Your search keyword '"Pomponi, F."' showing total 33 results

1. Why method matters: Temporal, spatial and physical variations in LCA and their impact on choice of structural system

Author

Moncaster, A.M., Pomponi, F., Symons, K.E., and Guthrie, P.M.

Published

2018

2. Wood in buildings: the right answer to the wrong question

Author

Göswein, V, primary, Arehart, J, additional, Pittau, F, additional, Pomponi, F, additional, Lamb, S, additional, Zea Escamilla, E, additional, Freire, F, additional, Silvestre, J D, additional, and Habert, G, additional

Published

2022

3. P1144: RADIOIMMUNOTHERAPY (RIT) VERSUS AUTOLOGOUS HEMATOPOIETIC STEM-CELL TRANSPLANTATION (ASCT) IN RELAPSED/REFRACTORY (R/R) FOLLICULAR LYMPHOMA: A FONDAZIONE ITALIANA LINFOMI (FIL) PHASE III TRIAL.

Author

Ladetto, M., primary, Tavarozzi, R., additional, Evangelista, A., additional, Zanni, M., additional, Tucci, A., additional, Anastasia, A., additional, Botto, B., additional, Boccomini, C., additional, Bolis, S., additional, Volpetti, S., additional, Zilioli, V. R., additional, Puccini, B., additional, Arcari, A., additional, Pavone, V., additional, Gaidano, G., additional, Corradini, P., additional, Tani, M., additional, Ferrero, S., additional, Cavallo, F., additional, Milone, G., additional, Ghiggi, C., additional, Pinto, A., additional, Pastore, D., additional, Ferreri, A. J., additional, Latte, G., additional, Patti, C., additional, Re, F., additional, Arcaini, L., additional, Benedetti, F., additional, Usai, S. V., additional, Luminari, S., additional, Mannina, D., additional, Pulsoni, A., additional, Stelitano, C., additional, Pennese, E., additional, Pietrantuono, G., additional, Gherlinzoni, F., additional, Pomponi, F., additional, Olivieri, A., additional, Perrone, T., additional, Rota Scalabrini, D., additional, Califano, C., additional, Falini, B., additional, Ciccone, G., additional, and Vitolo, U., additional

Published

2022

4. Water, energy, and carbon dioxide footprints of the construction sector: A case study on developed and developing economies

Author

Pomponi, F, Stephan, A, Pomponi, F, and Stephan, A

Abstract

Buildings and construction are major driver of anthropogenic environmental effects. While energy use and CO2 emissions of buildings and construction have been quantified, their water footprint remains understudied from an economy-wide perspective. We use environmentally-extended multi-regional input-output analysis to quantify the water, energy and carbon (dioxide) footprints associated with the construction sector of India, Italy, South Africa, and the UK, disaggregating the supply chains driving these environmental effects by using structural path analysis. Comparisons are made in terms of contributions by country, by sector, by stage of the supply chain and in terms of actual supply chain pathways. Results show that Italy and the UK have more disaggregated and international supply chains compared to India and South Africa. Total (i.e. direct + indirect) water footprints of construction sectors vary from 11.8 to 14.8 L/USD for all countries, except India at 78.1 L/USD. There was no notable correlation between water and energy and carbon dioxide footprints in terms of sectoral contributions, even if the latter two are correlated. More developed economies exhibit a higher share of international WF than developing economies. The current focus on energy and carbon dioxide footprints might therefore miss out on significant water impacts caused by construction activities, globally.

Published

2021

5. Global socio-economic losses and environmental gains from the Coronavirus pandemic

Author

Lenzen, M, Li, M, Malik, A, Pomponi, F, Sun, Y, Wiedmann, T, Faturay, F, Fry, J, Gallego, B, Geschke, A, Lenzen, M, Li, M, Malik, A, Pomponi, F, Sun, Y, Wiedmann, T, Faturay, F, Fry, J, Gallego, B, and Geschke, A

Published

2020

6. The ‘building paradox’: research on building-related environmental effects requires global visibility and attention

Author

Pomponi, F, Crawford, R, Stephan, A, Hart, J, D'Amico, B, Pomponi, F, Crawford, R, Stephan, A, Hart, J, and D'Amico, B

Abstract

The construction and operation of buildings is a major contributor to global energy demand, greenhouse gases emissions, resource depletion, waste generation, and associated environmental effects, such as climate change, pollution and habitat destruction. Despite its wide relevance, research on building-related environmental effects often fails to achieve global visibility and attention, particularly in premiere interdisciplinary journals – thus representing a major gap in the research these journals offer. In this article we review and reflect on the factors that are likely causing this lack of visibility for such a prominent research topic and emphasise the need to reconcile the construction and operational phases into the physical unity of a building, to contribute to the global environmental discourse using a lifecycle-based approach. This article also aims to act as a call for action and to raise awareness of this important gap. The evidence contained in the article can support institutional policies to improve the status quo and provide a practical help to researchers in the field to bring their work to wide interdisciplinary audiences.

Published

2020

7. Implications of using systematic decomposition structures to organize building LCA information: A comparative analysis of national standards and guidelines - IEA EBC ANNEX 72

Author

Universidad de Sevilla. Departamento de Construcciones Arquitectónicas I (ETSA), Universidad de Sevilla. TEP986: Digital Architecture for Sustainability Lab (Datus-Lab), Universidad de Sevilla. TEP130: Arquitectura, Patrimonio y Sostenibilidad: Acústica, Iluminación, Óptica y Energía, Soust-Verdaguer, Bernardette, García Martínez, Antonio, Llatas, Carmen, Gómez de Cózar, Juan Carlos, Allacker, K., Trigaux, D., Alsema, E., Berg, B., Dowdell, D., Debacker, W., Frischknecht, R., Ramseier, L., Veselka, J., Volf, M., Hajek, P., Lupíšek, A., Malik, Z., Habert, G., Hollberg, A., Lasvaux, S., Peuportier, B., Pomponi, F., Wastiel, L., Gomes, V., Zara, O., Gomes, M., Gusson Baiocchi, A., Pulgrossi, L., Ouellet-Plamondon, Claudiane, Moncaster, A., Di Bari, R., Horn, R., Lenz, K., Balouktsi, M., Lützkendorf, T., Röck, M., Hoxha, E., Passer, A., Universidad de Sevilla. Departamento de Construcciones Arquitectónicas I (ETSA), Universidad de Sevilla. TEP986: Digital Architecture for Sustainability Lab (Datus-Lab), Universidad de Sevilla. TEP130: Arquitectura, Patrimonio y Sostenibilidad: Acústica, Iluminación, Óptica y Energía, Soust-Verdaguer, Bernardette, García Martínez, Antonio, Llatas, Carmen, Gómez de Cózar, Juan Carlos, Allacker, K., Trigaux, D., Alsema, E., Berg, B., Dowdell, D., Debacker, W., Frischknecht, R., Ramseier, L., Veselka, J., Volf, M., Hajek, P., Lupíšek, A., Malik, Z., Habert, G., Hollberg, A., Lasvaux, S., Peuportier, B., Pomponi, F., Wastiel, L., Gomes, V., Zara, O., Gomes, M., Gusson Baiocchi, A., Pulgrossi, L., Ouellet-Plamondon, Claudiane, Moncaster, A., Di Bari, R., Horn, R., Lenz, K., Balouktsi, M., Lützkendorf, T., Röck, M., Hoxha, E., and Passer, A.

Abstract

The application of the Life Cycle Assessment (LCA) technique to a building requires the collection and organization of a large amount of data over its life cycle. The systematic decomposition method can be used to classify building components, elements and materials, overcome specific difficulties that are encountered when attempting to complete the life cycle inventory and increase the reliability and transparency of results. In this paper, which was developed in the context of the research project IEA EBC Annex 72, we demonstrate the implications of taking such approach and describe the results of a comparison among different national standards/guidelines that are used to conduct LCA for building decomposition. Methods: We initially identified the main characteristics of the standards/guidelines used by Annex participant countries. The "be2226" reference office building was used as a reference to apply the different national standards/guidelines related to building decomposition. It served as a basis of comparison, allowing us to identify the implications of using different systems/standards in the LCA practice, in terms of how these differences affect the LCI structures, LCA databases and the methods used to communicate results. We also analyzed the implications of integrating these standards/guidelines into Building Information Modelling (BIM) to support LCA. Results: Twelve national classification systems/standards/guidelines for the building decomposition were compared. Differences were identified among the levels of decomposition and grouping principles, as well as the consequences of these differences that were related to the LCI organization. In addition, differences were observed among the LCA databases and the structures of the results. Conclusions: The findings of this study summarize and provide an overview of the most relevant aspects of using a standardized building decomposition structure to conduct LCA. Recommendations are formulated on the basis of

Published

2020

8. Comparison of the greenhouse gas emissions of a high-rise residential building assessed with different national LCA approaches - IEA EBC Annex 72

Author

Frischknecht, R., Ramseier, L., Yang, W., Birgisdottir, H., Chae, Ch.U., Lützkendorf, T., Passer, A., Balouktsi, M., Berg, B., Bragança, L., Butler, J., Cellura, M., Dixit, M., Dowdell, D., Francart, Nicolas, García Martínez, A., Gomes, V., Gomes da Silva, M., Guimaraes, G., Hoxha, E., Kjendseth Wiik, M., König, H., Llatas, C., Longo, S., Lupíšek, A., Martel, J., Mateus, R., Nygaard Rasmussen, F., Ouellet-Plamondon, C., Peuportier, B., Pomponi, F., Pulgrossi, L., Röck, M., Satola, D., Soust Verdaguer, B., Szalay, Z., Truong Nhu, A., Veselka, J., Volf, M., Zara, O., Frischknecht, R., Ramseier, L., Yang, W., Birgisdottir, H., Chae, Ch.U., Lützkendorf, T., Passer, A., Balouktsi, M., Berg, B., Bragança, L., Butler, J., Cellura, M., Dixit, M., Dowdell, D., Francart, Nicolas, García Martínez, A., Gomes, V., Gomes da Silva, M., Guimaraes, G., Hoxha, E., Kjendseth Wiik, M., König, H., Llatas, C., Longo, S., Lupíšek, A., Martel, J., Mateus, R., Nygaard Rasmussen, F., Ouellet-Plamondon, C., Peuportier, B., Pomponi, F., Pulgrossi, L., Röck, M., Satola, D., Soust Verdaguer, B., Szalay, Z., Truong Nhu, A., Veselka, J., Volf, M., and Zara, O.

Abstract

Introduction: The international research project IEA EBC Annex 72 investigates the life cycle related environmental impacts caused by buildings. The project aims inter alia to harmonise LCA approaches on buildings. Methods: To identify major commonalities and discrepancies among national LCA approaches, reference buildings were defined to present and compare the national approaches. A residential high-rise building located in Tianjin, China, was selected as one of the reference buildings. The main construction elements are reinforced concrete shear walls, beams and floor slabs. The building has an energy reference area of 4566 m2 and an operational heating energy demand of 250 MJ/m2a. An expert team provided information on the quantities of building materials and elements required for the construction, established a BIM model and quantified the operational energy demand. Results: The greenhouse gas emissions and environmental impacts of the building were quantified using 17 country-specific national assessment methods and LCA databases. Comparisons of the results are shown on the level of building elements as well as the complete life cycle of the building. Conclusions: The results of these assessments show that the main differences lie in the LCA background data used, the scope of the assessment and the reference study period applied. Despite the variability in the greenhouse gas emissions determined with the 17 national methods, the individual results are relevant in the respective national context of the method, data, tool and benchmark used. It is important that environmental benchmarks correspond to the particular LCA approach and database of a country in which the benchmark is applied. Furthermore, the results imply to include building technologies as their contribution to the overall environmental impacts is not negligible. Grant support: The authors thank the IEA for its organizational support and the funding organizations in the participating countries for, QC 20210407

Published

2020

9. Comparison of the greenhouse gas emissions of a high-rise residential building assessed with different national LCA approaches – IEA EBC Annex 72

Author

Universidad de Sevilla. Departamento de Construcciones Arquitectónicas I (ETSA), Universidad de Sevilla. TEP130: Arquitectura, Patrimonio y Sostenibilidad: Acústica, Iluminación, Óptica y Energía, Universidad de Sevilla. TEP986: Digital Architecture for Sustainability Lab (Datus-Lab), Frischknecht, R., Ramseier, L., Yang, W., Birgisdottir, H., Chae, Ch U., Lützkendorf, T., Passer, A., Balouktsi, M., Berg, B., Bragança, L., Butler, J., Cellura, M., Dixit, M., Dowdell, D., Francart, N., García Martínez, Antonio, Gomes, V., Gomes da Silva, M., Guimaraes, G., Hoxha, E., Kjendseth Wiik, M., König, H., Llatas, Carmen, Longo, S., Lupíšek, A., Martel, J., Mateus, R., Nygaard Rasmussen, F., Ouellet-Plamondon, Claudiane, Peuportier, B., Pomponi, F., Pulgrossi, L., Röck, M., Satola, D., Soust-Verdaguer, Bernardette, Szalay, Z., Truong Nhu, A., Veselka, J., Volf, M., Zara, O., Universidad de Sevilla. Departamento de Construcciones Arquitectónicas I (ETSA), Universidad de Sevilla. TEP130: Arquitectura, Patrimonio y Sostenibilidad: Acústica, Iluminación, Óptica y Energía, Universidad de Sevilla. TEP986: Digital Architecture for Sustainability Lab (Datus-Lab), Frischknecht, R., Ramseier, L., Yang, W., Birgisdottir, H., Chae, Ch U., Lützkendorf, T., Passer, A., Balouktsi, M., Berg, B., Bragança, L., Butler, J., Cellura, M., Dixit, M., Dowdell, D., Francart, N., García Martínez, Antonio, Gomes, V., Gomes da Silva, M., Guimaraes, G., Hoxha, E., Kjendseth Wiik, M., König, H., Llatas, Carmen, Longo, S., Lupíšek, A., Martel, J., Mateus, R., Nygaard Rasmussen, F., Ouellet-Plamondon, Claudiane, Peuportier, B., Pomponi, F., Pulgrossi, L., Röck, M., Satola, D., Soust-Verdaguer, Bernardette, Szalay, Z., Truong Nhu, A., Veselka, J., Volf, M., and Zara, O.

Abstract

Introduction: The international research project IEA EBC Annex 72 investigates the life cycle related environmental impacts caused by buildings. The project aims inter alia to harmonise LCA approaches on buildings. Methods: To identify major commonalities and discrepancies among national LCA approaches, reference buildings were defined to present and compare the national approaches. A residential high-rise building located in Tianjin, China, was selected as one of the reference buildings. The main construction elements are reinforced concrete shear walls, beams and floor slabs. The building has an energy reference area of 4566 m2 and an operational heating energy demand of 250 MJ/m2 a. An expert team provided information on the quantities of building materials and elements required for the construction, established a BIM model and quantified the operational energy demand. Results: The greenhouse gas emissions and environmental impacts of the building were quantified using 17 country-specific national assessment methods and LCA databases. Comparisons of the results are shown on the level of building elements as well as the complete life cycle of the building. Conclusions: The results of these assessments show that the main differences lie in the LCA background data used, the scope of the assessment and the reference study period applied. Despite the variability in the greenhouse gas emissions determined with the 17 national methods, the individual results are relevant in the respective national context of the method, data, tool and benchmark used. It is important that environmental benchmarks correspond to the particular LCA approach and database of a country in which the benchmark is applied. Furthermore, the results imply to include building technologies as their contribution to the overall environmental impacts is not negligible

Published

2020

10. Machine Learning for Sustainable Structures: A Call for Data

Author

D'Amico, B., Myers, R.J., Sykes, J., Voss, E., Cousins-Jenvey, B., Fawcett, W., Richardson, S., Kermani, A., and Pomponi, F.

Published

2019

11. Comparison of the greenhouse gas emissions of a high-rise residential building assessed with different national LCA approaches – IEA EBC Annex 72

Author

Frischknecht, R, primary, Ramseier, L, additional, Yang, W, additional, Birgisdottir, H, additional, Chae, Ch U, additional, Lützkendorf, T, additional, Passer, A, additional, Balouktsi, M, additional, Berg, B, additional, Bragança, L, additional, Butler, J, additional, Cellura, M, additional, Dixit, M, additional, Dowdell, D, additional, Francart, N, additional, García Martínez, A, additional, Gomes, V, additional, Gomes Da Silva, M, additional, Guimaraes, G, additional, Hoxha, E, additional, Wiik, M Kjendseth, additional, König, H, additional, Llatas, C, additional, Longo, S, additional, Lupíšek, A, additional, Martel, J, additional, Mateus, R, additional, Rasmussen, F Nygaard, additional, Ouellet-Plamondon, C, additional, Peuportier, B, additional, Pomponi, F, additional, Pulgrossi, L, additional, Röck, M, additional, Satola, D, additional, Verdaguer, B Soust, additional, Szalay, Z, additional, Nhu, A Truong, additional, Veselka, J, additional, Volf, M, additional, and Zara, O, additional

Published

2020

12. Implications of using systematic decomposition structures to organize building LCA information: A comparative analysis of national standards and guidelines- IEA EBC ANNEX 72

Author

Soust-Verdaguer, B, primary, García Martínez, A, additional, Llatas, C, additional, Gómez de Cózar, J.C., additional, Allacker, K, additional, Trigaux, D, additional, Alsema, E, additional, Berg, B, additional, Dowdell, D, additional, Debacker, W, additional, Frischknecht, R, additional, Ramseier, L, additional, Veselka, J, additional, Volf, M, additional, Hajek, P, additional, Lupíšek, A, additional, Malik, Z, additional, Habert, G, additional, Hollberg, A, additional, Lasvaux, S, additional, Peuportier, B, additional, Pomponi, F, additional, Wastiel, L, additional, Gomes, V, additional, Zara, O, additional, Gomes, M, additional, Gusson Baiocchi, A, additional, Pulgrossi, L, additional, Ouellet-Plamondon, C, additional, Moncaster, A, additional, Di Bari, R, additional, Horn, R, additional, Lenz, K, additional, Balouktsi, M, additional, Lützkendorf, T, additional, Röck, M, additional, Hoxha, E, additional, and Passer, A, additional

Published

2020

13. Comparison of the environmental assessment of an identical office building with national methods

Author

Frischknecht, R., Birgisdottir, H., Chae, C. -U, Lützkendorf, T., Passer, A., Alsema, E., Balouktsi, M., Berg, B., Dowdell, D., Garcia Martinez, A., Habert, G., Hollberg, A., König, H., Lasvaux, S., Llatas, C., Nygaard Rasmussen, F., Peuportier, B., Ramseier, L., Röck, M., Soust Verdaguer, B., Szalay, Z., Bohne, R. A., Braganca, L., Cellura, M., Chau, C. K., Dixit, M., Francart, Nicolas, Gomes, V., Huang, L., Longo, S., Lupišek, A., Martel, J., Mateus, R., Ouellet-Plamondon, C., Pomponi, F., Ryklová, P., Trigaux, D., Yang, W., Frischknecht, R., Birgisdottir, H., Chae, C. -U, Lützkendorf, T., Passer, A., Alsema, E., Balouktsi, M., Berg, B., Dowdell, D., Garcia Martinez, A., Habert, G., Hollberg, A., König, H., Lasvaux, S., Llatas, C., Nygaard Rasmussen, F., Peuportier, B., Ramseier, L., Röck, M., Soust Verdaguer, B., Szalay, Z., Bohne, R. A., Braganca, L., Cellura, M., Chau, C. K., Dixit, M., Francart, Nicolas, Gomes, V., Huang, L., Longo, S., Lupišek, A., Martel, J., Mateus, R., Ouellet-Plamondon, C., Pomponi, F., Ryklová, P., Trigaux, D., and Yang, W.

Abstract

The IEA EBC Annex 72 focuses on the assessment of the primary energy demand, greenhouse gas emissions and environmental impacts of buildings during production, construction, use (including repair and replacement) and end of life (dismantling), i.e. during the entire life cycle of buildings. In one of its activities, reference buildings (size, materialisation, operational energy demand, etc.) were defined on which the existing national assessment methods are applied using national (if available) databases and (national/regional) approaches. The "be2226" office building in Lustenau, Austria was selected as one of the reference buildings. TU Graz established a BIM model and quantified the amount of building elements as well as construction materials required and the operational energy demand. The building assessment was carried out using the same material and energy demand but applying the LCA approach used in the different countries represented by the participating Annex experts. The results of these assessments are compared in view of identifying major discrepancies. Preliminary findings show that the greenhouse gas emissions per kg of building material differ up to a factor of two and more. Major differences in the building assessments are observed in the transports to the construction site (imports) and the construction activities as well as in the greenhouse gas emissions of the operational energy demand (electricity). The experts document their practical difficulties and how they overcame them. The results of this activity are used to better target harmonisation efforts., QC 20200417

Published

2019

14. Comparison of the environmental assessment of an identical office building with national methods

Author

Frischknecht, Rolf, Universidad de Sevilla. Departamento de Construcciones Arquitectónicas I, Universidad de Sevilla. TEP986: Digital Architecture for Sustainability Lab (Datus-Lab), Agencia Internacional de la Energía, Birgisdottir, Harpa, Chae, C-U, Lützkendorf, Thomas, Passer, Alexander, Alsema, E., Balouktsi, Maria, Berg, B., Dowdell, David, García Martínez, Antonio, Habert, Guillaume, Hollberg, Alexander, König, H., Lasvaux, Sebastien, Llatas, Carmen, Nygaard Rasmussen, Freja, Peuportier, Bruno, Ramseier, Livia, Röck, Martin, Soust-Verdaguer, Bernardette, Szalay, Z., Bohne, R. A., Bragança, Leana Kathleen, Cellura, M., Chau, C. K., Dixit, Manish Kumar, Francart, Nicolas, Gomes, V., Huang, L., Longo, S., Lupíšek, A., Martel, J., Mateus, R., Ouellet-Plamondon, Claudiane, Pomponi, F., Ryklová, P., Trigaux, Damien, Yang, W., Frischknecht, Rolf, Universidad de Sevilla. Departamento de Construcciones Arquitectónicas I, Universidad de Sevilla. TEP986: Digital Architecture for Sustainability Lab (Datus-Lab), Agencia Internacional de la Energía, Birgisdottir, Harpa, Chae, C-U, Lützkendorf, Thomas, Passer, Alexander, Alsema, E., Balouktsi, Maria, Berg, B., Dowdell, David, García Martínez, Antonio, Habert, Guillaume, Hollberg, Alexander, König, H., Lasvaux, Sebastien, Llatas, Carmen, Nygaard Rasmussen, Freja, Peuportier, Bruno, Ramseier, Livia, Röck, Martin, Soust-Verdaguer, Bernardette, Szalay, Z., Bohne, R. A., Bragança, Leana Kathleen, Cellura, M., Chau, C. K., Dixit, Manish Kumar, Francart, Nicolas, Gomes, V., Huang, L., Longo, S., Lupíšek, A., Martel, J., Mateus, R., Ouellet-Plamondon, Claudiane, Pomponi, F., Ryklová, P., Trigaux, Damien, and Yang, W.

Abstract

The IEA EBC Annex 72 focuses on the assessment of the primary energy demand, greenhouse gas emissions and environmental impacts of buildings during production, construction, use (including repair and replacement) and end of life (dismantling), i.e. during the entire life cycle of buildings. In one of its activities, reference buildings (size, materialisation, operational energy demand, etc.) were defined on which the existing national assessment methods are applied using national (if available) databases and (national/regional) approaches. The "be2226" office building in Lustenau, Austria was selected as one of the reference buildings. TU Graz established a BIM model and quantified the amount of building elements as well as construction materials required and the operational energy demand. The building assessment was carried out using the same material and energy demand but applying the LCA approach used in the different countries represented by the participating Annex experts. The results of these assessments are compared in view of identifying major discrepancies. Preliminary findings show that the greenhouse gas emissions per kg of building material differ up to a factor of two and more. Major differences in the building assessments are observed in the transports to the construction site (imports) and the construction activities as well as in the greenhouse gas emissions of the operational energy demand (electricity). The experts document their practical difficulties and how they overcame them. The results of this activity are used to better target harmonisation efforts.

Published

2019

15. Comparison of the environmental assessment of an identical office building with national methods

Author

Frischknecht, R, primary, Birgisdottir, H, additional, Chae, C-U, additional, Lützkendorf, T, additional, Passer, A, additional, Alsema, E, additional, Balouktsi, M, additional, Berg, B, additional, Dowdell, D, additional, García Martínez, A, additional, Habert, G, additional, Hollberg, A, additional, König, H, additional, Lasvaux, S, additional, Llatas, C, additional, Nygaard Rasmussen, F, additional, Peuportier, B, additional, Ramseier, L, additional, Röck, M, additional, Soust Verdaguer, B, additional, Szalay, Z, additional, Bohne, R A, additional, Bragança, L, additional, Cellura, M, additional, Chau, C K, additional, Dixit, M, additional, Francart, N, additional, Gomes, V, additional, Huang, L, additional, Longo, S, additional, Lupíšek, A, additional, Martel, J, additional, Mateus, R, additional, Ouellet-Plamondon, C, additional, Pomponi, F, additional, Ryklová, P, additional, Trigaux, D, additional, and Yang, W, additional

Published

2019

16. Embodied carbon in buildings: An Australian perspective

Author

Pomponi, F, Crawford, RH, Stephan, A, Schmidt, M, Pomponi, F, Crawford, RH, Stephan, A, and Schmidt, M

Published

2018

17. Reducing Embodied Carbon in the Built Environment: A Research Agenda

Author

Pomponi, F and Moncaster, A

Abstract

In spite of significant global efforts, the International Energy Agency suggests that buildings-related emissions are on track to double by 2050. Whilst operational energy efficiency continues to receive significant attention by researchers, a less well-researched area is the assessment of embodied carbon in the built environment in order to understand where the greatest opportunities for its mitigation and reduction lie. This paper reports on available mitigation strategies to tackle embodied carbon identified through a systematic review of the available academic evidence. It also investigates the scope and scale of current academic investigations to highlight where significant gaps are for impactful further research on the topic. In total, 17 mitigation strategies have been identified from within the existing literature which have been discussed individually. Results reveal that a one-size-fits-all approach is unlikely to yield beneficial results and future research should be diverse in breadth and scope, locally accurate, and significantly interdisciplinary.

Published

2017

18. Transforming challenges into opportunities in social housing: a case study from Italy

Author

Pomponi, L., Sablone, E., Rusconi Clerici, L., Consalez, L., and Pomponi, F.

Published

2017

19. Benefits and challenges of visualising embodied and whole life carbon of buildings

Author

Pomponi, F. and Moncaster, A.

Abstract

Embodied and whole life carbon of buildings are increasingly gaining attention. However, embodied carbon calculation is still far from being common practice for sustainability assessment of buildings. Some of its greatest difficulties lie with the long life lifespan of buildings which implies a great unpredictability of future scenarios and high uncertainty of data. To help understand which life cycle stages should get the most attention when considering a building project, this paper proposes a new visualisation method based on Sankey diagrams for whole life carbon that allows one to cluster the carbon emitted in each of the life cycle stages as identified in current BS 15978 standards. With the proposed method, the carbon figures can be further broken down to account for building assemblies and components. Additionally, the method is equally suitable to account for physical quantities of what is embedded in buildings and their components. As such it can supplement some units of existing assessment methods (e.g. metal depletion measured in mass units of Feeq) and turn it into mass units of embodied steel. With such new metric, a life cycle assessment would include knowledge on flows as well as quantities. Such information could then be linked to the building permanently and smartly to be updated when necessary as the building evolves, changes, and gets upgraded, building on the theoretical foundations of the shearing layers of buildings. As such, this information could be embedded within BIM which is fully suitable to store parametric details for each building component.

Published

2016

20. Heat island effects in urban life cycle assessment: Novel insights to include the effects of the urban heat island and UHI‐mitigation measures in LCA for effective policy making

Author

Francesco Pomponi, Tiziana Susca, Susca, T., and Pomponi, F.

Subjects

624 Civil engineering, Energy, Urban settlement, Economic development, Policy making, Culture and Communities, General Social Sciences, TA Engineering (General). Civil engineering (General), Transport Research Institute, industrial ecology, Carbon Emissions, urban settlement, urban LCA, heat island, policy making, Environmental science, Urban life, Industrial ecology, Urban heat island, Environmental planning, heat island, industrial ecology, policy making, urban heat island mitigation, urban LCA, urban settlement, urban heat island mitigation, Smart cities, Ethics and sustainability, General Environmental Science

Abstract

Urbanization often entails a surge in urban temperature compared to the rural surroundings: the Urban Heat Island (UHI) effect. Such a temperature increase triggers the formation of pollutants worsening the urban air quality. Jointly, bad air quality and UHI affect ecosystems and human health. To alleviate the impacts on the population and the environment, it is crucial to design effective UHI‐mitigation measures. Life Cycle Assessment (LCA) is an assessment tool able to capture the complexity of urban settlements and quantify their impact. Yet, as currently implemented, LCA neglects the interactions between the built environment and the local climate, omitting the resulting impacts. This study reviews the existing literature, showing the lack of studies that organically include interactions between the built environment and local climate in LCA. This forms the basis to identify the unsuitability of the current LCA framework for comprehensively capturing the impact of urban settlements. To overcome this limitation, this research offers a pathway to expand the LCA methodology, indicating the necessity to (a) couple the LCA methodology with climate models or physical relations that quantify the interactions between the local climate and the built environment; (b) include novel impact categories in LCA to address such interactions; and (c) use existing or ad hoc developed characterization factors to assess the impacts related to the UHI effect. The LCA community can build on the frame of reference offered by this research to overcome the current limitations of LCA and enable its use for a comprehensive assessment of the impacts of UHI and its mitigation measures.

Published

2020

21. Qualifying the sustainability of novel designs and existing solutions for post-disaster and post-conflict sheltering

Author

Lara Alshawawreh, Bernardino D'Amico, Susan Snaddon, Peter Guthrie, Francesco Pomponi, Alshawawreh, L [0000-0002-3103-4428], Pomponi, F [0000-0003-3132-2523], D'Amico, B [0000-0003-1789-3688], Guthrie, P [0000-0002-9523-3733], and Apollo - University of Cambridge Repository

Subjects

post-conflict shelter, Refugee, Geography, Planning and Development, lcsh:TJ807-830, 0211 other engineering and technologies, lcsh:Renewable energy sources, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Post conflict, Natural disaster, Environmental planning, lcsh:Environmental sciences, 0105 earth and related environmental sciences, lcsh:GE1-350, post-disaster shelter, emergency sheltering, Renewable Energy, Sustainability and the Environment, Displaced person, lcsh:Environmental effects of industries and plants, sustainable sheltering, 021107 urban & regional planning, refugees, transitional shelter, lcsh:TD194-195, Work (electrical), city, Scale (social sciences), Sustainability, Business, Element (criminal law)

Abstract

During the course of 2018, 70.8 million people globally were forcibly displaced due to natural disasters and conflicts&mdash, a staggering increase of 2.9 million people compared to the previous year&rsquo, s figure. Displaced people cluster in refugee camps which have very often the scale of a medium-sized city. Post-disaster and post-conflict (PDPC) sheltering therefore represents a vitally important element for both the short- and long-term wellbeing of the displaced. However, the constrained environment which dominates PDPC sheltering often results in a lack of consideration of sustainability dimensions. Neglecting sustainability has severe practical consequences on both people and the environment, and in the long run it also incurs higher costs. It is therefore imperative to quickly transfer to PDPC sheltering where sustainability considerations are a key element of the design and decision-making processes. To facilitate such transition, this article reviews both &lsquo, existing solutions&rsquo, and &lsquo, novel designs&rsquo, for PDPC sheltering against the three pillars of sustainability. Both clusters are systematically categorized, and pros and cons of solutions and designs are identified. This provides an overview of the attempts made so far in different contexts, and it highlights what worked and what did not. This article represents a stepping-stone for future work in this area, to both facilitate and accelerate the transition to sustainable sheltering.

Published

2020

22. Comparison of the greenhouse gas emissions of a high-rise residential building assessed with different national LCA approaches– IEA EBC Annex 72

Author

Ricardo Mateus, N. Francart, M. Kjendseth Wiik, Rolf Frischknecht, A. Truong Nhu, O. Zara, M. Gomes Da Silva, B. Soust Verdaguer, W. Yang, Holger König, Brian Berg, Bruno Peuportier, Zsuzsa Szalay, L. Ramseier, Martin Volf, Endrit Hoxha, J. Butler, D. Dowdell, Maurizio Cellura, L. Pulgrossi, G. D. Guimarães, Francesco Pomponi, A. García Martínez, Claudiane Ouellet-Plamondon, J. Veselka, Antonín Lupíšek, Daniel Satola, Thomas Lützkendorf, Manish K. Dixit, Alexander Passer, Ch. U. Chae, Maria Balouktsi, Martin Röck, Sonia Longo, J. Martel, Harpa Birgisdottir, Carmen Llatas, Luís Bragança, Vanessa Gomes, F. Nygaard Rasmussen, Centre Efficacité Énergétique des Systèmes (CES), MINES ParisTech - École nationale supérieure des mines de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), Universidad de Sevilla. Departamento de Construcciones Arquitectónicas I (ETSA), Universidad de Sevilla. TEP130: Arquitectura, Patrimonio y Sostenibilidad: Acústica, Iluminación, Óptica y Energía, Universidad de Sevilla. TEP986: Digital Architecture for Sustainability Lab (Datus-Lab), Walbaum, Holger, Hollberg, Alexander, Thuvander, Liane, Femenias, Paula, Kurkowska, Izabela, Mjörnell, Kristina, Fudge, Colin, Frischknecht R., Ramseier L., Yang W., Birgisdottir H., Chae Ch.U., Lutzkendorf T., Passer A., Balouktsi M., Berg B., Braganca L., Butler J., Cellura M., Dixit M., Dowdell D., Francart N., Garcia Martinez A., Gomes V., Gomes da Silva M., Guimaraes G., Hoxha E., Kjendseth Wiik M., Konig H., Llatas C., Longo S., Lupisek A., Martel J., Mateus R., Nygaard Rasmussen F., Ouellet-Plamondon C., Peuportier B., Pomponi F., Pulgrossi L., Rock M., Satola D., Soust Verdaguer B., Szalay Z., Truong Nhu A., Veselka J., Volf M., Zara O., and Universidade do Minho

Subjects

China, High-rise residential buidings, Economics, 020209 energy, Context (language use), 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, 7. Clean energy, Teknologi: 500 [VDP], 12. Responsible consumption, Life cycle related environmental, [SPI]Engineering Sciences [physics], Engenharia e Tecnologia::Engenharia Civil, Benchmark (surveying), Ação climática, 11. Sustainability, 0202 electrical engineering, electronic engineering, information engineering, ddc:330, Shear wall, Energias renováveis e acessíveis, Buildings, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, International research, Cidades e comunidades sustentáveis, Settore ING-IND/11 - Fisica Tecnica Ambientale, Scope (project management), LCA, Annex 72 IEA, Environmental economics, environmental assessment, office building, LCA, Tianjin, Greenhouse gases, 13. Climate action, Heating energy, Greenhouse gas, Assessment methods, Environmental science

Abstract

Introduction: The international research project IEA EBC Annex 72 investigates the life cycle related environmental impacts caused by buildings. The project aims inter alia to harmonise LCA approaches on buildings. Methods: To identify major commonalities and discrepancies among national LCA approaches, reference buildings were defined to present and compare the national approaches. A residential high-rise building located in Tianjin, China, was selected as one of the reference buildings. The main construction elements are reinforced concrete shear walls, beams and floor slabs. The building has an energy reference area of 4566 m2 and an operational heating energy demand of 250 MJ/m2a. An expert team provided information on the quantities of building materials and elements required for the construction, established a BIM model and quantified the operational energy demand. Results: The greenhouse gas emissions and environmental impacts of the building were quantified using 17 country-specific national assessment methods and LCA databases. Comparisons of the results are shown on the level of building elements as well as the complete life cycle of the building. Conclusions: The results of these assessments show that the main differences lie in the LCA background data used, the scope of the assessment and the reference study period applied. Despite the variability in the greenhouse gas emissions determined with the 17 national methods, the individual results are relevant in the respective national context of the method, data, tool and benchmark used. It is important that environmental benchmarks correspond to the particular LCA approach and database of a country in which the benchmark is applied. Furthermore, the results imply to include building technologies as their contribution to the overall environmental impacts is not negligible. Grant support: The authors thank the IEA for its organizational support and the funding organizations in the participating countries for their financial support., IEA -International Energy Agency(undefined)

Published

2020

23. Comparison of the environmental assessment of an identical office building with national methods

Author

Brian Berg, F. Nygaard Rasmussen, Bruno Peuportier, Ricardo Mateus, Antonín Lupíšek, Damien Trigaux, Maurizio Cellura, C. K. Chau, Sonia Longo, Claudiane Ouellet-Plamondon, Maria Balouktsi, P. Ryklová, D. Dowdell, Sébastien Lasvaux, Guillaume Habert, L. Huang, Harpa Birgisdottir, E. Alsema, Rolf André Bohne, B. Soust Verdaguer, Manish K. Dixit, Martin Röck, Alexander Passer, Holger König, L. Ramseier, N. Francart, Vanessa Gomes, A. García Martínez, Rolf Frischknecht, W. Yang, Alexander Hollberg, Chang-U Chae, Thomas Lützkendorf, Carmen Llatas, Luís Bragança, J. Martel, Zsuzsa Szalay, Francesco Pomponi, Passer, A, Lutzkendorf, T, Habert, G, KrompKolb, H, Monsberger, M, Centre Efficacité Énergétique des Systèmes (CES), MINES ParisTech - École nationale supérieure des mines de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), Universidade do Minho, and Frischknecht R, Birgisdottir H, Chae Ch U , Lützkendorf, Passer A, Alsema E, Balouktsi M, Berg B, Dowdell D, García Martínez A, Habert A, Hollberg A, König H, Lasvaux, Llatas C, Nygaard Rasmussen F, Peuportier B, Ramseier L, Röck M, Soust Verdaguer B, Szalay Z, Bohne R A, Bragança L, Cellura M, Chau C K, Dixit M, Francart N, Gomes V, Huang L, Longo S, Lupíšek A, Martel J, Mateus R, Ouellet-Plamondon C, Pomponi F, Ryklová P, Trigaux D, Yang W

Subjects

Primary energy, Economics, 0211 other engineering and technologies, Social Sciences, Building material, 02 engineering and technology, 010501 environmental sciences, engineering.material, 01 natural sciences, Engenharia e Tecnologia::Engenharia Civil, Annex 72, 11. Sustainability, 021105 building & construction, ddc:330, Production (economics), Environmental impact assessment, 0105 earth and related environmental sciences, Settore ING-IND/11 - Fisica Tecnica Ambientale, Comparative Analysis, Science & Technology, Energy demand, Environmental assessment, [SDE.IE]Environmental Sciences/Environmental Engineering, business.industry, LCA, Arts & Humanities, Environmental economics, 13. Climate action, Greenhouse gas, Assessment methods, engineering, Environmental science, Electricity, business, Building life cycle assessment

Abstract

The IEA EBC Annex 72 focuses on the assessment of the primary energy demand, greenhouse gas emissions and environmental impacts of buildings during production, construction, use (including repair and replacement) and end of life (dismantling), i.e. during the entire life cycle of buildings. In one of its activities, reference buildings (size, materialisation, operational energy demand, etc.) were defined on which the existing national assessment methods are applied using national (if available) databases and (national/regional) approaches. The ?be2226? office building in Lustenau, Austria was selected as one of the reference buildings. TU Graz established a BIM model and quantified the amount of building elements as well as construction materials required and the operational energy demand. The building assessment was carried out using the same material and energy demand but applying the LCA approach used in the different countries represented by the participating Annex experts. The results of these assessments are compared in view of identifying major discrepancies. Preliminary findings show that the greenhouse gas emissions per kg of building material differ up to a factor of two and more. Major differences in the building assessments are observed in the transports to the construction site (imports) and the construction activities as well as in the greenhouse gas emissions of the operational energy demand (electricity). The experts document their practical difficulties and how they overcame them. The results of this activity are used to better target harmonisation efforts., IEA -International Association for the Evaluation of Educational Achievement(Slovenia)

Published

2019

24. Embodied carbon tools for architects and clients early in the design process

Author

F. Nygaard Rasmussen, Harpa Birgisdottir, Rob Marsh, Pomponi, F., Moncaster, A., and De Wolf, C.

Subjects

Decision support system, Engineering, business.industry, Process (engineering), 0211 other engineering and technologies, Embodied carbon, Margin of error, 02 engineering and technology, Building design, Construction engineering, 021105 building & construction, Systems engineering, 021108 energy, business, Engineering design process

Abstract

Alterations of a building design are easier facilitated in the early stages of a building design where less strategic parameters are fixed. Tools for environmental assessments are aimed for decision-support but are often used late in the building design process because the calculations rely on detailed volumes of material uses. This paradox can be addressed by using carbon profiles of a large set of pre-specified, pre-calculated building elements together with limited, geometrical input data of the early building design. The simplified approach allows for embodied carbon modelling within minutes and at a 5-10 % margin of error compared to more detailed tools.

Published

2018

25. Embodied Carbon Measurement, Mitigation and Management Within Europe, Drawing on a Cross-Case Analysis of 60 Building Case Studies

Author

F. Nygaard Rasmussen, Tove Malmqvist, Harpa Birgisdottir, Alice Moncaster, E. Soulti, A. Houlihan Wiberg, Pomponi, F., Moncaster, A., and De Wolf, C.

Subjects

Architectural engineering, Political science, Energy agency, Embodied carbon, The arts, Cross case analysis

Abstract

This chapter provides a comprehensive overview of the state of the art on this subject within Europe. In order to do so, it draws on a cross-case analysis of over 60 European case studies, developed and analysed by the authors as part of the International Energy Agency Annex 57 project.

Published

2018

26. COVID-19 in patients with paroxysmal nocturnal haemoglobinuria: an Italian multicentre survey.

Author

Barcellini W, Fattizzo B, Giannotta JA, Quattrocchi L, Aydin S, Barone F, Carbone C, Pomponi F, Metafuni E, Beggiato E, Sica S, Di Bona E, Lanza F, Notaro R, and Iori AP

Subjects

Adult, Anemia, Aplastic complications, COVID-19 epidemiology, Female, Humans, Italy epidemiology, Male, Middle Aged, Myelodysplastic Syndromes complications, SARS-CoV-2 isolation & purification, COVID-19 complications, Hemoglobinuria, Paroxysmal complications

Published

2021

27. A New Estimate of Building Floor Space in North America.

Author

Arehart JH, Pomponi F, D'Amico B, and Srubar WV 3rd

Subjects

North America, Carbon analysis

Abstract

Floor space is a key variable used to understand the energy and material demands of buildings. Using recent data sets of building footprints, we employ a random forest regression model to estimate the total floor space (conditioned and unconditioned) of the North American building stock. Our estimate for total floor space in 2016 is 88033 (+15907/-21861) million m 2 , which is 2.9 times higher than current estimates from national statistics offices. We also show how floor space per capita (m 2 cap -1 ) is not constant across the North American region, highlighting the heterogeneous nature of building stocks. As a critical variable in integrated assessment models to project energy and material demands, this result suggests that there is much more unconditioned floor space than previously realized. Furthermore, when estimating material stocks, flows, and associated embodied carbon emissions, total floor space per-capita estimates, such as those presented in this study, offer a more comprehensive approach in comparison to national statistics that do not capture unconditioned floor space. This result also calls for an investigation as to why there is such a vast difference between estimates of conditioned and total floor space.

Published

2021

28. Water, energy, and carbon dioxide footprints of the construction sector: A case study on developed and developing economies.

Author

Pomponi F and Stephan A

Subjects

India, Italy, South Africa, Carbon Dioxide analysis, Water

Abstract

Buildings and construction are major driver of anthropogenic environmental effects. While energy use and CO 2 emissions of buildings and construction have been quantified, their water footprint remains understudied from an economy-wide perspective. We use environmentally-extended multi-regional input-output analysis to quantify the water, energy and carbon (dioxide) footprints associated with the construction sector of India, Italy, South Africa, and the UK, disaggregating the supply chains driving these environmental effects by using structural path analysis. Comparisons are made in terms of contributions by country, by sector, by stage of the supply chain and in terms of actual supply chain pathways. Results show that Italy and the UK have more disaggregated and international supply chains compared to India and South Africa. Total (i.e. direct + indirect) water footprints of construction sectors vary from 11.8 to 14.8 L/USD for all countries, except India at 78.1 L/USD. There was no notable correlation between water and energy and carbon dioxide footprints in terms of sectoral contributions, even if the latter two are correlated. More developed economies exhibit a higher share of international WF than developing economies. The current focus on energy and carbon dioxide footprints might therefore miss out on significant water impacts caused by construction activities, globally., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2021. Published by Elsevier Ltd.)

Published

2021

29. A Circular Economy: Where Will It Take Us?

Author

Hart J and Pomponi F

Abstract

The avalanche of environmental challenges, from local to global and back, has prompted responses at all levels from personal to inter-governmental. The results of these responses have fallen in the range between useful and counterproductive, with many examples on each side, but the scale of the overall challenge continues to escalate. Moving towards a zero-carbon global economy through absolute reductions in fossil fuel usage is a sure way of mitigating climate change, and a range of environmental, social and economic benefits would follow. The case for a Circular Economy (CE), however, is less clear. Whilst some CE initiatives may lead to the decoupling of economic growth from resource extraction, this does not necessarily equate to reducing the rate of extraction. Thus, the contribution of CE to the achievement of environmental objectives globally cannot be taken for granted. In terms of social impact, the best that can be said is that CE might be neutral. Technologies that promote the 'sharing economy' for instance, often suggested as a crucial CE strategy, create opportunities for individual wealth accumulation, but are also a route to the gig economy and the casualisation of labour. CE is arguably a business imperative, but definitive evidence to support the idea of a circular economy that meets social and environmental goals needs development., Competing Interests: Conflict of InterestThe authors declare no competing interests., (© The Author(s) 2021.)

Published

2021

30. A Novel Method for Estimating Emissions Reductions Caused by the Restriction of Mobility: The Case of the COVID-19 Pandemic.

Author

Pomponi F, Li M, Sun YY, Malik A, Lenzen M, Fountas G, D'Amico B, Akizu-Gardoki O, and Luque Anguita M

Abstract

The COVID-19 pandemic is the single largest event in contemporary history in terms of the global restriction of mobility, with the majority of the world population experiencing various forms of "lockdown". This phenomenon incurred increased amounts of teleworking and time spent at home, fewer trips to shops, closure of retail outlets selling non-essential goods, and the near disappearance of leisure and recreational activities. This paper presents a novel method for an economy-wide estimate of the emissions reductions caused by the restriction of movement. Using a global multiregional macro-economic model complemented by Google Community Mobility Reports (CMRs) and national transport data, we cover 129 individual countries and quantify direct and indirect global emissions reductions of greenhouse gases (GHG; 1173 Mt), PM 2.5 (0.23 Mt), SO 2 (1.57 Mt), and NO x (3.69 Mt). A statistically significant correlation is observed between cross-country emission reductions and the stringency of mobility restriction policies. Due to the aggregated nature of the CMRs, we develop different scenarios linked to consumption, work, and lifestyle aspects. Global reductions are on the order of 1-3% (GHG), 1-2% (PM 2.5 ), 0.5-2.8% (SO 2 ), and 3-4% (NO x ). Our results can help support crucial decision making in the post-COVID world, with quantified information about how direct and indirect consequences of mobility changes benefit the environment., Competing Interests: The authors declare no competing financial interest., (© 2020 American Chemical Society.)

Published

2020

31. Global socio-economic losses and environmental gains from the Coronavirus pandemic.

Author

Lenzen M, Li M, Malik A, Pomponi F, Sun YY, Wiedmann T, Faturay F, Fry J, Gallego B, Geschke A, Gómez-Paredes J, Kanemoto K, Kenway S, Nansai K, Prokopenko M, Wakiyama T, Wang Y, and Yousefzadeh M

Subjects

COVID-19, Commerce, Conservation of Natural Resources, Greenhouse Gases, Humans, Socioeconomic Factors, Coronavirus Infections economics, Pandemics economics, Pneumonia, Viral economics

Abstract

On 3 April 2020, the Director-General of the WHO stated: "[COVID-19] is much more than a health crisis. We are all aware of the profound social and economic consequences of the pandemic (WHO, 2020)". Such consequences are the result of counter-measures such as lockdowns, and world-wide reductions in production and consumption, amplified by cascading impacts through international supply chains. Using a global multi-regional macro-economic model, we capture direct and indirect spill-over effects in terms of social and economic losses, as well as environmental effects of the pandemic. Based on information as of May 2020, we show that global consumption losses amount to 3.8$tr, triggering significant job (147 million full-time equivalent) and income (2.1$tr) losses. Global atmospheric emissions are reduced by 2.5Gt of greenhouse gases, 0.6Mt of PM2.5, and 5.1Mt of SO2 and NOx. While Asia, Europe and the USA have been the most directly impacted regions, and transport and tourism the immediately hit sectors, the indirect effects transmitted along international supply chains are being felt across the entire world economy. These ripple effects highlight the intrinsic link between socio-economic and environmental dimensions, and emphasise the challenge of addressing unsustainable global patterns. How humanity reacts to this crisis will define the post-pandemic world., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

32. A compactness measure of sustainable building forms.

Author

D'Amico B and Pomponi F

Abstract

Global population growth and urbanization necessitate countless more buildings in this century, causing an unprecedented increase in energy consumption, greenhouse gas emissions, waste generation and resource use. It is imperative to achieve maximal efficiency in buildings quickly. The building envelope is a key element to address environmental concerns, as it is responsible for thermal transfers to the outdoors, causing energy demand and carbon emissions. It also requires cladding, thus consuming a significant amount of finite resources. This paper investigates the relationship between surface area and indoor space to unravel the sustainability of building forms. Firstly, we demonstrate what the optimal form is. Secondly, as a single definite form is of little use in practice, we develop a scale-independent metric to measure the degree of optimality of building forms and show its practical use. This newly developed metric can significantly help in early design stages, by quantifying how much a building form deviates from optimality and identifying the domain of alternative geometries to bring us closer to it. This compactness measure also represents a theoretical basis for further research, to explore how optimality changes when additional parameters are factored in. It therefore contributes to both theory and practice to support global efforts towards sustainable built environments., Competing Interests: The authors declare no competing interests in pursuing this research.

Published

2019

33. Embodied carbon mitigation and reduction in the built environment - What does the evidence say?

Author

Pomponi F and Moncaster A

Subjects

Carbon Dioxide, Humans, Carbon, Construction Materials standards, Environment Design, Environmental Pollution prevention & control

Abstract

Of all industrial sectors, the built environment puts the most pressure on the natural environment, and in spite of significant efforts the International Energy Agency suggests that buildings-related emissions are on track to double by 2050. Whilst operational energy efficiency continues to receive significant attention by researchers, a less well-researched area is the assessment of embodied carbon in the built environment in order to understand where the greatest opportunities for its mitigation and reduction lie. This article approaches the body of academic knowledge on strategies to tackle embodied carbon (EC) and uses a systematic review of the available evidence to answer the following research question: how should we mitigate and reduce EC in the built environment? 102 journal articles have been reviewed systematically in the fields of embodied carbon mitigation and reduction, and life cycle assessment. In total, 17 mitigation strategies have been identified from within the existing literature which have been discussed through a meta-analysis on available data. Results reveal that no single mitigation strategy alone seems able to tackle the problem; rather, a pluralistic approach is necessary. The use of materials with lower EC, better design, an increased reuse of EC-intensive materials, and stronger policy drivers all emerged as key elements for a quicker transition to a low carbon built environment. The meta-analysis on 77 LCAs also shows an extremely incomplete and short-sighted approach to life cycle studies. Most studies only assess the manufacturing stages, often completely overlooking impacts occurring during the occupancy stage and at the end of life of the building. The LCA research community have the responsibility to address such shortcomings and work towards more complete and meaningful assessments., (Crown Copyright © 2016. Published by Elsevier Ltd. All rights reserved.)

Published

2016