Energy infrastructures for low-carbon-emitting industries
Doktorsavhandling, 2024
The results confirm that reducing permitting times and expanding the capacity to build up grid infrastructure in parallel with the electrification technology are crucial measures to meet climate targets. Poor conditions for electrification, in terms of long permitting times and low grid expansion capacity, may delay the electrification of Swedish industry by up to 15 years.
In the studied system, the costs for CO2 separation and liquefaction make up ~65% of the costs for CO2 capture and transport systems (albeit excluding the cost for final storage), rendering the mitigation option sensitive to CO2 capture investments and technology performance. As CO2 capture gives a high added cost for industrial operators, implementation is highly dependent upon incentives, and the modeled deployment in different sectors is sensitive to the incentive scheme applied. For example, carbon pricing mechanisms for fossil CO2 and mechanisms that motivate capture of biogenic CO2 result in different sectors targeted for capture when implemented in conjunction as opposed to separately. This highlights the importance of clear, long-term policies to create incentives for site operators to invest in mitigation technologies.
Future industrial biomass demands are likely to exceed the logging residue supply potential on a national level, and even more so in high-demand regions. The cost of logging residue supply is highly sensitive to the transport distance when utilizing current transportation modes. However, cost-effective long-distance transportation chains can connect high-demand and high-supply regions at relatively low cost increases compared to supplying logging residues regionally.
carbon capture and storage
supply chains
electrification
decarbonization
carbon dioxide removal
biomass use
Industry
transition
infrastructure
Författare
Sebastian Karlsson
Chalmers, Rymd-, geo- och miljövetenskap, Energiteknik
Cost-optimal CO<inf>2</inf> capture and transport infrastructure—A case study of Sweden
International Journal of Greenhouse Gas Control,;Vol. 132(2024)
Artikel i vetenskaplig tidskrift
Modeling the development of a carbon capture and transportation infrastructure for Swedish industry
International Journal of Greenhouse Gas Control,;Vol. 124(2023)
Artikel i vetenskaplig tidskrift
Large-Scale Implementation of Bioenergy With Carbon Capture and Storage in the Swedish Pulp and Paper Industry Involving Biomass Supply at the Regional Level
Frontiers in Energy Research,;Vol. 9(2021)
Artikel i vetenskaplig tidskrift
Karlsson, S; Eriksson, A; Fernandez-Lacruz, R; Beiron, J; Normann, F; Johnsson, F. Supply potential and cost of residual forest biomass for new industrial applications in Sweden
Karlsson, S; Beiron, J; Normann, F; Johnsson, F. The roles of permitting times and grid expansion capacity in industrial decarbonization – A case study of the electrification of Swedish industry
Ämneskategorier
Energiteknik
Energisystem
ISBN
978-91-8103-113-3
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5571
Utgivare
Chalmers
SB-H1, Samhällsbyggnad I-II, Sven Hultins Gata 6
Opponent: François Maréchal, EPFL, Switzerland