1 |
Biomass-based gas use in Swedish iron and steel industry - Supply chain and process integration considerations Nwachukwu CM, Toffolo A, Wetterlund E Renewable Energy, 146, 2797, 2020 |
2 |
GIS-based techno-economic optimisation of a regional supply chain for large-scale deployment of bio-SNG in a natural gas network Singlitico A, Kilgallon I, Goggins J, Monaghan RFD Applied Energy, 250, 1036, 2019 |
3 |
Techno-economic assessment of natural gas displacement potential of biomethane: A case study on domestic energy supply in the UK Fubara T, Cecelja F, Yang AD Chemical Engineering Research & Design, 131, 193, 2018 |
4 |
Thermodynamic modelling and energy balance of direct methanation of glycerol for Bio-SNG production White R, Dupont V, Cockerill T Energy Conversion and Management, 160, 354, 2018 |
5 |
Value chains for integrated production of liquefied bio-SNG at sawmill sites - Techno-economic and carbon footprint evaluation Ahlstrom JM, Pettersson K, Wetterlund E, Harvey S Applied Energy, 206, 1590, 2017 |
6 |
Renewable methan - A technology evaluation by multi-criteria decision making from a European perspective Billig E, Thraen D Energy, 139, 468, 2017 |
7 |
Improved syngas processing for enhanced Bio-SNG production: A techno-economic assessment Haro P, Johnsson F, Thunman H Energy, 101, 380, 2016 |
8 |
Evaluation of biomethane technologies in Europe - Technical concepts under the scope of a Delphi-Survey embedded in a multi-criteria analysis Billig E, Thran D Energy, 114, 1176, 2016 |
9 |
Investigation of cryogenic technique for synthetic natural gas upgrading Birgen C, Jarque SG International Journal of Hydrogen Energy, 40(34), 11161, 2015 |
10 |
Comparison of energy efficiency assessment process methods: Case Bio-SNG process Kohl T, Laukkanen T, Tuomaala M, Niskanen T, Siitonen S, Jarvinen MP, Ahtila P Energy, 74, 88, 2014 |