspirates, and help to store and manage storm water run-off. A bioretention cell retains water, removes pollutants, and provides water elements for urban green areas. Although bioretention is a promising method for multifunctional storm water management, its construction details should not be copied from other climatic areas. A direct application may dismiss local conditions, materials, and construction practices. This study aimed to adapt construction details for bioretention to Finnish local practices and conditions and to formulate bioretention constructions that balance water, soil, and vegetation. First, construction details were reviewed, then local adaptations were applied, and finally, the application and two variations of growing media in two construction depths were tested in a test field in Southern Finland. Sandy growing media allowed the efficient retention of water during the first year, but failed to provide vital growth. The use of topsoil and compost in the growing media improved growth, but held high electrical conductivity after infiltration. All the experimental cells in the test field showed activity during the melting periods, both during winter and spring. If bioretention plays a multifunctional role in urban design and engineered ecology, the design parameters should not only focus on storm water quantity, but also on quality management and vegetation growth.
Outi Tahvonen. Adapting Bioretention Construction Details to Local Practices in Finland. Sustainability 2018, 10, 276 .
AMA StyleOuti Tahvonen. Adapting Bioretention Construction Details to Local Practices in Finland. Sustainability. 2018; 10 (2):276.
Chicago/Turabian StyleOuti Tahvonen. 2018. "Adapting Bioretention Construction Details to Local Practices in Finland." Sustainability 10, no. 2: 276.