ARCOM

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Acre, F and Wyckmans, A (2015) The impact of dwelling renovation on spatial quality: The case of the Arlequin neighbourhood in Grenoble, France. Smart and Sustainable Built Environment, 4(03), 268-309.

Adan, H and Fuerst, F (2015) Modelling energy retrofit investments in the UK housing market: A microeconomic approach. Smart and Sustainable Built Environment, 4(03), 251-67.

Adekunle, T O (2019) Summer performance, comfort, and heat stress in structural timber buildings under moderate weather conditions. Smart and Sustainable Built Environment, 8(03), 220–42.

Attallah, S O, Senouci, A, Kandil, A and Al-Derham, H (2013) Utilization of life-cycle analysis to evaluate sustainability rating systems for construction projects with a case study on Qatar Sustainability Assessment System (QSAS). Smart and Sustainable Built Environment, 2(03), 272-87.

Attia, M K M (2013) LEED as a tool for enhancing affordable housing sustainability in Saudi Arabia: The case of Al-Ghala project. Smart and Sustainable Built Environment, 2(03), 224-50.

Azeem, S, Naeem, M A, Waheed, A and Thaheem, M J (2017) Examining barriers and measures to promote the adoption of green building practices in Pakistan. Smart and Sustainable Built Environment, 6(03), 86-100.

Barthel, P-A (2016) Morocco in the era of eco-urbanism: Building a critical and operational research on an emerging practice in Africa. Smart and Sustainable Built Environment, 5(03), 272-88.

Birkeland, J L (2015) Prospects for nature in proposals for urban growth. Smart and Sustainable Built Environment, 4(03), 310-4.

Clevenger, C M and Haymaker, J R (2012) The value of design strategies applied to energy efficiency. Smart and Sustainable Built Environment, 1(03), 222-40.

Davis, M M, Vallejo Espinosa, A L and Ramirez, F R (2019) Beyond green façades: active air-cooling vertical gardens. Smart and Sustainable Built Environment, 8(03), 243–52.

Dizdaroglu, D, Yigitcanlar, T and Dawes, L (2012) A micro-level indexing model for assessing urban ecosystem sustainability. Smart and Sustainable Built Environment, 1(03), 291-315.

Dobbelsteen, A v d, Broersma, S, Fremouw, M, Blom, T, Sturkenboom, J and Martin, C (2019) The Amsterdam energy transition roadmap – introducing the City-zen methodology. Smart and Sustainable Built Environment, 9(03), 307–20.

Driza, P-J N and Park, N-K (2014) Occupant satisfaction in LEED-certified higher education buildings. Smart and Sustainable Built Environment, 3(03), 223-36.

Ene, G U, Goulding, J S and John, G A (2016) Sustainable human capacity development in the African built environment: How far is the journey to a knowledge society?. Smart and Sustainable Built Environment, 5(03), 212-31.

GhaffarianHoseini, A, Tookey, J, GhaffarianHoseini, A, Naismith, N and Rotimi, J O B (2016) Integrating alternative technologies to improve built environment sustainability in Africa: Nexus of energy and water. Smart and Sustainable Built Environment, 5(03), 193-211.

Gijsbers, R and Lichtenberg, J (2014) Demand driven selection of adaptable building technologies for flexibility-in-use. Smart and Sustainable Built Environment, 3(03), 237-60.

Gohardani, N and Björk, F (2012) Sustainable refurbishment in building technology. Smart and Sustainable Built Environment, 1(03), 241-52.

Han, Q and Keeffe, G (2019) Stepping stones. Smart and Sustainable Built Environment, 9(03), 246–57.

• Type: Journal Article
• Keywords: Climate change; Urban landscape; Tree migration; Range shift; Graph theory;
• ISBN/ISSN: 2046-6099
• URL: https://doi.org/10.1108/SASBE-12-2018-0065
• Abstract:
  Large-scale urbanisation has become a significant barrier to the natural migration of tree species, which is being exacerbated by accelerated climate change. Within this context, improving the permeability of urban landscapes is expected to be an effective strategy to facilitate the process of forest migration through cities. The purpose of this paper is to develop a method to assess the permeability of urban green spaces as stepping stones for forest migration, from the perspective of seed dispersal. The proposed method combines a least-cost path (LCP) model and a graph theory-based approach. The LCP model is applied to map the potential pathways of seed dispersal at multiple spatial and temporal scales, based on which graph theory-based indices are used to quantify the accessibility of urban landscapes for seed dispersers. This method is demonstrated by a case study in the Greater Manchester area, UK. Eurasian jay, Eurasian siskin, coal tit and grey squirrel are selected as the main seed dispersers in the study area. The results provide a comparison of the landscape permeability maps generated from different seed dispersers and identify key areas likely to facilitate the process of forest migration. Recommendations regarding landscape management for improving permeability are also discussed. This method allows designers to re-visualise highly modified and fragmented urban landscapes as stepping stones for seed dispersal, which in turn allows for a more piecemeal form of landscape design to optimise urban landscapes for climate adaptation.

Kamel, M A E (2013) Encouraging walkability in GCC cities: smart urban solutions. Smart and Sustainable Built Environment, 2(03), 288-310.

Komolafe, M O, Oyewole, M O and Kolawole, J T (2016) Extent of incorporation of green features in office properties in Lagos, Nigeria. Smart and Sustainable Built Environment, 5(03), 232-60.

Liaros, S (2019) Implementing a new human settlement theory. Smart and Sustainable Built Environment, 9(03), 258–71.

McGill, G, Oyedele, L O and McAllister, K (2015) An investigation of indoor air quality, thermal comfort and sick building syndrome symptoms in UK energy efficient homes. Smart and Sustainable Built Environment, 4(03), 329-48.

Nadim, W (2016) Live-work and adaptable housing in Egypt: A zero commuting concept, lessons learnt from informal developments. Smart and Sustainable Built Environment, 5(03), 289-302.

Nguyen, N T H and Dang, H T (2019) Adaptation of “participatory method” in design “for/with/by” the poor community in Tam Thanh, Quang Nam, Vietnam. Smart and Sustainable Built Environment, 9(03), 272–82.

Nikou, T and Klotz, L (2014) Application of multi-attribute utility theory for sustainable energy decisions in commercial buildings: A case study. Smart and Sustainable Built Environment, 3(03), 207-22.

Oyewole, M O, Ojutalayo, A A and Araloyin, F M (2019) Developers’ willingness to invest in green features in Abuja, Nigeria. Smart and Sustainable Built Environment, 8(03), 206–19.

Rahmouni, S and Smail, R (2019) A design approach towards sustainable buildings in Algeria. Smart and Sustainable Built Environment, 9(03), 229–45.

Rasdorf, W, Lewis, P, Arocho, I and Hummer, J (2015) Characterizing air pollutant emissions for highway construction projects. Smart and Sustainable Built Environment, 4(03), 315-28.

Rodriguez, B X, Simonen, K, Huang, M and De Wolf, C (2019) A taxonomy for Whole Building Life Cycle Assessment (WBLCA). Smart and Sustainable Built Environment, 8(03), 190–205.

Roggema, R (2019) Towards sustainable cities: about redundancy, voids and the potentials of the land. Smart and Sustainable Built Environment, 9(03), 283–306.

Rwelamila, P M D and Purushottam, N (2016) Strategic project management as an innovative approach for sustainable green campus buildings in Africa: The need for a paradigm shift. Smart and Sustainable Built Environment, 5(03), 261-71.

Sidawi, B and Deakin, M (2013) Diabetes, built environments and (un)healthy lifestyles: The potential of smart city technologies. Smart and Sustainable Built Environment, 2(03), 311-23.

Smits, M W M (2019) Toward self-reliant development. Smart and Sustainable Built Environment, 9(03), 321–39.

Subasinghe, C (2019) Forsake me not: balcony spaces in codes and cues among on-campus apartment dwellers. Smart and Sustainable Built Environment, 8(03), 253–66.

Surf, M S A, Trigunarsyah, B and Susilawati, C (2013) Saudi Arabia's sustainable housing limitations: the experts’ views. Smart and Sustainable Built Environment, 2(03), 251-71.

Wågø, S and Berker, T (2014) Architecture as a strategy for reduced energy consumption? An in-depth analysis of residential practices’ influence on the energy performance of passive houses. Smart and Sustainable Built Environment, 3(03), 192-206.

Wong, I L, Eames, P and Perera, S (2012) Energy simulations of a transparent-insulated office façade retrofit in London, UK. Smart and Sustainable Built Environment, 1(03), 253-76.

Yau, Y (2012) Eco-labels and willingness-to-pay: a Hong Kong study. Smart and Sustainable Built Environment, 1(03), 277-90.

Zhai, X, Reed, R and Mills, A (2014) Addressing sustainable challenges in China: The contribution of off-site industrialisation. Smart and Sustainable Built Environment, 3(03), 261-74.