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Primary data priorities for the life cycle inventory of construction products: focus on foreground processes



Life cycle assessment can support decisions for improving the environmental performance of construction products. However, the amount of data required for developing life cycle inventories limits the adoption of LCA. This work associates the interpretation of the impact results of construction products at the unit process level with a quantitative definition for the foreground and background system, for guiding primary data collection towards foreground processes that can be affected by decision-makers in the construction sector.


A set of construction products commonly used in Brazil is selected, and their cradle-to-gate life cycle inventories are modeled using the ecoinvent database (version 2). Life cycle impact assessment is performed using the ReCiPe Midpoint Hierarchist method. The contribution of each process during the life cycle of construction products for each impact category is quantified. These processes are associated with economic sectors, which are classified as belonging to the foreground or background system from the perspective of the construction industry. Foreground sectors are those controlled or influenced by the construction sector and are defined based on the production share consumed by the construction value chain. The elementary flows defining each impact category are also identified.

Results and discussion

Foreground processes show significant contributions to most impact results of construction products. Global warming, fine particulate matter formation, ozone formation, acidification, human carcinogenic toxicity, and terrestrial ecotoxicity are mainly caused by direct emissions and fossil fuel combustion in manufacturing processes. Land occupation for production activities contributes to land use change, while the consumption of fuels, raw materials, and water causes fossil and mineral resource scarcity and water consumption respectively. Freshwater and marine ecotoxicities and human non-carcinogenic toxicity have foreground contributions only for steel and copper products due to emissions from the landfilling of mining tails. Ionizing radiation and stratospheric ozone depletion are mostly driven by background processes. A reduced group of elementary flows covers a big share of the environmental impacts of most construction products.


The results indicate priorities for life cycle inventory primary data collection of construction products, by focusing on foreground processes and the corresponding elementary flows that cause many of the potential embodied impacts of construction. Increasing the availability of primary data for these processes improves the reliability of LCA-based decisions in the construction sector, especially in countries which still lack local LCI databases.

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Fig. 1


  • ABAL (2017) 2017 Abal statistical yearbook, São Paulo

  • ABCOBRE (2017) Brazilian copper yearbook 2017, São Paulo

  • ABIPLAST (2016, 2016) Indústria brasileira de transformação e reciclagem de material plástico - Perfil

  • ABIQUIM (2016) O Desempenho da Indústria Química Brasileira em 2016

  • ABRAFATI (2018) Associação Brasilera dos Fabricantes de Tintas. Accessed 5 Nov 2018

  • ACR (2016) Anuário Estatístico de Base Florestal para o Estado de Santa Catarina 2016 (ano base 2015). Lages

  • Almeida MI, Dias AC, Demertzi M, Arroja L (2016) Environmental profile of ceramic tiles and their potential for improvement. J Clean Prod 131:583–593.

    Article  Google Scholar 

  • Althaus H-J, Hischier R, Osses M, et al (2007) Life cycle inventories of chemicals. Ecoinvent report n. 8. Dübendorf

  • ANA (2018) Brazilian water resources report 2017. Brasília

    Google Scholar 

  • Berg J (2018) Tomorrow’s earth. Science 360:1379.

    CAS  Article  Google Scholar 

  • Bleiwas D (2011) Estimates of electricity requirements for the recovery of mineral commodities, with examples applied to sub-Saharan Africa.

  • Bourgault G, Lesage P, Samson R (2012) Systematic disaggregation: a hybrid LCI computation algorithm enhancing interpretation phase in LCA. Int J Life Cycle Assess 17:774–786.

    Article  Google Scholar 

  • Cabeza LF, Rincón L, Vilariño V, Pérez G, Castell A (2014) Life cycle assessment (LCA) and life cycle energy analysis (LCEA) of buildings and the building sector: a review. Renew Sust Energ Rev 29:394–416.

    Article  Google Scholar 

  • CEFIC (2017) Facts & Figures 2017 of the European Chemical Industry

  • Classen M, Althaus H-J, Blaser S, et al (2009) Life cycle inventories of metals. Ecoinvent report n. 10. Dübendorf

  • Condeixa K, Haddad A, Boer D (2014) Life cycle impact assessment of masonry system as inner walls: a case study in Brazil. Constr Build Mater 70:141–147.

    Article  Google Scholar 

  • Corradini G, Pierobon F, Zanetti M (2019) Product environmental footprint of a cross-laminated timber system: a case study in Italy. Int J Life Cycle Assess 24:975–988.

    Article  Google Scholar 

  • DIN (2018) EN 15804:2012+A1:2013/prA2:2018 - Sustainability of construction works - Environmental product declarations - Core rules for the product category of construction products (draft). 80

  • DNPM (2016) Anuário mineral brasileiro - principais substâncias metálicas. Brasília

  • DNPM (2018) Sumário Mineral 2016. Brasília

  • Doyle MW, Havlick DG (2009) Infrastructure and the environment. Annu Rev Environ Resour 34:349–373.

    Article  Google Scholar 

  • EPE (2016) Balanço Energético Nacional 2016: Ano base 2015. Rio de Janeiro

  • EPE (2019) Balanço energético nacional 2019: ano base 2018. Rio de Janeiro

  • European Commission (2010a) International reference life cycle data system (ILCD) handbook - general guide for life cycle assessment - detailed guidance, 1st edn. Publications Office of the European Union, Luxembourg

    Google Scholar 

  • European Commission (2010b) International reference life cycle data system (ILCD) handbook : specific guide for life cycle inventory data sets. Publications Office of the European Union, Luxembourg

    Google Scholar 

  • FAO (2017) Yearbook of forest products 2015. Food and Agriculture Organization of the United Nations, Rome

    Google Scholar 

  • Finnveden G, Hauschild MZ, Ekvall T, Guinée J, Heijungs R, Hellweg S, Koehler A, Pennington D, Suh S (2009) Recent developments in life cycle assessment. J Environ Manag 91:1–21.

    Article  Google Scholar 

  • Habert G, Bouzidi Y, Chen C, Jullien A (2010) Development of a depletion indicator for natural resources used in concrete. Resour Conserv Recycl 54:364–376.

    Article  Google Scholar 

  • Havey T (2008) California’s coastal power plants: alternative cooling system analysis. Oakland

  • Hellweg S, Mila i Canals L (2014) Emerging approaches, challenges and opportunities in life cycle assessment. Science 344:1109–1113.

    CAS  Article  Google Scholar 

  • Hischier R (2007) Life cycle inventories of packagings and graphical paper. Ecoinvent report n. 11. Dübendorf

  • Horvath A (2004) Construction materials and the environment. Annu Rev Environ Resour 29:181–204.

    Article  Google Scholar 

  • Huijbregts MAJJ, Rombouts LJAA, Hellweg S et al (2006) Is cumulative fossil energy demand a useful indicator for the environmental performance of products? Environ Sci Technol 40:641–648.

    CAS  Article  Google Scholar 

  • Huijbregts MAJ, Hellweg S, Frischknecht R, Hendriks HWM, Hungerbühler K, Hendriks AJ (2010) Cumulative energy demand as predictor for the environmental burden of commodity production. Environ Sci Technol 44:2189–2196.

    CAS  Article  Google Scholar 

  • IABR (2018) Relatório de Sustentabilidade 2018, Rio de Janeiro

  • Ingrao C, Lo Giudice A, Tricase C, Mbohwa C, Rana R (2014) The use of basalt aggregates in the production of concrete for the prefabrication industry: environmental impact assessment, interpretation and improvement. J Clean Prod 75:195–204.

    CAS  Article  Google Scholar 

  • Instituto Brasileiro do PVC (2015) Brasil recicla 17,1% de PVC pós-consumo - outubro 2015. Accessed 5 Nov 2018

  • International Energy Agency, United Nations Environment Programme (2018) 2018 Global Status Report: towards a zero-emission, efficient and resilient buildings and construction sector

  • IPCC (2014) Climate change 2014: synthesis report. Contribution of working groups I ,II and III to the Fifth Assessment Report of the Intergovernamental Panel on Climate Change. IPCC, Geneva

    Google Scholar 

  • ISO (2006a) ISO 14040 - Environmental management - life cycle assessment - principles and framework. 20

  • ISO (2006b) ISO 14044 - Environmental management - life cycle assessment - requirements and guidelines. 46

  • ISO (2017) ISO 21930 - Sustainability in buildings and civil engineering works - core rules for environmental product declarations of construction products and services. 80

  • Kellenberger D, Althaus H-J, Künninger T, et al (2007) Life cycle inventories of building products. Ecoinvent report n. 7. Dübendorf

  • Krausmann F, Gingrich S, Eisenmenger N, Erb KH, Haberl H, Fischer-Kowalski M (2009) Growth in global materials use, GDP and population during the 20th century. Ecol Econ 68:2696–2705.

    Article  Google Scholar 

  • Lafarge (2011) Sustainability 11th report. Paris

  • Lasvaux S, Schiopu N, Habert G, Chevalier J, Peuportier B (2014) Influence of simplification of life cycle inventories on the accuracy of impact assessment: application to construction products. J Clean Prod 79:142–151.

    CAS  Article  Google Scholar 

  • Lasvaux S, Achim F, Garat P, Peuportier B, Chevalier J, Habert G (2016) Correlations in life cycle impact assessment methods (LCIA) and indicators for construction materials: what matters? Ecol Indic 67:174–182.

    Article  Google Scholar 

  • Laurent A, Olsen SI, Hauschild MZ et al (2012) Limitations of carbon footprint as indicator of environmental sustainability. Environ Sci Technol 46:4100–4108.

    CAS  Article  Google Scholar 

  • Medeiros LM, Durante LC, IJA C (2018) Contribuição para a avaliação de ciclo de vida na quantificação de impactos ambientais de sistemas construtivos. Ambient Construído 18:365–385.

    Article  Google Scholar 

  • MME (2009) Perfil de argilas para cerâmica vermelha

  • MME (2010) Perfil do Titânio

  • MME (2017) Anuário estatístico do setor de transformação de não metálicos

  • Mohammadi J, South W (2017) Life cycle assessment (LCA) of benchmark concrete products in Australia. Int J Life Cycle Assess 22:1588–1608.

    CAS  Article  Google Scholar 

  • Paleari M, Lavagna M, Campioli A (2016) The assessment of the relevance of building components and life phases for the environmental profile of nearly zero-energy buildings: life cycle assessment of a multifamily building in Italy. Int J Life Cycle Assess 21:1667–1690.

    CAS  Article  Google Scholar 

  • Petek Gursel A, Masanet E, Horvath A, Stadel A (2014) Life-cycle inventory analysis of concrete production: a critical review. Cem Concr Compos 51:38–48.

    CAS  Article  Google Scholar 

  • Pfister S, Vionnet S, Levova T, Humbert S (2016) Ecoinvent 3: assessing water use in LCA and facilitating water footprinting. Int J Life Cycle Assess 21:1349–1360.

    Article  Google Scholar 

  • Regucki P, Engler B, Szeliga Z (2016) Analysis of water management at a closed cooling system of a power plant. J Phys Conf Ser 760:012026.

    CAS  Article  Google Scholar 

  • Reinhard J, Mutel CL, Wernet G, Zah R, Hilty LM (2016) Contribution-based prioritization of LCI database improvements: method design, demonstration, and evaluation. Environ Model Softw 86:204–218.

    Article  Google Scholar 

  • Reis DC, Mack-Vergara Y, John VM (2019) Material flow analysis and material use efficiency of Brazil’s mortar and concrete supply chain. J Ind Ecol 23:1396–1409.

    Article  Google Scholar 

  • Rydh CJ, Sun M (2005) Life cycle inventory data for materials grouped according to environmental and material properties. J Clean Prod 13:1258–1268.

    Article  Google Scholar 

  • Silva FB, Arduin RH, Diestelkamp ED et al (2017) The importance of primary data for life cycle assessment of construction products in Brazil. In: VII International Conference on Life Cycle Assessment in Latin America. Medellín, p 6

  • SNIC (2015) Consumo aparente de cimento por regiões e estados (t) 2015. Accessed 3 Aug 2019

  • Soust-Verdaguer B, Llatas C, García-Martínez A (2016) Simplification in life cycle assessment of single-family houses: a review of recent developments. Build Environ 103:215–227.

    Article  Google Scholar 

  • Tavares SF (2006) Metodologia de análise do ciclo de vida energético de edificações residenciais brasileiras. Universidade Federal de Santa Catarina

  • Todd JA, Curran MA (1999) Streamlined life-cycle assessment: a final report from the SETAC North America Streamlined LCA Workgroup

  • UN Environment, International Resource Panel (2018) Global materials flow database. Accessed 5 Nov 2018

  • United Nations (2015) World Population Prospects 2015 - Data Booklet (ST/ESA/SER.A/377)

  • USGS (2016) Mineral Commodity Summaries 2016.

  • Van Hoof G, Vieira M, Gausman M, Weisbrod A (2013) Indicator selection in life cycle assessment to enable decision making: issues and solutions. Int J Life Cycle Assess 18:1568–1580.

    Article  Google Scholar 

  • WBCSD (2016a) The business case for the use of life cycle metrics in construction & real estate, Geneva

  • WBCSD (2016b) GNR Project Reporting CO2 - total production volumes of cement - grey and white cement - Brazil. Accessed 12 Dec 2017

  • Weidema BP, Bauer C, Hischier R, et al (2013) Overview and methodology - data quality guideline for the ecoinvent database version 3. St. Gallen

  • Werner F, Althaus H-J, Künninger T, et al (2007) Life cycle inventories of wood as fuel and construction material. Ecoinvent report n. 9. Dübendorf

  • Wernet G, Bauer C, Steubing B, Reinhard J, Moreno-Ruiz E, Weidema B (2016) The ecoinvent database version 3 (part I): overview and methodology. Int J Life Cycle Assess 21:1218–1230.

    Article  Google Scholar 

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The authors acknowledge the financial support of the Swiss–Latin American cooperation program coordinated by the University of St. Gallen; the Foundation for Support of the Institute for Technological Research (FIPT); the Laboratory of Microstructure and Eco-efficiency of Materials (LME), the National Institute on Advanced Eco-Efficient Cement-Based Technologies (CEMtec), the São Paulo Research Foundation (FAPESP) (grant no. 2014/50948-3); the National Council for Scientific and Technological Development (CNPq) (grant no. 465593/2014-3); the Technological University of Panama (UTP), Institute for Training and Development of Human Resources (IFARHU) of the Republic of Panama (fellowship no. 08-2014-42); and the Swiss Government Excellence Scholarship for Foreign Scholars 2017/2018.

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Correspondence to Fernanda Belizario Silva.

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Silva, F.B., Reis, D.C., Mack-Vergara, Y.L. et al. Primary data priorities for the life cycle inventory of construction products: focus on foreground processes. Int J Life Cycle Assess 25, 980–997 (2020).

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  • Data collection
  • Life cycle assessment
  • Unit process
  • Foreground
  • Background
  • Construction