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A climate neutral Swedish industry: An inventory of technologies
IVL Swedish Environmental Research Institute.
IVL Swedish Environmental Research Institute.
IVL Swedish Environmental Research Institute.
Luleå University of Technology, Department of Engineering Sciences and Mathematics, Energy Science.ORCID iD: 0000-0002-0385-8139
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2019 (English)Report (Other (popular science, discussion, etc.))
Abstract [sv]

År 2017 kom utsläppen av växthusgaser i Sverige till cirka 27 procent från industrierna, vilket motsvarar 17 203 tusen ton koldioxidekvivalenter. De fyra industrisektorerna med den största klimatgasutsläpp i Sverige är järn och stål, cement, raffinaderier och kemi. Denna rapport fokuserar på dessa fyra sektorer som tillsammans släpper ut 80 % av de industriella utsläppen av växthusgaser i Sverige. Var och en av dessa sektorer har flera möjliga vägar för att bli klimatneutrala. Beskrivning och diskussion av dessa vägar är fokus för denna rapport.

Med bakgrund av klimatutmaningen är slutsatsen att det inte är möjligt att nå tillräckligt långt enbart med effektivisering av nuvarande industriprocesserna. Eftersom en stor del av utsläppen inte härstammar från energianvändning utan från processerna i sig samt användningen av fossil råvara, finns det behov av transformativa förändringar som nya processer och användning av nytt råmaterial. Många av alternativen är tekniskt omogna och det är många års utveckling kvar innan de kunde implementeras i stor skala.

Förutom de tekniska utmaningarna finns det ytterligare hinder för transformationen. Till exempel tillgång och pris på råvaror, osäker marknad för nya produkter och även juridiska hinder i viss mån. Dessutom kräver några av alternativen utveckling av infrastruktur. Till exempel kräver elektrifiering av stål- och cementproduktion förstärkning av elnätet och ökad produktion av förnybar el.

Vissa av de tekniska alternativen kommer inte att vara färdiga för fullskalig implementering på många år, ibland till och med årtionden. Men klimatutmaningen behöver hanteras snabbare än så. Därför det viktigt att även beakta möjliga övergångsteknologier. Dessa kanske inte reducerar hela utsläppet men utgör ändå en viktig pusselbit. Behovet av koldioxidinfångning och lagring eller användning (CCS/CCU) är oundvikligt under övergångsfasen, men också i ett framtida scenario där all transformation är genomförd. Särskilt som det inte är möjligt att producera klimatneutralt cement utan CCS/CCU. CCU är dock inte en varaktig lagring utan snarare ett sätt att flytta utsläppen till ett annat ställe. Det kan dock delvis ersätta användning av fossil råvara och därmed bidra till minskning av nya fossila växthusgasutsläpp.
Abstract [en]

In year 2017, about 27 percent of the greenhouse gas emissions in Sweden originated from the industries. This equals to 17,203 thousand tonnes carbon dioxide equivalents. Within the Swedish industry, the four industrial sectors with the largest climate gas release are Iron and steel, Cement, Refineries and Chemicals. This report focuses on these four sectors which together emit 80 % of the industrial greenhouse gas emissions in Sweden. Each of these sectors have several possible pathways to become climate neutral. In this report some possible pathways are described and discussed.

In order to reach climate neutrality, transformative changes such as new processes and use of new raw material are needed. This is because a vast part of the emissions in all the sectors in question originates from the processes themselves or the use of fossil feedstock, not only from energy use. Many of the options are technically immature and there are many years of development left before they could be implemented in large scale.

Several technical challenges exist which are related to the processes, but in addition, there are several barriers of non-technical nature for the transformation. For example, supply and price of raw materials, uncertain market for new products and even some legal barriers. Furthermore, some of the options require development of infrastructure, for example the electrification of steel and cement production demands strengthening of the electric grids and increased production of renewable electricity.

Some of the technical options will not be ready for full-scale implementation in many years, even decades. But the climate challenge needs to be tackled quickly. Therefore, an aspect to consider is the demand for additional CO2 reduction technologies during a transition phase. These technical options may not reduce all the emissions but still make an important contribution. Carbon capture and storage or usage (CCS/CCU) is inevitable during the transition phase, but also in a future scenario where all the new technologies are implemented. In particular, this applies to the cement industry since it will not be possible to produce climate neutral cement without CCS/CCU. It should be noted that CCU does no remove the CO2 but transfers it elsewhere. However, it could partly reduce the climate impact from the use of new fossil resources.
Place, publisher, year, edition, pages
Stockholm: IVL Swedish Environmental Research Institute , 2019. , p. 52
Series
IVL rapport ; B 2367
National Category
Energy Engineering
Research subject
Energy Engineering
Identifiers
URN: urn:nbn:se:ltu:diva-76866OAI: oai:DiVA.org:ltu-76866DiVA, id: diva2:1373203
Funder
Swedish Energy Agency, 44678-1
Note

ISBN för värdpublikation: 978-91-7883-131-9

Available from: 2019-11-26 Created: 2019-11-26 Last updated: 2025-10-22Bibliographically approved
In thesis
1. Capturing Swedish Industry Transition towards Carbon Neutrality in a National Energy System Model
Open this publication in new window or tab >>Capturing Swedish Industry Transition towards Carbon Neutrality in a National Energy System Model
2020 (English)Licentiate thesis, comprehensive summary (Other academic)
Abstract [en]

Industry is responsible for approximately 30 % of the total emissions of greenhouse gases, both globally and in Sweden. Given the climate targets set out in the Paris agreement, the industry is facing a challenging future, requiring effective policies to aid the transition. Energy system optimisation models are commonly used for analysing the impact from different policies and for assessing the transition to a climate-neutral energy system. In the past, the primary focus of the models has been on the stationary energy sector, and less on the industry. This thesis work, therefore, aims to improve energy system optimisation models as a tool for decision support and policy analysis about the industry. An improved modelling structure of the industry sector is developed and a wide range of future technology options that can support the transition to a climate-neutral industry is identified. The improved model is then applied in different scenario analysis, assessing how the Swedish industry can meet net-zero CO2-emission under resource limitations.

The methodology applied is energy system analysis with a focus on the process of modelling, an iterative process of i) model conceptualisation, ii) model computation and iii) model result interpretation. Two different models for the evaluation of the Swedish industry are developed and used; a TIMES based model (cost-minimisation) and a small linear optimisation model (resource optimisation).

An outcome from developing the model structure was that the following important aspects need to be represented in the model to capture the transition to a climate-neutral industry sector; i) synergies between different types of industrial processes, ii) setup of process chains based on important tradeable materials, iii) detailed technology representation. When identifying and analysing future technologies, it was concluded that there are plenty of technology options for Swedish industry to become fossil-free. Technology options were identified that enable all studied site categories (representing approximately 92 % of the CO2 emissions from Swedish industry in 2015) to reach net-zero CO2-emissions via either electrification (direct electric heating or via power to gas) or biofuels usage. CCS options were implemented for iron and steel industry, chemical industry, cement- and limestone industry and aluminium industry, and for most of the industrial energy conversion technologies. Although technology options for deep reductions in CO2 emissions exist, many of them require further development to enable full-scale implementation, as concluded in paper III.

The scenario analysis performed in paper I and paper II gives insights into key resources and technologies enabling the industry to reach net-zero CO2 emissions. About resources, biomass is seemingly the most cost-efficient option for reaching ambitious climate targets, e.g. according to the findings in paper II biomass is consistently preferred over electrified alternatives. However, the availability of biomass is limited, and increased electrification of technologies is unavoidable to achieve sustainable use of it (as seen in paper I and paper II). Finally, there is not one key enabling technology but rather key groups of enabling technologies that create cross-technology synergies, providing different benefits depending on resource availability and the overall needs of the system in different scenarios.
Place, publisher, year, edition, pages
Luleå University of Technology, 2020. p. 53
Series
Licentiate thesis / Luleå University of Technology, ISSN 1402-1757
National Category
Energy Systems Energy Engineering
Research subject
Energy Engineering
Identifiers
urn:nbn:se:ltu:diva-76868 (URN)978-91-7790-508-0 (ISBN)978-91-7790-509-7 (ISBN)
Presentation
2020-02-12, E632, Luleå tekniska universitet, Luleå, 09:30 (English)
Opponent
Supervisors
Available from: 2019-11-27 Created: 2019-11-26 Last updated: 2025-10-22Bibliographically approved

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Sandberg, ErikKrook-Riekkola, Anna

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