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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.

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.

• Type: Journal Article
• Keywords: adaptation; building stock; climate justice; housing; inhabitants; mitigation; overheating; resilience; retrofit;
• ISBN/ISSN: 2632-6655
• URL: https://doi.org/10.5334/bc.12
• Abstract:
  Can thermal retrofit measures also enhance summer heat resilience and climate justice? Two common building types of multifamily dwellings in Central Europe are investigated: the ‘Gründerzeithaus’ and post-war large-panel construction along with their different inhabitant demographics. Thermal simulations and demographic surveys were undertaken for dwellings in both building types to evaluate the effectiveness of retrofit measures in reducing winter heat demand and to understand the impacts on summer overheating. Results indicate that standard retrofitting measures can reduce the overheating risks. The high summer temperatures on the top floor can be significantly lowered to values comparable with the ground floor. The remaining overheating in highly exposed rooms is reduced by additional selective adaptation measures. Adaptation requires more than technical interventions. Demographic surveys conducted for both building types show that different social groups are affected. The economics of retrofit requires policy clarity to avoid placing additional burdens on economically disadvantaged people. Inhabitants’ active involvement in night-time ventilation are vital for avoiding overheating. Appropriate affordances and a clear guidance for manual window opening/closing can reduce overheating. However, inhabitants who are unable to act (e.g. the elderly, immobile or those with chronic diseases) will be increasingly vulnerable and disadvantaged by increased exposure to overheating. The existing approaches for reducing heating demand and their impacts on overheating are examined for two common building types in Central Europe: the Gründerzeithaus and post-war large-panel multifamily housing. The evidence of physical effects and social interdependencies provides a basis both for decision-makers to select suitable measures, and for inhabitants to apply appropriate behavioural practices. Thermal retrofitting strategies for reducing winter heating demand can lead to enhanced resilience to hot summer weather, but also entail inhabitants’ active involvement. Additional technical measures are needed to ensure reduced levels of overheating. Inhabitants’ practices have a significant influence on resilience and the reduction of overheating. Therefore, technical interventions must be accompanied by clear strategies to empower inhabitants to control internal temperatures using natural ventilation. Elderly or ill inhabitants may not be able to perform these practices and, therefore, remain vulnerable. Increased rents caused by retrofits may displace socially disadvantaged inhabitants.

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.