Based on Larson ED, Li Z, & Williams RH (2012) Chapter 12-fossil energy. In Global Energy Assessment-Toward a
Sustainable Future. Cambridge University press, Cambridge, UK and New York, NY, USA and the
International Institute for Applied Systems Analysis, Laxenburg, Austria, pp. 901-992 (p.941)
c_storage_BtL.xlsx
Includes also mass-balance calculations for SNG, electrofuel (FT), methanation (H2-based) and anaerobic digestion
Add also extra investment cost (high uncertainty: Daioglou, V., Rose, S.K., Bauer, N. et al. Bioenergy technologies in long-run climate change mitigation: results from the EMF-33 study. Climatic Change 163, 1603–1620 (2020). https://doi.org/10.1007/s10584-020-02799-y)
Based on Larson ED, Li Z, & Williams RH (2012) Chapter 12-fossil energy. In Global Energy Assessment-Toward a Sustainable Future. Cambridge University press, Cambridge, UK and New York, NY, USA and the International Institute for Applied Systems Analysis, Laxenburg, Austria, pp. 901-992 (p.941)
GEA_Chapter12_fossils_lowres.pdf
tCO2/MWh_in | 0,206407 stored | 0,030224 vented $_2007/MW_out: 2.6M
c_storage_BtL.xlsx Includes also mass-balance calculations for SNG, electrofuel (FT), methanation (H2-based) and anaerobic digestion
Add also extra investment cost (high uncertainty: Daioglou, V., Rose, S.K., Bauer, N. et al. Bioenergy technologies in long-run climate change mitigation: results from the EMF-33 study. Climatic Change 163, 1603–1620 (2020). https://doi.org/10.1007/s10584-020-02799-y)