Carbon footprint of construction industry: A global review and supply chain analysis

[1]  G. Brundtland,et al.  Our common future , 1987 .

[2]  D. Crosthwaite The global construction market: a cross-sectional analysis , 2000 .

[3]  Manfred Lenzen,et al.  Environmental impact assessment including indirect effects—a case study using input–output analysis , 2003 .

[4]  Gjalt Huppes,et al.  System boundary selection in life-cycle inventories using hybrid approaches. , 2004, Environmental science & technology.

[5]  José M. Rueda-Cantuche,et al.  A SYMMETRIC INPUT–OUTPUT TABLE FOR EU27: LATEST PROGRESS , 2009 .

[6]  Joe Ravetz,et al.  Resource flow analysis for sustainable construction: metrics for an integrated supply chain approach , 2008 .

[7]  Robert Ries,et al.  Estimating Construction Project Environmental Effects Using an Input-Output-Based Hybrid Life-Cycle Assessment Model , 2008 .

[8]  Mohamed Osmani,et al.  Feasibility of zero carbon homes in England by 2016: a house builder's perspective , 2009 .

[9]  T. Wiedmann A review of recent multi-region input–output models used for consumption-based emission and resource accounting , 2009 .

[10]  M. Lenzen,et al.  Companies on the Scale , 2009 .

[11]  Jonatan Pinkse,et al.  Overcoming Barriers to Sustainability: An Explanation of Residential Builders' Reluctance to Adopt Clean Technologies , 2009 .

[12]  E. Hertwich,et al.  Carbon footprint of nations: a global, trade-linked analysis. , 2009, Environmental science & technology.

[13]  Walter Klöpffer,et al.  Our plans and expectations for the 14th volume 2009 of Int J Life Cycle Assess , 2009 .

[14]  Jun Li,et al.  Managing carbon emissions in China through building energy efficiency. , 2009, Journal of environmental management.

[15]  Sukumar Natarajan,et al.  Climate change and future energy consumption in UK housing stock , 2010 .

[16]  Daniel Mendoza,et al.  Modeling energy consumption and CO2 emissions at the urban scale: Methodological challenges and insights from the United States , 2010 .

[17]  Adolf Acquaye,et al.  Input-output analysis of Irish construction sector greenhouse gas emissions , 2010 .

[18]  B. Solberg,et al.  Climate change mitigation through increased wood use in the European construction sector—towards an integrated modelling framework , 2011, European Journal of Forest Research.

[19]  R. Ries,et al.  The quantification of the embodied impacts of construction projects on energy, environment, and society based on I-O LCA , 2011 .

[20]  Qinghua Zhu,et al.  Contributing to local policy making on GHG emission reduction through inventorying and attribution: A case study of Shenyang, China , 2011 .

[21]  Arnaud Mercier,et al.  Prospective on the energy efficiency and CO 2 emissions in the EU cement industry , 2011 .

[22]  S. Lutter,et al.  Quo Vadis MRIO? Methodological, data and institutional requirements for multi-region input-output analysis , 2011 .

[23]  John Ward,et al.  Aggregates in England—Economic contribution and environmental cost of indigenous supply , 2011 .

[24]  Jesper Holm,et al.  Local Climate Mitigation and Eco‐efforts in Housing and Construction as Transition Places , 2011 .

[25]  Klaus Hubacek,et al.  A "carbonizing dragon": China's fast growing CO2 emissions revisited. , 2011, Environmental science & technology.

[26]  Joseph F. Francois,et al.  The World Input-Output Database (WIOD): Contents, Sources and Methods , 2012 .

[27]  Z. Li,et al.  Inventory and input-output analysis of CO2 emissions by fossil fuel consumption in Beijing 2007 , 2012, Ecol. Informatics.

[28]  Murat Kucukvar,et al.  Sustainability Assessment of U.S. Construction Sectors: Ecosystems Perspective , 2012 .

[29]  Ling Shao,et al.  Energy-Dominated Local Carbon Emissions in Beijing 2007: Inventory and Input-Output Analysis , 2012, TheScientificWorldJournal.

[30]  Adolf Acquaye,et al.  Biofuels and their potential to aid the UK towards achieving emissions reduction policy targets , 2012 .

[31]  Tao Huang,et al.  Toward a Low Carbon–Dematerialization Society , 2012 .

[32]  S. Managi,et al.  Which industry is greener? An empirical study of nine industries in OECD countries , 2013 .

[33]  Kjartan Steen-Olsen,et al.  Integrating ecological and water footprint accounting in a multi-regional input–output framework , 2012 .

[34]  F. Shi,et al.  Regional Disparity in Carbon Dioxide Emissions , 2012 .

[35]  Yujie Lu,et al.  Effectiveness and equity implications of carbon policies in the United States construction industry , 2012 .

[36]  Lizhen Huang,et al.  Embodied air emissions in Norway's construction sector: input-output analysis , 2012 .

[37]  O. Tatari,et al.  Ecologically based hybrid life cycle analysis of continuously reinforced concrete and hot-mix asphalt pavements , 2012 .

[38]  D Trotter Towards a green economy , 2012 .

[39]  Murat Kucukvar,et al.  Eco-Efficiency of Construction Materials: Data Envelopment Analysis , 2012 .

[40]  Jorge Enrique Zafrilla,et al.  Fulfilling the Kyoto protocol in Spain: A matter of economic crisis or environmental policies? , 2012 .

[41]  Ying Fan,et al.  Energy consumption and CO2 emissions in China's cement industry: A perspective from LMDI decomposition analysis , 2012 .

[42]  Gui-Bing Hong,et al.  The status of energy conservation in Taiwan's cement industry , 2013 .

[43]  Matthew Fry,et al.  Cement, carbon dioxide, and the 'necessity' narrative: A case study of Mexico , 2013 .

[44]  M. Cellura,et al.  The role of the building sector for reducing energy consumption and greenhouse gases: An Italian case study , 2013 .

[45]  Neven Duić,et al.  Reducing the CO2 emissions in Croatian cement industry , 2013 .

[46]  Arnold Tukker,et al.  GLOBAL MULTIREGIONAL INPUT–OUTPUT FRAMEWORKS: AN INTRODUCTION AND OUTLOOK , 2013 .

[47]  Jack Steven Goulding,et al.  Carbon emission reduction strategies in the UK industrial sectors: an empirical study , 2013 .

[48]  Manfred Lenzen,et al.  BUILDING EORA: A GLOBAL MULTI-REGION INPUT–OUTPUT DATABASE AT HIGH COUNTRY AND SECTOR RESOLUTION , 2013 .

[49]  Peter S. P. Wong,et al.  Driving carbon reduction strategies adoption in the Australian construction sector – The moderating role of organizational culture , 2013 .

[50]  Yong Geng,et al.  Exploring driving factors of energy-related CO2 emissions in Chinese provinces: A case of Liaoning , 2013 .

[51]  Liu Rui-jie,et al.  Carbon emissions in the construction sector based on input-output analyses , 2013 .

[52]  Bart Los,et al.  THE CONSTRUCTION OF WORLD INPUT–OUTPUT TABLES IN THE WIOD PROJECT , 2013 .

[53]  Murat Kucukvar,et al.  Towards a triple bottom-line sustainability assessment of the U.S. construction industry , 2013, The International Journal of Life Cycle Assessment.

[54]  Glen P. Peters,et al.  COMPARING THE GTAP-MRIO AND WIOD DATABASES FOR CARBON FOOTPRINT ANALYSIS , 2014 .

[55]  N. Wang,et al.  The role of the construction industry in China's sustainable urban development , 2014 .

[56]  Balan Sundarakani,et al.  System dynamics-based modelling and analysis of greening the construction industry supply chain , 2014 .

[57]  Arnold Tukker,et al.  Global Sustainability Accounting—Developing EXIOBASE for Multi-Regional Footprint Analysis , 2014 .

[58]  Omer Tatari,et al.  Towards greening the U.S. residential building stock: A system dynamics approach , 2014 .

[59]  Murat Kucukvar,et al.  Stochastic decision modeling for sustainable pavement designs , 2014, The International Journal of Life Cycle Assessment.

[60]  Philippe Quirion,et al.  Reaping the Carbon Rent: Abatement and Overallocation Profits in the European Cement Industry, Insights from an LMDI Decomposition Analysis , 2014 .

[61]  Huijuan Dong,et al.  Three accounts for regional carbon emissions from both fossil energy consumption and industrial process , 2014 .

[62]  Murat Kucukvar,et al.  Evaluating environmental impacts of alternative construction waste management approaches using supply-chain-linked life-cycle analysis , 2014, Waste management & research : the journal of the International Solid Wastes and Public Cleansing Association, ISWA.

[63]  Glen P. Peters,et al.  Comparing the use of GTAP-MRIO and WIOD for carbon footprint analysis , 2014 .

[64]  A. Hoekstra,et al.  Humanity’s unsustainable environmental footprint , 2014, Science.

[65]  Dequn Zhou,et al.  Sectoral comparison of electricity-saving potentials in China: An analysis based on provincial input–output tables , 2014 .

[66]  Murat Kucukvar,et al.  Towards Life Cycle Sustainability Assessment of Alternative Passenger Vehicles , 2014 .

[67]  Murat Kucukvar,et al.  Scope-based carbon footprint analysis of U.S. residential and commercial buildings: An input–output hybrid life cycle assessment approach , 2014 .

[68]  O. Tatari,et al.  Sustainability assessment of U.S. final consumption and investments: triple-bottom-line input–output analysis , 2014 .

[69]  Jack Chin Pang Cheng,et al.  Life cycle carbon footprint measurement of Portland cement and ready mix concrete for a city with local scarcity of resources like Hong Kong , 2014, The International Journal of Life Cycle Assessment.

[70]  Linwei Ma,et al.  The implications of China’s investment-driven economy on its energy consumption and carbon emissions , 2014 .

[71]  Sumiani Yusoff,et al.  A review of life cycle assessment method for building industry , 2015 .

[72]  Yuanyuan Gong,et al.  Life Cycle Building Carbon Emissions Assessment and Driving Factors Decomposition Analysis Based on LMDI—A Case Study of Wuhan City in China , 2015 .

[73]  W. Zeng,et al.  Carbon Footprints and Embodied Carbon Flows Analysis for China’s Eight Regions: A New Perspective for Mitigation Solutions , 2015 .

[74]  Xianjin Huang,et al.  Spatiotemporal Changes of Built-Up Land Expansion and Carbon Emissions Caused by the Chinese Construction Industry. , 2015, Environmental science & technology.

[75]  Nasir Shafiq,et al.  Minimization of Embodied Carbon Footprint from Housing Sector of Malaysia , 2015 .

[76]  Lishan Xiao,et al.  A sustainable urban form: The challenges of compactness from the viewpoint of energy consumption and carbon emission , 2015 .

[77]  John E. Anderson,et al.  Energy analysis of the built environment—A review and outlook , 2015 .

[78]  Nuri Cihat Onat,et al.  Integrated Sustainability Assessment Framework for the U.S. Transportation , 2015 .

[79]  Nuri Onat,et al.  A Macro-Level Sustainability Assessment Framework for Optimal Distribution of Alternative Passenger Vehicles , 2015 .

[80]  Ernst Worrell,et al.  Energy Efficiency Improvement Potentials for the Cement Industry in Ethiopia , 2015 .

[81]  Ali Tighnavard Balasbaneh,et al.  Combinations of building construction material for residential building for the global warming mitigation for Malaysia , 2015 .

[82]  Peter S. P. Wong,et al.  The drivers and strategies of carbon reduction in projects: perceptions of the Australian construction practitioners , 2015 .

[83]  David Gibbs,et al.  Building a green economy? Sustainability transitions in the UK building sector , 2015 .

[84]  Murat Kucukvar,et al.  A global, scope-based carbon footprint modeling for effective carbon reduction policies: Lessons from the Turkish manufacturing , 2015 .

[85]  Murat Kucukvar,et al.  Linking national food production to global supply chain impacts for the energy-climate challenge: the cases of the EU-27 and Turkey , 2015 .

[86]  Wei Pan,et al.  Zero carbon homes: Perceptions from the UK construction industry , 2015 .

[87]  Hongxun Liu,et al.  CO2 mitigation potential in China's building construction industry: A comparison of energy performance , 2015 .

[88]  Peng Wu,et al.  Economic sustainability, environmental sustainability and constructability indicators related to concrete- and steel-projects , 2015 .

[89]  David Thorpe,et al.  Potential carbon emission reductions in Australian construction systems through bioclimatic principles , 2016 .

[90]  Rajib Sinha,et al.  Environmental footprint assessment of building structures: A comparative study , 2016 .

[91]  Boqiang Lin,et al.  A quantile regression analysis of China's provincial CO2 emissions: Where does the difference lie? , 2016 .

[92]  Murat Kucukvar,et al.  Integration of system dynamics approach toward deepening and broadening the life cycle sustainability assessment framework: a case for electric vehicles , 2016, The International Journal of Life Cycle Assessment.

[93]  Dezhi Li,et al.  Carbon emissions and policies in China's building and construction industry: Evidence from 1994 to 2012 , 2016 .

[94]  Bing Zhang,et al.  Globalization and Climate Change: New Empirical Panel Data Evidence , 2016 .

[95]  Nathan Kibwami,et al.  Enhancing sustainable construction in the building sector in Uganda , 2016 .

[96]  Richard Wood,et al.  The Carbon Footprint of Norwegian Household Consumption 1999–2012 , 2016 .

[97]  Manfred Lenzen,et al.  Substantial nitrogen pollution embedded in international trade , 2016 .

[98]  Omer Tatari,et al.  Uncertainty-embedded dynamic life cycle sustainability assessment framework: An ex-ante perspective on the impacts of alternative vehicle options , 2016 .

[99]  Omer Tatari,et al.  Light-duty electric vehicles to improve the integrity of the electricity grid through Vehicle-to-Grid technology: Analysis of regional net revenue and emissions savings , 2016 .

[100]  Pascal Brinks,et al.  Potential-analysis of grey energy limits for residential buildings in Germany , 2016 .

[101]  E. Hertwich,et al.  Environmental Impact Assessment of Household Consumption , 2016 .

[102]  Geoffrey Qiping Shen,et al.  Energy use embodied in China's construction industry: A multi-regional input-output analysis , 2016 .

[103]  Franz-Josef Ulm,et al.  Data analytics for simplifying thermal efficiency planning in cities , 2016, Journal of The Royal Society Interface.

[104]  Omer Tatari,et al.  Investigating carbon footprint reduction potential of public transportation in United States: A system dynamics approach , 2016 .

[105]  P. G. Taylor,et al.  Construction sector views on low carbon building materials , 2016 .

[106]  Tao Zhao,et al.  Sensitivity analysis of technology and supply change for CO2 emission intensity of energy-intensive industries based on input–output model , 2016 .

[107]  Murat Kucukvar,et al.  Energy-climate-manufacturing nexus: New insights from the regional and global supply chains of manufacturing industries , 2016 .

[108]  Omer Tatari,et al.  The Climate Change-Road Safety-Economy Nexus: A System Dynamics Approach to Understanding Complex Interdependencies , 2017, Syst..

[109]  Neven Duić,et al.  A review of developments in technologies and research that have had a direct measurable impact on sustainability considering the Paris agreement on climate change , 2017 .

[110]  Y. Ali Carbon, water and land use accounting: Consumption vs production perspectives , 2017 .

[111]  Omer Tatari,et al.  Public transportation adoption requires a paradigm shift in urban development structure , 2017 .

[112]  Daniel Chemisana,et al.  Concentrating solar systems: Life Cycle Assessment (LCA) and environmental issues , 2017 .

[113]  Rongrong Li,et al.  Decoupling and Decomposition Analysis of Carbon Emissions from Electric Output in the United States , 2017 .

[114]  Guanyi Yu,et al.  Carbon emissions in China’s industrial sectors , 2017 .

[115]  Manfred Lenzen,et al.  The Global MRIO Lab – charting the world economy , 2017 .

[116]  L. Miao,et al.  Sector decomposition of China’s national economic carbon emissions and its policy implication for national ETS development , 2017 .

[117]  Qian Shi,et al.  An empirical study on the CO2 emissions in the Chinese construction industry , 2017 .

[118]  M. Habibullah,et al.  Financial development and sectoral CO2 emissions in Malaysia , 2017, Environmental Science and Pollution Research.

[119]  Boqiang Lin,et al.  Cost-based modelling of optimal emission quota allocation , 2017 .

[120]  Murat Kucukvar,et al.  Exploring the material footprints of national electricity production scenarios until 2050: The case for Turkey and UK , 2017 .

[121]  Rongrong Li,et al.  Moving Low-Carbon Construction Industry in Jiangsu Province: Evidence from Decomposition and Decoupling Models , 2017 .

[122]  Fausto Freire,et al.  A review of fleet-based life-cycle approaches focusing on energy and environmental impacts of vehicles , 2017 .

[123]  Thomas Wiedmann,et al.  An input–output virtual laboratory in practice – survey of uptake, usage and applications of the first operational IELab , 2017 .

[124]  Q. Du,et al.  Spatiotemporal Characteristics and InfluencingFactors of China’s Construction IndustryCarbon Intensity , 2017 .

[125]  Mark Ferguson,et al.  Carbon dioxide emissions of plug-in hybrid electric vehicles: A life-cycle analysis in eight Canadian cities , 2017 .

[126]  S. Koh,et al.  Comparing linear and circular supply chains: a case study from the construction industry , 2017 .

[127]  Wei Li,et al.  Temporal and spatial heterogeneity of carbon intensity in China's construction industry , 2017 .

[128]  Arnaud Castel,et al.  Hybrid life cycle assessment of greenhouse gas emissions from cement, concrete and geopolymer concrete in Australia , 2017 .

[129]  Daniel Moran,et al.  Identifying species threat hotspots from global supply chains , 2016, Nature Ecology &Evolution.

[130]  Edgar G. Hertwich,et al.  Mapping the carbon footprint of EU regions , 2017 .

[131]  Qian Shi,et al.  Driving factors of the changes in the carbon emissions in the Chinese construction industry , 2017 .

[132]  Chunlu Liu,et al.  The log mean divisia index based carbon productivity in the Australian construction industry , 2017 .

[133]  Seungjun Roh,et al.  Integrated building life-cycle assessment model to support South Korea's green building certification system (G-SEED) , 2017 .

[134]  Murat Kucukvar,et al.  A framework for water and carbon footprint analysis of national electricity production scenarios , 2017 .

[135]  Fenglai Wang,et al.  Life-cycle carbon emission assessment and permit allocation methods: A multi-region case study of China’s construction sector , 2017 .

[136]  Anthony Halog,et al.  Systems Thinking for Life Cycle Sustainability Assessment: A Review of Recent Developments, Applications, and Future Perspectives , 2017 .

[137]  Y. Ali,et al.  Carbon and water footprint accounts of Italy: A Multi-Region Input-Output approach , 2018 .

[138]  E. Hertwich,et al.  Building Material Use and Associated Environmental Impacts in China 2000-2015. , 2018, Environmental science & technology.

[139]  Weisheng Lu,et al.  Decoupling relationship between economic output and carbon emission in the Chinese construction industry , 2018, Environmental Impact Assessment Review.

[140]  João F. D. Rodrigues,et al.  The evolution of inter-sectoral linkages in China's energy-related CO2 emissions from 1997 to 2012 , 2018 .

[141]  Q. Du,et al.  Carbon Emissions in China’s Construction Industry: Calculations, Factors and Regions , 2018, International journal of environmental research and public health.

[142]  Liyin Shen,et al.  Will China's building sector participate in emission trading system? Insights from modelling an owner's optimal carbon reduction strategies , 2018, Energy Policy.

[143]  Sarah Schmidt,et al.  EXIOBASE 3: Developing a Time Series of Detailed Environmentally Extended Multi‐Regional Input‐Output Tables , 2018 .

[144]  O. Tatari,et al.  Well-to-wheel water footprints of conventional versus electric vehicles in the United States: A state-based comparative analysis , 2018, Journal of Cleaner Production.

[145]  Jie Zhang,et al.  Expansion of environmental impact assessment for eco-efficiency evaluation of China's economic sectors: An economic input-output based frontier approach. , 2018, The Science of the total environment.

[146]  David Webb,et al.  An Exploration of the Relationship between Improvements in Energy Efficiency and Life-Cycle Energy and Carbon Emissions using the BIRDS Low-Energy Residential Database. , 2018, Energy and buildings.

[147]  He Xu,et al.  Mapping inter-industrial CO2 flows within China , 2018, Renewable and Sustainable Energy Reviews.

[148]  Q. Du,et al.  Club convergence and spatial distribution dynamics of carbon intensity in China’s construction industry , 2018, Natural Hazards.

[149]  Sara Martinez,et al.  The Environmental Footprint of the end-of-life phase of a dam through a hybrid-MRIO analysis , 2018, Building and Environment.

[150]  Chuangzhi Wu,et al.  Life cycle assessment of biofuels in China: Status and challenges , 2018, Renewable and Sustainable Energy Reviews.

[151]  M. Kucukvar,et al.  Material dependence of national energy development plans: The case for Turkey and United Kingdom , 2018, Journal of Cleaner Production.

[152]  Robert Best,et al.  Assessing life cycle impacts and the risk and uncertainty of alternative bus technologies , 2018, Renewable and Sustainable Energy Reviews.

[153]  Manfred Lenzen,et al.  Triple-bottom-line assessment of São Paulo state’s sugarcane production based on a Brazilian multi-regional input-output matrix , 2018 .

[154]  Wan Mohd Sabki Wan Omar,et al.  A hybrid life cycle assessment of embodied energy and carbon emissions from conventional and industrialised building systems in Malaysia , 2018 .

[155]  Xiaoling Zhang,et al.  Carbon emission of global construction sector , 2018 .

[156]  Manfred Lenzen,et al.  The Australian industrial ecology virtual laboratory and multi-scale assessment of buildings and construction , 2018 .

[157]  Anyu Yu,et al.  Estimation of carbon efficiency decomposition in materials and potential material savings for China's construction industry , 2018, Resources Policy.

[158]  Manfred Lenzen,et al.  Hybrid life cycle assessment (LCA) will likely yield more accurate results than process-based LCA , 2018 .

[159]  Yi-Ming Wei,et al.  Shadow prices of direct and overall carbon emissions in China’s construction industry: A parametric directional distance function-based sensitive estimation , 2018, Structural Change and Economic Dynamics.

[160]  Wenjia Cai,et al.  How the transitions in iron and steel and construction material industries impact China’s CO2 emissions: Comprehensive analysis from an inter-sector linked perspective , 2018 .

[161]  D. Yan,et al.  Modelling of energy consumption and carbon emission from the building construction sector in China, a process-based LCA approach , 2019, Energy Policy.

[162]  Murat Kucukvar,et al.  Eco-efficiency of electric vehicles in the United States: A life cycle assessment based principal component analysis , 2019, Journal of Cleaner Production.

[163]  S. Managi,et al.  Energy-carbon performance and its changing trend: An example from China’s construction industry , 2019, Resources, Conservation and Recycling.

[164]  S. T. Ng,et al.  Developing a GHG-based methodological approach to support the sourcing of sustainable construction materials and products , 2019, Resources, Conservation and Recycling.

[165]  O. Tatari,et al.  Assessing regional and global environmental footprints and value added of the largest food producers in the world , 2019, Resources, Conservation and Recycling.

[166]  S. Hsu,et al.  Quantifying city-scale carbon emissions of the construction sector based on multi-regional input-output analysis , 2019, Resources, Conservation and Recycling.

[167]  Yongze Song,et al.  Analyzing the influence factors of the carbon emissions from China's building and construction industry from 2000 to 2015 , 2019, Journal of Cleaner Production.

[168]  Weiguang Cai,et al.  How to set the proper level of carbon tax in the context of Chinese construction sector? A CGE analysis , 2019 .

[169]  Rongyue Zheng,et al.  Uncertainty in the life cycle assessment of building emissions: A comparative case study of stochastic approaches , 2019, Building and Environment.

[170]  Heng Li,et al.  Revealing stylized empirical interactions among construction sector, urbanization, energy consumption, economic growth and CO2 emissions in China. , 2019, The Science of the total environment.

[171]  Liyin Shen,et al.  What makes the difference in construction carbon emissions between China and USA? , 2019, Sustainable Cities and Society.

[172]  Xiaojing Song,et al.  Which Influencing Factors Cause CO2 Emissions Differences in China’s Provincial Construction Industry: Empirical Analysis from a Quantile Regression Model , 2019, Polish Journal of Environmental Studies.

[173]  Zhifeng Yang,et al.  Quantification of urban water-carbon nexus using disaggregated input-output model: A case study in Beijing (China) , 2019, Energy.

[174]  Qiang Du,et al.  Relationship of carbon emissions and economic growth in China's construction industry , 2019, Journal of Cleaner Production.

[175]  Weili Liu,et al.  Investigating interior driving factors and cross-industrial linkages of carbon emission efficiency in China's construction industry: Based on Super-SBM DEA and GVAR model , 2019, Journal of Cleaner Production.

[176]  Murat Kucukvar,et al.  How sustainable is electric mobility? A comprehensive sustainability assessment approach for the case of Qatar , 2019, Applied Energy.

[177]  Jian Zuo,et al.  How to evaluate the efforts on reducing CO2 emissions for megacities? Public building practices in Shenzhen city , 2019, Resources, Conservation and Recycling.

[178]  Murat Kucukvar,et al.  Material footprint of electric vehicles: A multiregional life cycle assessment , 2019, Journal of Cleaner Production.

[179]  Jing Sun,et al.  Factor decomposition of carbon emissions in Chinese megacities. , 2019, Journal of environmental sciences.

[180]  Qiang Du,et al.  Dynamics and scenarios of carbon emissions in China’s construction industry , 2019, Sustainable Cities and Society.

[181]  Charley Z. Huang,et al.  Integrated GHG emissions and emission relationships analysis through a disaggregated ecologically-extended input-output model; A case study for Saskatchewan, Canada , 2019, Renewable and Sustainable Energy Reviews.

[182]  Xiaodong Lai,et al.  A synthesized factor analysis on energy consumption, economy growth, and carbon emission of construction industry in China , 2019, Environmental Science and Pollution Research.

[183]  Liyin Shen,et al.  The environmental Kuznets curve of CO2 emissions in the manufacturing and construction industries: A global empirical analysis , 2019, Environmental Impact Assessment Review.

[184]  S. Pauliuk,et al.  Integrating Dynamic Material Flow Analysis and Computable General Equilibrium Models for Both Mass and Monetary Balances in Prospective Modeling: A Case for the Chinese Building Sector. , 2018, Environmental science & technology.

[185]  Yuanqing Wang,et al.  Life cycle assessment for carbon dioxide emissions from freeway construction in mountainous area: Primary source, cut-off determination of system boundary , 2019, Resources, Conservation and Recycling.

[186]  Yan Zhang,et al.  Medium-to-long-term coupled strategies for energy efficiency and greenhouse gas emissions reduction in Beijing (China) , 2019, Energy Policy.

[187]  A. Borrion,et al.  The significance of measuring embodied carbon dioxide equivalent in water sector infrastructure , 2019, Journal of Cleaner Production.

[188]  Yanan Wang,et al.  Exploring the spatial effect of urbanization on multi-sectoral CO2 emissions in China , 2019, Atmospheric Pollution Research.

[189]  Cui Can,et al.  Life-cycle CO2 Emissions and Their Driving Factors in Construction Sector in China , 2019 .

[190]  Wei Li,et al.  Exploring the driving force and mitigation contribution rate diversity considering new normal pattern as divisions for carbon emissions in Hebei province , 2020 .

[191]  Peter D. Blair,et al.  Input-Output Analysis , 2021 .