A Steel Roadmap for a Low Carbon Europe 2050

A Steel Roadmap for a Low Carbon Europe 2050 IEA Global Industry Dialogue and Expert Review Workshop Paris, 7 October 2013 Dr.-Ing. Jean Theo Ghenda Steel Institute VDEh

Agenda 1. Objectives and Phases of the project 2. Steel s Contribution to a Low Carbon Europe 2050 2.1. Steel industry overview and technology development 2.2. Baselining 2.3. Technology assessment 2.4. Steel and Scrap forecast 2.5. Steels own impact Abatement scenarios for 2050 2.6. Steel as mitigation enabler 3. Steel Roadmap for a Low Carbon Europe 2050 3.1. CO 2 intensity pathways up to 2050 3.2. Challenges for an adequate set of climate policies for steel 3.3. Policy recommendations 2

A Steel Roadmap for a Low Carbon Europe 2050 Objectives of the project Respond to the Commission Roadmap with a sound and credible alternative in order to engage constructively with stakeholders Assess the technical-economical options over the mid and long-term. Knowing what our sector can do and at which cost will enable companies to make informed investment decisions Demonstrate that stack emissions are just one side of the problem: steel is a strategic and sustainable material which will be instrumental in achieving the EU s climate and resource efficiency objectives 3

A Steel Roadmap for a Low Carbon Europe 2050 Project Phases First phase: technical-economical assessment contracted to the Boston Consulting Group in collaboration with the Steel Institute VDEh: Steel s Contribution to a Low Carbon Europe 2050 Second phase: EUROFER Steel roadmap built on BCG/VDEh s findings but scope broadened to options for deeper cuts (HIsarna, Ulcored, electricity and hydrogenbased reduction, ) main challenges of the various options competitiveness issues policy recommendations 4

Agenda 1. Objectives and Phases of the project 2. Steel s Contribution to a Low Carbon Europe 2050 2.1. Steel industry overview and technology development 2.2. Baselining 2.3. Technology assessment 2.4. Steel and Scrap forecast 2.5. Steels own impact Abatement scenarios for 2050 2.6. Steel as mitigation enabler 3. Steel Roadmap for a Low Carbon Europe 2050 3.1. CO 2 intensity pathways up to 2050 3.2. Challenges for an adequate set of climate policies for steel 3.3. Policy recommendations 5

Steel s Contribution to a Low Carbon Europe 2050 Work divided in two workstreams Argumentation logic Content 1 Workstream 1: Baselining and technology assessment Emission baselining Technology profiles Starting point for discussion: What has the steel industry achieved so far? By how much can individual technologies reduce emissions and how much do they cost? Baselining within defined system boundaries Assessment of technologies based on abatement potential, costs, possible time of introduction as well as possible penetration rate 2 Workstream 2: Steel roadmap low carbon Europe 2050 Steel's own impact Steel as mitigation enabler How can emissions be reduced until 2050 considering different technology scenarios? CO 2 balance: What role does steel play in other industries in enabling mitigation? Construction of emission model based on projected steel production and scenarios derived from technology profiles CO 2 balance for selected use cases where only steel as a material is making mitigation possible in other industries

Overview of iron- and steel-making routes BOF steel EAF steel Raw material Integrated route Smelting reduction Direct reduction Scrap Lump ore Fine ore Lump ore Fine ore Lump ore Fine ore Raw material preparation Coal Coke Sinter Pellets Pellets Pellets Scrap Blast furnace Shaft prereduction Fluidized bed Shaft furnace Fluidized bed Iron making Coal, oil or natural gas Scrap Blast O 2 Hot metal Meltergasifier Reducing gas HCI Coal O 2, coal Hot metal Natural gas HBI DRI Natural gas HBI Steel making O 2 O 2 BOF Scrap BOF EAF Scrap EAF Casting Rolling / processing Source: Steel Institute VDEh; WV Stahl; WSA; BCG Liquid steel Liquid steel Liquid steel Liquid steel Crude steel Finished products (flat & long)

Baselining: system boundaries Scope investigated: Primary/secondary steelmaking to hot rolling Scope I direct CO 2 emissions from the following facilities: not included Sintering xx g CO 2 /t Pelletizing xx g CO 2 /t Cokemaking xx g CO 2 /t Ironmaking xx g CO 2 /t BOF Steelmaking xx g CO 2 /t Casting + hot rolling Cold rolling + further processing Scrap EAF xx g CO 2 /t Scope II indirect CO 2 emissions from purchased electricity Scope III indirect CO 2 emissions from purchased materials (produced in EU27): Pellets DRI Pig iron Graphite electrodes Credits for by-product gases 1 System boundaries for base line Oxygen Steam Coke Burnt lime Credits for slag 2 1. The utilization of by-products, such as process gases or waste heat is not counted as a credit, since such use helps to reduce the energy consumption of aggregates. Only byproduct gases that are sold to a second party can be counted as a credit, since they help to reduce emissions of a different sector. 2. Emission factors for BF and BOF to cement industry not finalized yet Source: worldsteel; Project team analysis

Reduction of CO 2 emission from 1990 to 2010 EU27 s specific CO 2 intensity decreased by 15%; EU27 s absolute CO 2 emissions dropped by 25%; Drivers: mainly Volume changes, Shift from BF-BOF to EAF route, efficiency gains, improved CO 2 emission of electric generation (minor effect) Mt CO 2 300 298 BF-BOF production -30 Mt 1990: 131 Mt CS 2010: 101 Mt CS EAF production +16 Mt 1990: 55 Mt CS 2010: 71 Mt CS 200 197.4 Mt 59 8 11 15 3 223 100 BF-BOF efficiency gain -80kg CO 2 /t CS 1990: 1,968 kg CO 2 /t CS 2010: 1,888 kg CO 2 /t CS EAF efficiency gain -212 kg CO 2 /t CS 1990: 667 kg CO 2 /t CS 2010: 455 kg CO 2 /t CS Effect of better indirect emission (electricity) only minor (~10%) 172.8 Mt 0 Total emissions 1990 BF-BOF route volume effect BF-BOF route efficiency gain BF-BOF route EAF route volume effect EAF route EAF route efficiency gain OHF route effect Total emissions 2010 Note: Includes all direct and upstream emissions as well as casting and hot rolling; OHF route volume 1990: 11 M CS = crude steel Source: EUROFER Benchmark 2007/08; VDEh data exchange 1990/2010; Project team analysis

Steel intensity (SI) curves used to forecast finished steel consumption (FSC) per country Use of SI curves accounting for industrial structure of individual countries SI curves calculated for each country by using historical data for FSC in relation to GDP per Capita and population FSC forecasts calculated based on population and GDP forecasts by EIU Plot historical data Steel/GDP (kg/k$) 50 40 Assessed parameter for industry development 2012 2050 Industrialization Share of industrial production of total economy Assumption: No deindustrialization in EU Industry structure Development of steel-intensive industries Assumption: Stable industry structure Steel Intensity curve 30 20 2012-2050 Steel efficiency gains Efficiency gains in steel application Assumption: Certain efficiency gains Assess future industry development 10 Sources: World Steel Association; EIU; BCG analysis. 0 0 Crude steel production 10 20 Finished steel consumption Steel Intensity (SI) curve 30 40 50 60 70 GDP/Capita (k$ PPP)

Methodology to compute crude steel production from finished steel consumption Use Crude steel Production and Finished Steel Production are calculated from Finished Steel Consumption using Self-sufficiency rate and Conversion Rate Assumptions: 1) EU27 Self-sufficiency by 2030 (FSC=FSP); Steel/GDP 2) EU27 Conversion Rate rises to 95% in 2030 and remain constant until 2050 Finished steel consumption 1.5 1.0 0.5 Net exporter Net importer GDP/Capita 2000 2010 2020 2030 2040 2050 2000 2010 2020 2030 2040 2050 EU27 Self sufficiency rate Finished steel production Crude steel production 100% 95% 90% EU27 Conversion rate (yield) 85% 2000 2010 2020 2030 2040 2050 Sources: World Steel Association; EIU; BCG analysis.

Moderate annual crude steel production growth of 0.8% from 2010 until 2050 expected Historically, crude steel production stable in EU15 but declining in Eastern Europe Going forward, slow growth expected for EU27, 2007 production level will be reached in 2032 Mt Mt 250 200 150 210 50 197 43 193 30 210 35 139 173 25 178 26 250 200 150 173 25 178 26 191 0.8% 204 222 236 21 100 50 160 154 163 176 118 148 152 100 50 148 152 0 0 1980 1990 2000 2007 2009 2010 2011 2010 2011 2020e 2030e 2040e 2050e Oth. EU EU15 Oth. EU EU15 EU27 Note: e = estimate. Sources: World Steel Association; BCG analysis.

Scrap availability forecasted to grow by 0.9% annually until 2050, mainly driven by obsolete scrap Scrap availability driven by three scrap types Total available scrap in EU27 (in Mt) New / prompt scrap Production waste and errors in conversion of crude to finished Depending on efficiency of production process Production waste and errors in steel-using sectors Home scrap Depending on industry sector Steel in products at the end of their life cycle Depending on scrap recovery rate and life cycle per sector Obsolete / old scrap Finished steel < cons. per sector Crude steel production Finished steel cons. per sector Recycling rate (%) Scrap rate (%) Scrap rate (%) Life time (y) 150 100 50 0 111 102 94 20 43 18 25 22 19 66 54 41 1990 2005 2007 Home scrap 96 84 18 13 16 13 58 62 2009 2010 New scrap 99 16 17 65 2011 0.9% 113 10 25 77 136 12 26 98 2030e 2050e Obsolete scrap (adj. for trade) Source: BCG analysis.

CO 2 emission projections Technology review Agglomeration Integrated route EAF route Incremental Sinter plant cooler heat recovery Coke dry quenching (CDQ) Injection of H 2 rich reductants 1 Injection of H 2 into shaft Optimization of Pellet ratio to Blast Furnace Top gas recovery turbine (TRT) Waste gas recovery Heat recovery Optimization Substitution Breakthrough Corex Finex HIsarna Midrex / HyL based on natural gas Finmet / Ulcored based on natural gas + fine ores Synergies between different technologies 2 Top gas recovery (TGR) Combination of technologies with CCS 3 1. Includes the potential use of coke oven gas as reductant 2. E.g., use of coke oven gas for DR, BF+Corex/Finex+DR, use of Corex/Finex gas for DR 3. BF: CCS after power plant, TGR with CCS, Corex/Finex with CCS, HIsarna with CCS EAF: gas based DR with CCS, Ulcored with CCS

CO 2 emission projections Economic feasibility assessment of the technologies Likely outcomes analyzed using 2-step logic: 1. Determination of economic feasibility under different price scenarios. 2. Gradual implementation of the economically feasible technologies on the basis of varying adaptation curves for different scenarios Economic feasibility was computed by comparing costs (CAPEX et OPEX) with the potential savings over considered investment period, depending on different price scenarios The price scenarios included a reference-price scenario (inflation only), medium-price scenario (doubling of real input factor costs) and highprice scenario (fivefold increase of input factor costs)

BF-TGR (top gas recycling) Coke Top gas (CO, CO2, H2, N2) Gas cleaning Gas net (N2 purge) CO 2 scrubber CO 400 2 Nm3 /t Oxygen PCI CO, H2, N2 Gas heater Re-injection Ulcos-BF concept: V4 V3 V1 -Retro-fit to existing BF -Lower 900 coke C consumption X 900 C -Higher productivity -But a lot of technical challenges to overcome 1250 C 1250 C 25 C Expected C-savings 25 % 24 % 21 %

Comparison of the Operating Expenses (OPEX) of Alternative Steelmaking Technologies Source: BCG/VDEh OPEX BF-BOF Smelting reduction 2 Scrap-EAF DRI-EAF 2010 100 103 Costs are normalized to BF-BOF = 100 114 133 BF-BOF DRI-EAF Smelting reduction Scrap-EAF +33% +3% +14% OPEX 2010 ( / t CS) 429 24% 572 13% 440 18% 489 12% 76% 87% 82% 88% Sources: Steel Institute VDEh; project team analysis. Note: CS = crude steel 1. Based on Midrex direct reduction technology. 2. Based on Finex smelting reduction technology Other OPEX OPEX - input factor costs

Comparison of Capital Expenditures (CAPEX) for Alternative steelmaking technologies Source: BCG/VDEh CAPEX BF-BOF retrofit Scrap-EAF Smelting reduction DRI-EAF BF-BOF greenfield 2010 100 108 231 242 259 Cost are normalized BF-BOF retrofit = 100 Scrap-EAF BF-BOF retrofit DRI-EAF Smelting reduction BF-BOF greenfield CAPEX 2010 ( / t CS) 184 +8% +143% +131% 414 393 184 128 171 64 1 230 265 74 15 3 2 17 4 441 128 149 51 114 EAF DRI BOF Corex/Finex BF Sinter plant Coke plant 1. BOF: 50% of Greenfield investment 2. BF: 50% of Greenfield investment 3. Sinter: 30% of Greenfield investment 4. Coke: 15% of Greenfield investment Note: CS = crude steel Sources: Steel Institue VDEh; Project team analysis

Absolute CO 2 emissions in 2050 only 56% lower than 1990 s if CCS fully implemented in 2050 Mt CO 2 Abatement cost of moving from existing BF-BOF to DRI-EAF: 260 to 700 /tco 2-80% compared to 1990 350 300 250 200 150 100 50 0 Crude steel production [Mt crude steel] 298 1990 197.4 180 223 264 249 239 213 305 271 258 184 ~130 2009 1 2010 2030 2050 139.3 172.8 204 236 A -9% B -38% C D -56% Upper boundary A Crude steel production forecast & CO 2 intensity on 2010 level B Increased EAF-share on the basis of scrap availability & best-practice sharing Economic scenarios Lower theoretical boundary without CCS C 44% Scrap-EAF, 45% DRI- EAF, 11% BF-BOF; increased improvements, especially for BF-BOF Lower theoretical boundary with CCS Specific CO 2 intensity [kg CO 2 / t crude steel] 1,508 1,293 Sources: EUROFER Benchmark 2007/2008; VDEh data exchange 1990/2010; Project team analysis. 1. 2009 crude-steel production with 2010 CO 2 intensity and 2010 Scrap-EAF share. A 1,219 1,145 B 1,046 778 C ~550 D D 44% Scrap-EAF, 56% BF- BOF+TGR, DRI-EAF, or SR-BOF Economically viable Not economically viable

Abatement potential up to 2050 Abatement potential compared to 2010 (intensity) Reference year 2010 (specific emissions) 2030 2050 Economic scenario -9% -15% Maximum theoretical abatement without CCS -19% -40% Maximum theoretical abatement with CCS -9% -57% Commission Roadmap for a Competitive Low Carbon Economy 2050 (table 9, source: PRIMES, GAINS) Reference year 2005 (absolute emissions) 2030 2050 Overall -35% to -40% -77% to -81% ETS -43% to -48% -88% to -92% non-ets -24% to -36% -66% to -71% 20

Steel as a mitigation enabler Innovative steel-based emission-saving applications may help reduce CO 2 emissions Only saving that are 100% attributable to steel are taken into account Stringent 4-step logic applied to isolate the case studies for evaluating steel s own mitigation potential Initial list Weight reduction-cars Onshore/offsho re wind power Leaf springs Rubberenforcing steel structures for tires Motor systems Assembled camshafts CCS Structural steel < 1 Geography Focus on EU-27 Nuclear power plants Solar power 2 Relevant potential by 2030 Inland water transport CCS Potential impact vs. 2010 3 Substitution of materials No comparative examination of alternatives Bridges Onshore wind mills 4 Absolute potential Rail Jet engines Cases with abatement 5 MtCO 2 / year 8 case studies with distinct potential Sources: VDEh; BCG analysis.

Case studies for EU27 result in annual CO 2 savings of about 440 Mt while emitting only 70 Mt of extra CO 2 Case study Net CO 2 reduction Emissions in the Ratio between CO 2 potential 2 steel production reduction / emission 1 Efficient fossil fuel PPs 103.0 0.7 ~ 155:1 2 Offshore wind power 69.7 3.0 ~ 23:1 Energy industry 3 Other renewables 1 22.2 0.16 ~ 148:1 4 Efficient transformers 19.6 1.2 ~ 17:1 5 Efficient e-motors 6.9 3.2 ~ 2:1 Traffic Household / industry 6 7 8 Weight reduction cars Weight reduction trucks Combined heat / power 0 6.3 50 49.6 165.9 100 200 Mt CO 2 / yr. 0 42.1 14.0 5.3 5 10 45 Mt CO 2 / yr. ~ 4:1 < 1 ~ 9:1 ~ 443 ~70 ~ 6:1 1. Bioenergy. 2. Net reduction refers to reduction attributable to steel. Note: PP = power plant Source: BCG analysis

Agenda 1. Objectives and Phases of the project 2. Steel s Contribution to a Low Carbon Europe 2050 2.1. Steel industry overview and technology development 2.2. Baselining 2.3. Technology assessment 2.4. Steel and Scrap forecast 2.5. Steels own impact Abatement scenarios for 2050 2.6. Steel as mitigation enabler 3. Steel Roadmap for a Low Carbon Europe 2050 3.1. CO 2 intensity pathways up to 2050 3.2. An adequate set of climate policies for steel 3.3. Policy recommendations 23

Steel Roadmap for a Low Carbon Europe Base on findings of the BCG/VDEh study Broader scope: options for deeper cuts (HIsarna, Ulcored, electricity and hydrogen-based reduction, ) deeper look into CCS main challenges of the various options competitiveness issues policy recommendations (role of the ETS) Steel Low C Roadmap published in July 2013 but the work doesn t stop there. 24

25 CO 2 intensity pathways up to 2050 What?

26 CO 2 intensity pathways up to 2050 How?

27 CO 2 intensity pathways up to 2050 Conditions for success

What? economic CO2 reduction potential How? continued decarbonisation of the power sector increased scrap availability best practice sharing implementation of cost-effective incremental technologies Conditions for success access to scrap and energy at competitive prices incentives through e.g. sectoral energy efficiency programmes full offset of distortive CO 2 costs until levelplaying field is restored maximum theoretical abatement without CCS: -40% partial shift from BF-BOF to DRI- EAF NG and electricity prices such that natural gas-based DRI becomes competitive in Europe + maximum theoretical abatement with CCS: -57% hypothetic breakthrough technologies in combination with CCS use of BF-TGR technology in combination with CCS BF-TGR, ULCORED/HIsarna CCS on all emission sources electricification of heating hydrogen-based reduction electrolysis, support for demonstration and deployment of BF-TGR, access to CCS widespread at competitive prices support for R&D, demonstration and deployment of breakthrough technologies + +

An adequate set of climate policies for steel What s wrong with the projected policy framework The CO 2 reduction potential in the EU steel industry estimated to be about 10% between 2010 and 2030 (specific emissions). Steel will not be able to come anywhere near the interim reduction objectives suggested in the Commission Low Carbon Roadmap of 43-48% for the ETS sector between 2005 and 2030. Going beyond the 10% mark would require having recourse to yet unproven technologies, as well from a technical point of view as in terms of costeffectiveness. These technologies need further research and funding for pilot and demonstration tests. Their implementation will be costly, not only because of the investments involved but also because of the higher operating costs stemming a.o. from the use of CCS and the problems stemming from it. In a long-term perspective, the EU ETS carbon price signal alone will not to put steelmaking breakthrough technologies on-stream. Breakthrough technologies can only be put on-stream via adequate funding in R&D, pilot, demonstration and deployment. 29

An adequate set of climate policies for steel Policy recommendations The 2030 Climate and Energy Framework has therefore to acknowledge that steel cannot move at the same pace than other sectors. Leading principles for the 2030 policy framework: Policies have to make industry more competitive by securing globally competitive energy prices (NG, electricity) instead of increasing (carbon) costs. Emission reduction pathways for the steel industry have to be built bottom-up, based on the technical and economic abatement potentials of the sectors (sectoral approaches). Climate goals should be dependent upon comparable reduction effort by other major economies. In the context of cap and trade, best performers need 100% of their allowances for free (no correction factor should apply) and their indirect CO 2 costs must be fully and consistently offset through a truly effective EU mechanism (based on realistic benchmarks) at least until international distortions to competition are removed. The continuation and generalization of exemptions from energy taxation, levies and tariffs stemming from support for renewables and other climate-related initiatives (CCS). Funding in research, demonstration and deployment of potential new technologies is therefore key to success. In this regard, ambitious climate objectives require public funding commitment that is consistent with the level of effort envisaged. 30

Thank you 31