| 1 |
Parametric design to minimize the embodied GHG emissions in a ZEB
Lobaccaro G, Wiberg AH, Ceci G, Manni M, Lolli N, Berardi U
Energy and Buildings, 167, 106, 2018 |
| 2 |
The Australian industrial ecology virtual laboratory and multi-scale assessment of buildings and construction
Baynes TM, Crawford RH, Schinabeck J, Bontinck PA, Stephan A, Wiedmann T, Lenzen M, Kenway S, Yu M, Teh SH, Lane J, Geschke A, Fry J, Chen GW
Energy and Buildings, 164, 14, 2018 |
| 3 |
An exploration of the relationship between improvements in energy efficiency and life-cycle energy and carbon emissions using the BIRDS low-energy residential database
Kneifel J, O'Rear E, Webb D, O'Fallon C
Energy and Buildings, 160, 19, 2018 |
| 4 |
Abatement cost of embodied emissions of a residential building in Sweden
Andersson M, Barkander J, Kono J, Ostermeyer Y
Energy and Buildings, 158, 595, 2018 |
| 5 |
Is a net life cycle balance for energy and materials achievable for a zero emission single-family building in Norway?
Kristjansdottir TF, Houlihan-Wiberg A, Andresen I, Georges L, Heeren N, Good CS, Brattebo H
Energy and Buildings, 168, 457, 2018 |
| 6 |
A Quasi-Input-Output model to improve the estimation of emission factors for purchased electricity from interconnected grids
Qu S, Wang HX, Liang S, Shapiro AM, Suh SW, Sheldon S, Zik O, Fang H, Xu M
Applied Energy, 200, 249, 2017 |
| 7 |
The CO2 Content of Consumption Across US Regions: A Multi-Regional Input-Output (MRIO) Approach
Caron J, Metcalf GE, Reilly J
Energy Journal, 38(1), 1, 2017 |
| 8 |
Estimating the complete CO2 emissions and the carbon intensity in India: From the carbon transfer perspective
Sun CW, Ding D, Yang M
Energy Policy, 109, 418, 2017 |
| 9 |
Ecological network analysis of embodied particulate matter 2.5-A case study of Beijing
Yang SY, Fath B, Chen B
Applied Energy, 184, 882, 2016 |
| 10 |
Consumption-based emission accounting for Chinese cities
Mi ZF, Zhang YK, Guan DB, Shan YL, Liu Z, Cong RG, Yuan XC, Wei YM
Applied Energy, 184, 1073, 2016 |
