| 1 |
Quantifying energy symbiosis of building-integrated agriculture in a mediterranean rooftop greenhouse
Munoz-Liesa J, Royapoor M, Lopez-Capel E, Cuerva E, Rufi-Salis M, Gasso-Domingo S, Josa A
Renewable Energy, 156, 696, 2020 |
| 2 |
Technical evaluation of post-combustion CO2 capture and hydrogen production industrial symbiosis
Ghayur A, Verheyen TV
International Journal of Hydrogen Energy, 43(30), 13852, 2018 |
| 3 |
Exergy Life Cycle Assessment of electricity production from Waste-to-Energy technology: A Hybrid Input-Output approach
Rocco MV, Di Lucchio A, Colombo E
Applied Energy, 194, 832, 2017 |
| 4 |
The role of utilities in developing low carbon, electric megacities
Kennedy C, Stewart ID, Facchini A, Mele R
Energy Policy, 106, 122, 2017 |
| 5 |
An optimization-based cooperative game approach for systematic allocation of costs and benefits in interplant process integration
Tan RR, Andiappan V, Wan YK, Ng RTL, Ng DKS
Chemical Engineering Research & Design, 106, 43, 2016 |
| 6 |
Quantitative tools for cultivating symbiosis in industrial parks
Kastner CA, Lau R, Kraft M
Applied Energy, 155, 599, 2015 |
| 7 |
"Wealth from metal waste": Translating global knowledge on industrial ecology to metals recycling in Australia
Corder GD, Golev A, Giurco D
Minerals Engineering, 76, 2, 2015 |
| 8 |
Life cycle analysis of a biogas-centred integrated dairy farm-greenhouse system in British Columbia
Zhang SD, Bi XT, Clift R
Process Safety and Environmental Protection, 93, 18, 2015 |
| 9 |
Design of robust water exchange networks for eco-industrial symbiosis
Aviso KB
Process Safety and Environmental Protection, 92(2), 160, 2014 |
| 10 |
A systematic methodology for the environomic design and synthesis of energy systems combining process integration, Life Cycle Assessment and industrial ecology
Gerber L, Fazlollahi S, Marechal F
Computers & Chemical Engineering, 59, 2, 2013 |
