Page 142 - Materials Chemistry, Second Edition
P. 142
138 6. Life cycle thinking for sustainable development in the building industry
Khasreen, M.M., Banfill, P.F.G., Menzies, G.F., 2009a. Life-cycle assessment and the environmental impact of build-
ings: a review. Sustainability 1, 674–701. https://doi.org/10.3390/su1030674.
Khasreen, M.M., Banfill, P.F.G., Menzies, G.F., 2009b. Life-cycle assessment and the environmental impact of build-
ings: a review. Sustainability 1 (3), 534–544.
Li, D.Z., Cui, P., Lu, Y.J., 2016. Development of an automated estimator of life-cycle carbon emissions for residential
buildings: a case study in Nanjing, China. Habitat Int. 57, 154–163 (in Chinese).
Liu, Y., Zhang, Y.F., 2016. Research on green building materials selection based on life cycle evaluation. Prog. Chinese
Mater. 35 (10). 769–775+790. (in Chinese).
MIIT, Instruction for Promoting Green Building Material Standard, Certification and Labeling. http://www.miit.
gov.cn/n1146285//content.html. (Accessed 15 October 2018).
Minho, J., Twaheon, H., Changyoon, J., 2015. Hybrid LCA model for assessing the embodied environmental impacts
of buildings in South Korea. Environ. Impact Assess. Rev. 50, 143–155.
NBSC (National Bureau of Statistics of China), 2001-2016. China Statistical Yearbook on Construction. China Statistics
Press, Beijing (in Chinese).
Ng, S.T., Chen, Y., Wong, J.M.W., 2013. Variability of building environmental assessment tools on evaluating carbon
emissions. Environ. Impact Assess. 38, 131–141.
Ning, J., 2017. China Statistical Yearbook-2017. China Statistics Press, Beijing.
Pu, Y.H., Tang, J.L., 2012. The enlightenment of recycling construction waste in Japan to China [J]. Construct. Technol.
21, 43–45 (in Chinese).
Strauss, K., Brent, A., Hietkamp, S., 2006. Characterisation and normalisation factors for life cycle impact assessment
mined abiotic resources categories in South Africa: the manufacturing of catalytic converter exhaust systems as a
case study. Int. J. Life Cycle Assess. 11, 162–171.
Sun, C.J., Zhou, G., Ge, Y.J., 2017. Application research of BIM technology in the whole life cycle of sustainable green
building. Proj. Manag. Technol. (2) (in Chinese).
Tang, L.B., 2014. Application analysis of green building materials in building energy conservation. Shanghai Build.
Mater. (2), 37–38 (in Chinese).
Tang, 2016. Application of new energy-saving materials for green buildings in modern urban development. USA &
Times (4), 34–35.
Tanikawa, H., Fishman, T., Okuoka, K., et al., 2015. The weight of society over time and space-a comprehensive
account of the construction material stock of Japan, 1945-2010. J. Ind. Ecol. 19, 778–791.
Thormark, C., 2006. The effect of materials choice on the total energy need and recycling potential of a building. Build.
Environ. 41, 1019–1026.
Wang, J., Bao, Y.Y., 2015. Review the use of ecological environment materials. Technol. Innov. Appl. 5, 23–26.
Xie, H.T., Yan, Y.F., 2015. Application analysis of green building materials and building energy conservation in
engineering. SME Manag. Technol. (late issue) (9), 118.
Xiong, W., Deng, J.Y., 2016. Study on the life cycle assessment method of Japanese green buildings. Const. Econ.
37 (02), 95–99.
Yi, P., De, H., 2005. Methods of Life Cycle Environmental Impact Assessment. Association of Industrial environmen-
tal management, pp. 27–256.
You, P., Hu, D., Zhang, H., Guo, Z., Zhao, Y., Wang, B., Yuan, Y., 2011. Carbon emissions in the system in China-a case
study of residential life cycle of urban building system in China-a case study of residential buildings. Ecol. Com-
plex. 8 (2), 201–212 (in Chinese).
Y€ ucel, G., 2013. Extent of inertia caused by the existing building stock against an energy transition in the Netherlands.
Energy Build. 56, 134–145.
Zhang, C., Sun, L.N., 2018. Status quo of sludge treatment and utilization and development prospects [J]. Heilong-
jiang Agri. Sci. 09, 158–161 (in Chinese).
