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Abrahams, G (2017) Constructing definitions of sustainable development. Smart and Sustainable Built Environment, 6(01), 34-47.

Arslan, M, Cruz, C, Roxin, A and Ginhac, D (2018) Spatio-temporal analysis of trajectories for safer construction sites. Smart and Sustainable Built Environment, 7(01), 80–100.

Asif, M, Hassanain, M A, Nahiduzzaman, K M and Sawalha, H (2019) Techno-economic assessment of application of solar PV in building sector. Smart and Sustainable Built Environment, 8(01), 34–52.

Baker, D and Mahmood, M N (2012) Developing tools to support complex infrastructure decision-making. Smart and Sustainable Built Environment, 1(01), 59-72.

Baker, D and Mahmood, M N (2012) Developing tools to support complex infrastructure decision-making. Smart and Sustainable Built Environment, 1(01), 59-72.

Bebelaar, N, Braggaar, R C, Kleijwegt, C M, Meulmeester, R W E, Michailidou, G, Salheb, N, van der Spek, S, Vaissier, N and Verbree, E (2018) Monitoring urban environmental phenomena through a wireless distributed sensor network. Smart and Sustainable Built Environment, 7(01), 68–79.

Birkeland, J L (2016) Net positive biophilic urbanism. Smart and Sustainable Built Environment, 5(01), 9-14.

• Type: Journal Article
• Keywords: sustainability; eco-positive retrofitting; net positive design; biophilic urbanism; positive development; urban biodiversity
• ISBN/ISSN:
• URL: https://doi.org/10.1108/SASBE-10-2015-0034
• Abstract:
  Purpose – Positive development and biophilic urbanism appear to be grounded in a different human-nature relationship. Biophilic urbanism builds on the theory that humans have an innate need to feel connected with nature, and explores ways to amplify its psychological and physiological benefits. Positive development contends that development must proactively increase nature in absolute terms (beyond pre-industrial conditions). The purpose of this paper is to propose a radical reconstruction of development design and decision making. Are these positions compatible? Design/methodology/approach – A literature review revealed many similarities and differences between the two theories, and the views and visions among individual proponents of sustainability paradigms vary. Therefore, the comparison focussed on the respective role of nature, a foundational element in each theory. Findings – Biophilic urbanism stresses the individual’s experience of nature and its importance to human life quality. Positive development stresses the preservation of species and ecosystems through the re-design of institutional systems and physical structures that increase the ecological base and public estate. Both viewpoints are essential to the whole system transformation that sustainability requires. However, if urban development does not increase urban nature and wilderness well beyond past/ongoing depletion and damage, the natural life support system will collapse. Research limitations/implications – These paradigms are too complex to be represented in a brief commentary, so the discussion focusses on a crucial difference. Since many papers in this special issue discuss biophilic urbanism references, the emphasis here is on the lesser known theory. Originality/value – These paradigms evolved independently and, as far as is known, this is the first time their essential messages are compared.

Bonyad, R, Hamzenejad, M and Khanmohammadi, M (2018) Ranking the regenerative architecture indicators for assessment of research-educational building projects in Tehran, Iran. Smart and Sustainable Built Environment, 9(01), 27–37.

Brandon, P (2012) Sustainable development: ignorance is fatal - what don. Smart and Sustainable Built Environment, 1(01), 14-28.

Brandon, P (2012) Sustainable development: ignorance is fatal - what don't we know?. Smart and Sustainable Built Environment, 1(01), 14-28.

Brynskov, M, Heijnen, A, Balestrini, M and Raetzsch, C (2018) Experimentation at scale: challenges for making urban informatics work. Smart and Sustainable Built Environment, 7(01), 150–63.

Burton, C A, Ryan, C, Rismanchi, B and Candy, S (2019) Urban shared energy systems and behaviour change - simulating a common pooled resource problem. Smart and Sustainable Built Environment, 9(01), 17–26.

Contarini, A and Meijer, A (2015) LCA comparison of roofing materials for flat roofs. Smart and Sustainable Built Environment, 4(01), 97-109.

De Waegemaeker, J, Kerselaers, E, Van Acker, M and Rogge, E (2017) Design workshops in the age of climate change: Analysis of a design workshop on drought in Flanders. Smart and Sustainable Built Environment, 6(01), 48-63.

Dritsa, D and Biloria, N (2018) Towards a multi-scalar framework for smart healthcare. Smart and Sustainable Built Environment, 7(01), 33–52.

Foth, M (2018) Participatory urban informatics: towards citizen-ability. Smart and Sustainable Built Environment, 7(01), 4–19.

Gholami, M, Mofidi Shemirani, M and Fayaz, R (2018) A modelling methodology for a solar energy-efficient neighbourhood. Smart and Sustainable Built Environment, 7(01), 117–32.

Glass, J (2012) The state of sustainability reporting in the construction sector. Smart and Sustainable Built Environment, 1(01), 87-104.

Glass, J (2012) The state of sustainability reporting in the construction sector. Smart and Sustainable Built Environment, 1(01), 87-104.

Goel, A (2019) Sustainability in construction and built environment: a “wicked problem”?. Smart and Sustainable Built Environment, 8(01), 2–15.

Guven, H and Tanik, A (2018) Water-energy nexus. Smart and Sustainable Built Environment, 9(01), 54–70.

Haeusler, M H, Hespanhol, L and Hoggenmueller, M (2018) ParticipationPlus. Smart and Sustainable Built Environment, 7(01), 133–49.

Hajji, A M and Lewis, P (2013) Development of productivity-based estimating tool for energy and air emissions from earthwork construction activities. Smart and Sustainable Built Environment, 2(01), 84-100.

Hussein, D, Sarkar, S and Armstrong, P (2018) Mapping preferences for the number of built elements. Smart and Sustainable Built Environment, 7(01), 53–67.

Hwang, Y H, Feng, Y and Tan, P Y (2016) Managing deforestation in a tropical compact city (Part B): Urban ecological approaches to landscape design. Smart and Sustainable Built Environment, 5(01), 73-92.

Ismail, Z-A (2017) Maintenance management system (MMS) to support facilities management at Malaysian polytechnic. Smart and Sustainable Built Environment, 6(01), 19-33.

Kayan, B A (2015) Conservation plan and “green maintenance” from sustainable repair perspectives. Smart and Sustainable Built Environment, 4(01), 25-44.

Kellert, S (2016) Biophilic urbanism: the potential to transform. Smart and Sustainable Built Environment, 5(01), 8-18.

Kleerekoper, L, van den Dobbelsteen, A A J F, Hordijk, G J, van Dorst, M J and Martin, C L (2015) Climate adaptation strategies: achieving insight in microclimate effects of redevelopment options. Smart and Sustainable Built Environment, 4(01), 110-36.

Kokkarinen, N, Shaw, A, Cullen, J, Pedrola, M O, Mason, A and Al-Shamma’a, A (2014) Investigation of audible carbon monoxide alarm ownership: Case study. Smart and Sustainable Built Environment, 3(01), 72-86.

Littke, H (2016) Becoming biophilic: Challenges and opportunities for biophilic urbanism in urban planning policy. Smart and Sustainable Built Environment, 5(01), 15-24.

Littke, H (2016) Becoming biophilic: Challenges and opportunities for biophilic urbanism in urban planning policy. Smart and Sustainable Built Environment, 5(01), 15-24.

Lombardi, P and Ferretti, V (2015) New spatial decision support systems for sustainable urban and regional development. Smart and Sustainable Built Environment, 4(01), 45-66.

Meng, X (2014) The role of facilities managers in sustainable practice in the UK and Ireland. Smart and Sustainable Built Environment, 3(01), 23-34.

Miller, W and Buys, L (2013) Factors influencing sustainability outcomes of housing in subtropical Australia. Smart and Sustainable Built Environment, 2(01), 60-83.

Muehlbauer, M (2018) Towards typogenetic tools for generative urban aesthetics. Smart and Sustainable Built Environment, 7(01), 20–32.

Nourian, P, Rezvani, S, Valeckaite, K and Sariyildiz, S (2018) Modelling walking and cycling accessibility and mobility. Smart and Sustainable Built Environment, 7(01), 101–16.

Papageorgiou, G and Demetriou, G (2020) Investigating learning and diffusion strategies for sustainable mobility. Smart and Sustainable Built Environment, 9(01), 1–16.

Pisello, A L, Xu, X, Taylor, J E and Cotana, F (2012) Network of buildings. Smart and Sustainable Built Environment, 1(01), 73-86.

Pisello, A L, Xu, X, Taylor, J E and Cotana, F (2012) Network of buildings' impact on indoor thermal performance. Smart and Sustainable Built Environment, 1(01), 73-86.

Roggema, R, Kabat, P and Dobbelsteen, A v d (2012) Towards a spatial planning framework for climate adaptation. Smart and Sustainable Built Environment, 1(01), 29-58.

Roggema, R, Kabat, P and Dobbelsteen, A v d (2012) Towards a spatial planning framework for climate adaptation. Smart and Sustainable Built Environment, 1(01), 29-58.

Saade, M R M, Silva, M G d, Gomes, V, Franco, H G, Schwamback, D and Lavor, B (2014) Material eco-efficiency indicators for Brazilian buildings. Smart and Sustainable Built Environment, 3(01), 54-71.

Sarker, R I, Mailer, M and Sikder, S K (2019) Walking to a public transport station. Smart and Sustainable Built Environment, 9(01), 38–53.

Selberherr, J (2015) Sustainable life cycle offers through cooperation. Smart and Sustainable Built Environment, 4(01), 4-24.

Settembre Blundo, D, García-Muiña, F E, Pini, M, Volpi, L, Siligardi, C and Ferrari, A M (2019) Sustainability as source of competitive advantages in mature sectors. Smart and Sustainable Built Environment, 8(01), 53–79.

Shen, Q, Wang, H and Tang, B-s (2014) A decision-making framework for sustainable land use in Hong Kong's urban renewal projects. Smart and Sustainable Built Environment, 3(01), 35-53.

Siew, R Y J, Balatbat, M C A and Carmichael, D G (2013) The relationship between sustainability practices and financial performance of construction companies. Smart and Sustainable Built Environment, 2(01), 6-27.

Singhaputtangkul, N (2017) A decision support tool to mitigate decision-making problems faced by a building design team. Smart and Sustainable Built Environment, 6(01), 2-18.

Slagstad, H and Brattebø, H (2013) Use of LCA to evaluate solutions for water and waste infrastructure in the early planning phase of carbon-neutral urban settlements. Smart and Sustainable Built Environment, 2(01), 28-42.

Stremke, S and Schöbel, S (2019) Research through design for energy transition: two case studies in Germany and The Netherlands. Smart and Sustainable Built Environment, 8(01), 16–33.

Tan, P Y, Feng, Y and Hwang, Y H (2016) Deforestation in a tropical compact city (Part A): Understanding its socio-ecological impacts. Smart and Sustainable Built Environment, 5(01), 47-72.

Thomsen, J, Berker, T, Hauge, Å L, Denizou, K, Wågø, S and Jerkø, S (2013) The interaction between building and users in passive and zero-energy housing and offices: The role of interfaces, knowledge and user commitment. Smart and Sustainable Built Environment, 2(01), 43-59.

Windapo, A O and Goulding, J S (2015) Understanding the gap between green building practice and legislation requirements in South Africa. Smart and Sustainable Built Environment, 4(01), 67-96.

Yang, J (2012) Editorial: promoting integrated development for smart and sustainable built environment. Smart and Sustainable Built Environment, 1(01), 4-13.

Young, R F (2016) The biophilic city and the quest for paradise. Smart and Sustainable Built Environment, 5(01), 25-46.

Zainul Abidin, N and Amir Shariffuddin, N A (2019) Engaging consultants in green projects: exploring the practice in Malaysia. Smart and Sustainable Built Environment, 8(01), 80–94.