Abstracts – Browse Results
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Afroz, R (2020) Developing a low-carbon architecture pedagogy in Bangladesh. Buildings and Cities, 1(01), 637–49.
Andersen, C E, Kanafani, K, Zimmermann, R K, Rasmussen, F N and Birgisdóttir, H (2020) Comparison of GHG emissions from circular and conventional building components. Buildings and Cities, 1(01), 379–92.
Anderson, J and Moncaster, A (2020) Embodied carbon of concrete in buildings, Part 1: analysis of published EPD. Buildings and Cities, 1(01), 198–217.
Axon, S and Morrissey, J (2020) Just energy transitions? Social inequities, vulnerabilities and unintended consequences. Buildings and Cities, 1(01), 393–411.
Baborska-Narozny, M, Szulgowska-Zgrzywa, M, Mokrzecka, M, Chmielewska, A, Fidorow-Kaprawy, N, Stefanowicz, E, Piechurski, K and Laska, M (2020) Climate justice: air quality and transitions from solid fuel heating. Buildings and Cities, 1(01), 120–40.
Balouktsi, M (2020) Carbon metrics for cities: production and consumption implications for policies. Buildings and Cities, 1(01), 233–59.
Bordass, B (2020) Metrics for energy performance in operation: the fallacy of single indicators. Buildings and Cities, 1(01), 260–76.
Clarke, L, Sahin-Dikmen, M and Winch, C (2020) Transforming vocational education and training for nearly zero-energy building. Buildings and Cities, 1(01), 650–61.
Crawley, J, McKenna, E, Gori, V and Oreszczyn, T (2020) Creating Domestic Building Thermal Performance Ratings Using Smart Meter Data. Buildings and Cities, 1(01), 1–13.
Fawcett, T and Topouzi, M (2020) Residential retrofit in the climate emergency: the role of metrics. Buildings and Cities, 1(01), 475–90.
Francart, N, Höjer, M, Mjörnell, K, Orahim, A S, von Platten, J and Malmqvist, T (2020) Sharing indoor space: stakeholders’ perspectives and energy metrics. Buildings and Cities, 1(01), 70–85.
Frischknecht, R, Alig, M, Nathani, C, Hellmüller, P and Stolz, P (2020) Carbon footprints and reduction requirements: the Swiss real estate sector. Buildings and Cities, 1(01), 325–36.
Grant, E J (2020) Mainstreaming environmental education for architects: the need for basic literacies. Buildings and Cities, 1(01), 538–49.
Green, E, Lannon, S, Patterson, J, Variale, F and Iorwerth, H (2020) Decarbonising the Welsh housing stock: from practice to policy. Buildings and Cities, 1(01), 277–92.
Green, S D and Sergeeva, N (2020) The contested privileging of zero carbon: plausibility, persuasiveness and professionalism. Buildings and Cities, 1(01), 491–503.
Habert, G, Röck, M, Steininger, K, Lupísek, A, Birgisdottir, H, Desing, H, Chandrakumar, C, Pittau, F, Passer, A, Rovers, R, Slavkovic, K, Hollberg, A, Hoxha, E, Jusselme, T, Nault, E, Allacker, K and Lützkendorf, T (2020) Carbon budgets for buildings: harmonising temporal, spatial and sectoral dimensions. Buildings and Cities, 1(01), 429–52.
Hamstead, Z, Coseo, P, AlKhaled, S, Boamah, E F, Hondula, D M, Middel, A and Rajkovich, N (2020) Thermally resilient communities: creating a socio-technical collaborative response to extreme temperatures. Buildings and Cities, 1(01), 218–32.
Hoxha, E, Passer, A, Saade, M R M, Trigaux, D, Shuttleworth, A, Pittau, F, Allacker, K and Habert, G (2020) Biogenic carbon in buildings: a critical overview of LCA methods. Buildings and Cities, 1(01), 504–24.
Killip, G (2020) A reform agenda for UK construction education and practice. Buildings and Cities, 1(01), 525–37.
Klinsky, S and Mavrogianni, A (2020) Climate justice and the built environment. Buildings and Cities, 1(01), 412–28.
Kuittinen, M and Häkkinen, T (2020) Reduced carbon footprints of buildings: new Finnish standards and assessments. Buildings and Cities, 1(01), 182–97.
Lützkendorf, T (2020) The role of carbon metrics in supporting built-environment professionals. Buildings and Cities, 1(01), 676–86.
Lützkendorf, T and Frischknecht, R (2020) (Net-) zero-emission buildings: a typology of terms and definitions. Buildings and Cities, 1(01), 662–75.
Mayer, M (2020) Material recovery certification for construction workers. Buildings and Cities, 1(01), 550–64.
Parkin, A, Herrera, M and Coley, D A (2020) Net-zero buildings: when carbon and energy metrics diverge. Buildings and Cities, 1(01), 86–99.
Passe, U (2020) A design workflow for integrating performance into architectural education. Buildings and Cities, 1(01), 565–78.
Passe, U, Dorneich, M, Krejci, C, Koupaei, D M, Marmur, B, Shenk, L, Stonewall, J, Thompson, J and Zhou, Y (2020) An urban modelling framework for climate resilience in low-resource neighbourhoods. Buildings and Cities, 1(01), 453–74.
Patrick, M, Grewal, G, Chelagat, W and Shannon, G (2020) Planetary health justice: feminist approaches to building in rural Kenya. Buildings and Cities, 1(01), 308–24.
Roca-Puigròs, M, Billy, R G, Gerber, A, Wäger, P and Müller, D B (2020) Pathways toward a carbon-neutral Swiss residential building stock. Buildings and Cities, 1(01), 579–93.
Salter, J, Lu, Y, Kim, J C, Kellett, R, Girling, C, Inomata, F and Krahn, A (2020) Iterative ‘what-if’ neighborhood simulation: energy and emissions impacts. Buildings and Cities, 1(01), 293–307.
- Type: Journal Article
- Keywords: buildings; energy demand; energy model; energy policy; neighborhood; urban morphology; ‘what-if’ scenarios;
- ISBN/ISSN: 2632-6655
- URL: https://doi.org/10.5334/bc.51
- Abstract:
As efforts to address climate change shift to action at local scales, municipalities are called upon to develop locally specific action plans. Many municipalities lack the resources to develop energy and emissions-reducing policy interventions appropriate to their characteristics. This research synthesises urban form, scenario analysis and energy simulation into a cohesive workflow for evaluating energy and emissions policy interventions across a range of urban forms. A geospatial and census analysis of six cities across British Columbia, Canada, led to the development of seven urban neighborhood patterns. These represent neighborhood forms and densities found in cities of various sizes, densities, forms and climates. To test the approach of an urban built environment model (UBEM), retrofit and infill redevelopment ‘what-if’ scenarios were applied iteratively to two sample patterns comparing the relative efficacy of building technology-improvement policies versus land-use intensification policies. The future ‘what-if’ policy scenarios were spatially tested and validated using relevant policy. The simplified UBEM methods applied to typical patterns and development demonstrates a step towards an accessible and flexible modeling approach. Small and medium-sized municipalities can use this approach to assess and compare potential energy and emissions policy options and outcomes at building and neighborhood scales.Practice relevance A new, simple method has been created for municipalities to understand multiple ‘what-if’ scenarios for reducing energy demand and emissions from buildings. This is based on profiles from census data, geospatial analysis and energy data that characterise urban neighborhood patterns. The approach integrates building-scale and neighborhood-scale energy and greenhouse gas simulations. It can simulate a variety of policy scenarios and strategy interventions in order to show the interactions between and among urban form and retrofit options. This enables planners and decision-makers to compare the relative magnitudes of different interventions at the neighborhood or city level for energy and emissions performance. The model was developed for use by a variety of communities in British Columbia, Canada. There is potential for adapting this method for use in other locations.
Schünemann, C, Olfert, A, Schiela, D, Gruhler, K and Ortlepp, R (2020) Mitigation and adaptation in multifamily housing: overheating and climate justice. Buildings and Cities, 1(01), 36–55.
Schiller, G, Gruhler, K and Xie, X (2020) Assessing the efficiency of indoor and outdoor access-related infrastructure. Buildings and Cities, 1(01), 56–69.
Schmidt, M, Crawford, R H and Warren-Myers, G (2020) Integrating life-cycle GHG emissions into a building’s economic evaluation. Buildings and Cities, 1(01), 361–78.
Schoenefeldt, H (2020) Delivery of occupant satisfaction in the House of Commons, 1950–2019. Buildings and Cities, 1(01), 141–63.
Simpson, K, Janda, K B and Owen, A (2020) Preparing ‘middle actors’ to deliver zero-carbon building transitions. Buildings and Cities, 1(01), 610–24.
Srivastava, M (2020) Cooperative learning in design studios: a pedagogy for net-positive performance. Buildings and Cities, 1(01), 594–609.
Steadman, P, Evans, S, Liddiard, R, Godoy-Shimizu, D, Ruyssevelt, P and Humphrey, D (2020) Building stock energy modelling in the UK: the 3DStock method and the London Building Stock Model. Buildings and Cities, 1(01), 100–19.
Steininger, K W, Meyer, L, Nabernegg, S and Kirchengast, G (2020) Sectoral carbon budgets as an evaluation framework for the built environment. Buildings and Cities, 1(01), 337–60.
Stevenson, F and Kwok, A (2020) Mainstreaming zero carbon: lessons for built-environment education and training. Buildings and Cities, 1(01), 687–96.
Tanguy, A, Breton, C, Blanchet, P and Amor, B (2020) Characterising the development trends driving sustainable neighborhoods. Buildings and Cities, 1(01), 164–81.
Waldman, B, Huang, M and Simonen, K (2020) Embodied carbon in construction materials: a framework for quantifying data quality in EPDs. Buildings and Cities, 1(01), 625–36.
Willand, N, Moore, T, Horne, R and Robertson, S (2020) Retrofit Poverty: Socioeconomic Spatial Disparities in Retrofit Subsidies Uptake. Buildings and Cities, 1(01), 14–35.