Influence of energy mix on the life cycle of an eco-neighborhood, a case study of 150 countries

[en] In recent years, the destruction of the ecosystem, due to strong emissions of greenhouse gas into the atmosphere by humans has led to significant damage to wildlife, human health, and flora. This has significantly changed the human life cycle. Nowadays, the environmental damage costs are applied for the countries strongly impacting pollutant emission. To this end, developing countries receive annual compensation from the countries considered to be the most polluting. So far, decision-makers seem to be unaware that, at the scale of an eco-neighborhood, some emerging countries produce also a significant amount of CO2. The main purpose of this research is to quantify and to compare the effect of the energy mix of 150 countries on three environmental impacts generated by an eco-neighborhood: greenhouse effect, energy demand, and biodiversity damage. To perform this comparison, the same neighborhood design is applied to 150 countries, but four parameters are adapted to each country: energy mix, local climate, building materials, and occupants’ mobility. In addition, this research evaluates the induced environmental costs of the neighborhood over a life cycle of 100 years and examines the impact of mobility and photovoltaic panel on these environmental costs. The different environmental impacts were evaluated by the Pleiades ACV simulation software under four phases (construction, use, renovation, and demolition), before being translated into environmental costs. Among the four local parameters (energy mix, local materials, climate, and transport), the energy mix has the most significant effect on the three studied environmental impacts. The results show that the countries having a higher concentration of renewable energy sources produce lower CO2 than others. Domestic and material waste are also one of the main sources of greenhouse gas emissions and biodiversity damage in a sustainable neighborhood. The biodiversity damage is high in Sub-Sahara Africa, and MiddleEast, but low in the USA, Brazil, European Union, Russia, and Australia. The implementation of photovoltaic panels in a sustainable neighborhood mitigates, on average, 15.9% of carbon dioxide emissions and 21.2% of primary energy demand; but, unfortunately, this solution increases up to 25.0% the biodiversity damage.

Research center :

LEMA
UEE - Urban and Environmental Engineering - ULiège
Lepur : Centre de Recherche sur la Ville, le Territoire et le Milieu rural - ULiège

Disciplines :

Architecture
Energy

Author, co-author :

Kameni Nematchoua, Modeste ; Université de Liège - ULiège > Département ArGEnCo > Urbanisme et aménagement du territoire

Asadi, Somayeh

Reiter, Sigrid ; Université de Liège - ULiège > Département ArGEnCo > Urbanisme et aménagement du territoire

Language :

English

Title :

Influence of energy mix on the life cycle of an eco-neighborhood, a case study of 150 countries

Publication date :

19 August 2020

Journal title :

Renewable Energy

Publisher :

Elsevier

Volume :

162

Pages :

81-97

Peer reviewed :

Peer reviewed

Name of the research project :

ZEUS

Available on ORBi :

since 24 August 2020

Statistics

Number of views

71 (4 by ULiège)

Number of downloads

253 (6 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

Bibliography

IPCC, Summary for policy makers (2013) Climate: The Physical Science Basis, Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change
IPCC, Climate Change 2007: Synthesis Report. Contribution of Working Groups I, II, and III to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change (2007), Cambridge University Press Cambridge, UK
International Energy AgencyTransition to Sustainable Buildings, Strategies and Opportunities to 2050ISBN: 978-92-64-20241-20242 (2013)
Artola, I., Rademaekers, K., Williams, R., J. YearwoodBoosting building renovation: what potential and value for Europe?PE (2016), 587, p. 326
Huovila, P., Alla-Juusela, M., Melchert, L., Pouffary, S., Buildings and Climate Change: Summary for Decision-Makers (2007), pp. 2-56. , United Nations Environment Programme
VlatkoMilić, K., Moshfegh, B., On the performance of LCC optimization software OPERA-MILP by comparison with building energy simulation software IDA ICE (2018) Build. Environ., 128, pp. 305-319
Nematchoua, M.K., Orosa, J., Reiter, S., Energy consumption assessment due to the mobility of inhabitants, and multiannual prospective on the horizon 2030-2050
A case of Belgium (2019) Energy, 171, pp. 523-534
Invidiata, A., EnedirGhisi, Impact of climate change on heating and cooling energy demand in houses in Brazil (2016) Energy Build., 130, pp. 20-32
Nematchoua, M.K., Yvon, A., Kalameu, O., Asadi, S., Reiter, S., Impact of climate change on demands for heating and cooling energy in hospitals. An in-depth case study of six islands located in the Indian Ocean region (2019) Sustain. Cities Soc., 44, pp. 629-645
Born, C.-H., Dupont, V., Poncelet, C., La compensation écologique desdommages causés à la biodiversité: un mal nécessaire? (2012) Aménagement, environnement,urbanisme et droit foncier: revue d’études juridiques, pp. 12-40. , Vol. Numérospécial, no. 3
Buyle, M., Braet, J., Audenaert, A., Life cycle assessment in the construction sector: a review (2013) Renew. Sustain. Energy Rev., 26, pp. 379-388
Simonen, K., Life Cycle assessment.Pocket Architecture: Technical Design Series (2014), Routledge London and New York
Lotteau, M., Loubet, P., Pousse, M., Dufrasnes, E., Sonnemann, G., , 93, pp. 165-178. , Critical review of life cycle assessment (LCA) for the built environment at the neighborhood scale. Build. Environ
Colombert, M., De Chastenet, C., Diab, Y., Gobin, C., Herfray, G., Jarrin, T., Trocmé, M., Analyse de cycle de vie à l’échelle du quartier: un outil d'aide à la décision? Le cas de la ZAC Claude Bernard à Paris (France) (2011) Environ. Urbain/UrbanEnviron., 5, pp. c1-c21
Oliver-Solà, J., Josa, A., Arena, A.P., Gabarrell, X., Rieradevall, J., The GWP-Chart: an environmental tool for guiding urban planning processes. Application to concrete sidewalks (2011) Cities, 28, pp. 245-250
Lotteau, M., Yepez-Salmon, G., Salmon, N., Environmental assessment of sustainable neighborhood projects through NEST, a decision support tool for early stage urban planning (2015) Procedia Eng., 115, pp. 69-76
Popovici, E., Contribution à l'analyse de cycle de vie des quartiers(PhD dissertation) (2006), Ecole Nationale supérieure des Mines de Paris Paris
Stephan, A., Crawford, R.H., de Myttenaere, K., Multi-scale life cycle energy analysis of a low-density suburban neighbourhood in Melbourne, Australia (2013) Build. Environ., 68, pp. 35-49
Norman, J., Maclean, H.L., Asce, M., Kennedy, C.A., Comparing high and low residential density: life-cycle analysis of energy use and greenhouse gas emissions (2006) J. Urban Plann. Dev., pp. 10-21
Trigaux, D., Allacker, K., De Troyer, F., Model for the Environmental Impact Assessment of Neighbourhoods (2014)
Allacker, K., Danielle Maia, S., Serenella, S., Land use impact assessment in the construction sector: an analysis of LCIA models and case study application (2014) Int. J. Life Cycle Assess, 19, pp. 1799-1809
De Nocker, L., Broekx, S., Liekens, I., Economischewaardering Van Verbetering Ecologischetoestandoppervlaktewater Op Basis Van Onderzoeksresultatenuit Aquamoney, Vito Intern Rapport 2011/RMA/R/248 (2011), p. 58. , 2011
TuomoNiemelä, R., JuhaJokisalo, Energy performance and environmental impact analysis of cost-optimal renovation solutions of large panel apartment buildings in Finland (2017) Sustain. Cities Soc., 32, pp. 9-30
Atmaca, A., Atmaca, N., Life cycle energy (LCEA) and carbon dioxideemissions (LCCO 2A) assessment of two residential buildings in Gaziantep,Turkey (2015) Energy Build., 102, pp. 417-431
Liu, L., Rohdin, P., Moshfegh, B., LCC assessments and environmental impacts on the energy renovation of a multi-family building from the 1890s (2016) Energy Build., 133, pp. 823-833
Broström, T., Eriksson, P., Liu, L., Rohdin, P., Ståhl, F., Moshfegh, B., A method to assess the potential for and consequences of energy retrofits in Swedish historic buildings (2014) Hist. Environ. Pol. Pract., 5, pp. 150-166
Tokarik, M.S., Richman, R.C., Life cycle cost optimization of passive energy efficiency improvements in a Toronto house (2016) Energy Build., 118, pp. 160-169
Gustafsson, S.-I., Optimal fenestration retrofits by use of MILP programming technique (2001) Energy Build., 33, pp. 843-851
Tokarik, M., Richman, R., Life cycle cost optimization of passive energy efficiency improvements in a Toronto house (2016) Energy Build., 118, pp. 160-169
Teller, J., Marique, A.F., Loiseau, V., Godard, F., Delbar, C., Référentiel Quartiers Durables (Guides Méthodologiques), Namur, Belgique, SPW, DGO4 (2014)
Riera Perez, M.G., Rey, E., A multi-criteria approach to compare urban renewal scenarios for an existing neighborhood. Case study in Lausanne (Switzerland) (2013) Build. Environ., 65, pp. 58-70
Site web of international energy statistics https://www.eia.gov/beta/international/data/browser/#/?pa=0000000010000000000000000000000000000000000000000000000000u&c=ruvvvvvfvtvnvv1urvvvvfvvvvvvfvvvou20evvvvvvvvvnvvuvo&ct=0&vs=INTL.44-2-BLR-QBTU.A&ord=CR&vo=0&v=H&end=2016
Remund, J., Müller, S., Kunz, S., Huguenin-Landl, B., Studer, C., Cattin, R., Global meteorological database version 7 software and data for engineers, planers and Education.METEOTESTFabrikstrasse 14 CH-3012 bern Switzerland (2017), www.meteotest.com, 1-17 www.meteonorm.com
Peuportier, B., Popovici, E., Troccmé, M., Analyse du cycle de vie à l’échelle du quartier, bilan et perspectives du projet ADEQU (2006) Build. Environ., 17. , 03(15)
Ecoinvent LCI database https://simapro.com/databases/ecoinvent/?gclid=CjwKCAjwsdfZBRAkEiwAh2z65sg-fOlOpNksILo.Websiteconsultedin2017
Goedkoop, M., Spriensma, R., The Eco Indicator 99: A Damage Oriented Method for Life Cycle Impact Assessment (2000), p. p142
Guinée, J.B., Gorréeb, M., Heijungs, R., Huppes, G., Lyfe Cycle Assessment
an Operational Guide to the ISI Standard (2001), p. P704
Byron, A.E., Life Cycle Cost (2007), pp. 2-8. , http://www.barringer1.com/lcc.xls, See Barringer's free LCC Excel file at
Salomon, T., Mikolasek, R., Peuportier, B., Outil de simulation thermique du bâtiment, COMFIE, fromJournée SFT-IBPSA, Outils de simulation thermo-aéraulique du bâtiment (2005), p. 8. , La Rochelle
De Nocker, L., VITO - WimDebacker, V.I.T.O., Annex: Monetisation of the MMG Method (Update 2017) (2018), pp. 1-65
Trigauxa, D., Allackera, K., De Troyera, F., Life cycle assessment of land use in neighborhoods (2017) Procedia Environ. Sci., 38, pp. 595-602
United Nations development Programme (UNDP), Fighting Climate Change: Human Solidarity in a Changing World (New York: Human Development Report (2007), p. 87. , UNDP
Gustavsson, L., Joelsson, A., Life cycle primary energy analysis of residential buildings (2010) Energy Build., 42, pp. 210-220
Burke, P.J., Income, resources and electricity mix (2010) Eng. Econ., 32, pp. 616-626
Hennicke, P., Scenarios for a robust policy mix: the final report of the German study commission on sustainable energy supply (2004) Energy Pol., 32, pp. 1673-1678
Luickx, P.J., Helsen, L.M., D'haeseleer, W.D., Influence of massive heat-pump introduction on the electricity-generation mix and the GHG effect: comparison between Belgium, France, Germany and The Netherlands (2008) Renew. Sustain. Energy Rev., 12, pp. 2140-2158
Marrero, G., Greenhouse gases emissions, growth and the energy mix in Europe (2010) Energy Econ., 32, pp. 1356-1363
Rossi, B., Marique, A.-F., Reiter, S., Life-cycle assessment of residential buildings in three different European locations.basic tool (2012) Build. Environ., 51, pp. 395-401
Rossi, B., Marique, A.-F., Reiter, S., Life-cycle assessment of residential buildings in three different European locations, case study (2012) Build. Environ., 51, pp. 402-407
Laleman, R., Albrecht, J., Jo, D., Life Cycle Analysis to estimate the environmental impact of residential photovoltaic systems in regions with a low solar irradiation (2011) Renew. Sustain. Energy Rev., 15, pp. 267-281
Jungbluth, N., Tuchschmid, M., ‘Ecoinvent Report N86’. Part XII Photovoltaics (2007)
Zhou, N., Khanna, N., Feng, W., Jing, K., Levine, M., Scenarios of energy efficiency and CO2 emissions reduction potential in the buildings sector in China to year 2050 (2018) Nat. Energy, 3, pp. 978-984. , www.nature.com/natureenergy
Blengini, G.A., Life cycle of buildings, demolition and recycling potential: a case study in Turin, Italy (2009) Build. Environ., 44, pp. 319-330
Nations Unies, Population, Development and the Environment (2013)
International Energy Agency, World Energy Outlook 2011 (2011)
Metz, B., Davidson, O., Bosch, P., Dave, R., Meyer, L., Contribution of Working Group III to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change (2007)
Comité européen de normalisation, EN 15978. Contribution des ouvrages de construction au développement durable - Évaluation de la performance environnementale des bâtiments - Méthode de calcul (2011), (Bruxelles, Belgique)
Agnès Sinaï, Un Paquet Climat-Énergie Européen Sans Audace (2014), http://www.journaldelenvironnement.net/article/bruxelles-presente-son-paquet-energie-climat-2030,42055
Sharif, A., Ali Raza, S., Ozturk, I., Afshan, S., The dynamic relationship of renewable and nonrenewable energy consumption with carbon emission: a global study with the application of heterogeneous panel estimations (2019) Renew. Energy, 133, pp. 685-691
Berardi, U., Building energy consumption in US, EU, and BRIC countries (2015) Procedia Eng., 118, pp. 128-136
Stamatiou, P., Dritsakis, N., Dynamic modeling of causal relationship between energy consumption, CO2 emissions, and economic growth in Italy (2017) Proceedings in Business and Economics, pp. 99-109. , Springer
Nematchoua, M.K., Roshan, G.R., Tchinda, R., Nasrabadi, T., Ricciardi, P., Climate change and its role in forecasting energy demand in buildings: a case study of Douala City, Cameroon (2015) J. Earth Syst. Sci., 124, pp. 269-281
Fthenakis, V.M., Frischknecht, R., Raugei, M., Kim, H., Alsema, E., Held, M., Methodology Guidelines on Life Cycle Assessment of Photovoltaic Electricity (2011), second ed. IEA PVPS Task 12: International Energy Agency Photovoltaic PowerSystems Program
Anne-Francoise, M., Sigrid, R., A simplified framework to assess the feasibility of zero-energy at the neighbourhood/community scale (2014) Energy Build., 82, pp. 114-122
UN-Habitat, (2019), https://unhabitat.org/knowledge/research-and-publications, Available: (Accessed 15 March 2019)
Pleaides LCA, (2019), https://www.izuba.fr/logiciels/outils-logiciels/pleiades-acv/, https://unhabitat.org/knowledge/research-and-publications Aaillable: (Accessed 15 March 2019)
Nematchoua, M.K., Orosa, J.A., Buratti, C., Obonyo, E., Rim, D., Ricciardi, P., Reiter, S., Comparative analysis of bioclimatic zones, energy consumption, CO2 emission and life cycle cost of residential and commercial buildings located in a tropical region: a case study of the big island of Madagascar (2020) Energy, 202, p. 117754
Nematchoua, M.K., Ricciardi, P., Orosa, J.A., Buratti, C., A detailed study of climate change and some vulnerabilities in Indian Ocean:A case of Madagascar island (2018) Sustain. Cities Soc., 41, pp. 886-898