On an industrial test site near the northeastern French city of Metz, a machine the size of a small two-storey house is producing iron plates. With this process, Europe is taking a key step in fighting climate change.

What is taking place is steel production through electrolysis, a new method that avoids heavy-polluting coal and reduces emissions of greenhouse gases including CO2. Using these new technologies, steel companies are hoping to decarbonise their own industry.

Pilot plant

The French pilot plant of Luxembourg-based ArcelorMittal, the world’s second-largest steel producer, emerged through the EU-funded SIDERWIN project, which ended this past March after more than five years.

While modest in the grand scheme of things, producing a tiny fraction of the steel volumes of a normal plant, the pilot site has big expectations riding on it.

"During 2025 and 2025, we will develop our first small industrial plant," says Valentine Weber-Zollinger, an ArcelorMittal engineer who coordinated SIDERWIN. "Our ambition is to have this pilot plant in operation in 2027. After that, we need to increase the size to that of a full-scale steel mill, which would happen by 2030."

Industrial emissions including from steel production contribute significantly to global warming worldwide and in Europe.

Crucial for everything from cars and fridges to bridges and railways, steel is responsible for about 7% of global and 5% of European CO2 emissions. By comparison, aviation accounts for about 2.5% of worldwide CO2.

Steel manufacturers have been in the sights of European climate legislators since 2005, when the EU began capping greenhouse gases from factories as well as power plants through the world’s biggest emissions-trading system, or ETS.

Since then, emitters under the ETS have faced steadily tighter annual caps as the EU pursues climate-neutrality by 2050. The stricter regulation has, in turn, prompted steel manufacturers in Europe to step up the hunt for greener production methods.

Clout and climate

In Europe, the sector has annual turnover of about €125bn and employs more than 300,000 people, according to industry association Eurofer.

Europe’s steel industry also has political importance rooted in the 1951 European Coal and Steel Community. The ECSC marked a first step towards European integration after the Second World War.

 

'It’s crucial that we decarbonise the sector as fast as possible.' Richard Porter, C4U

European climate ambitions along with the steel industry’s economic and political weight in Europe led the EU this year to approve an unprecedented trade-policy plan known as the Carbon Border Adjustment Mechanism, or CBAM. It will impose a levy on EU imports of goods including steel if they come from countries where manufacturers are spared the climate-protection costs faced by producers in the ETS.

"Steel production is one of the most energy-intensive industrial processes in existence," says Richard Porter, senior research associate at the University College London. "It produces a lot of CO2 emissions, so it’s crucial that we decarbonise the sector as fast as possible."

Dirty work

Steel production emits CO2 chiefly in three ways. In a typical steel plant, coal is used to produce coke, which in turn is a main energy source in blast furnaces.

Coke is also used as a so-called reducing agent. In this role, coke is burnt together with iron and creates a chemical process in which oxygen is removed from the iron ore and produces molten iron that is eventually used to make steel.

On top of that, a steelworks uses a lot of electricity, most of which is generated on site but for now still comes from CO2-producing sources. Nevertheless, the primary emissions source in steel making is the use of coal.

So far, the EU steel industry has focused its decarbonisation strategy mainly on hydrogen-based possibilities, according to the European Commission’s Joint Research Centre. 

ArcelorMittal's pilot plant in France uses electrolysis to produce iron plates. Image: ©SIDERWIN.

For example, Sweden-based H2 Green Steel plans to use a plant in the northern part of the country to produce the metal with green hydrogen – powered by fossil-free electricity – rather than with coal. The expectation is that CO2 emissions could be reduced by as much as 95% compared with traditional steel making.

Carbon capture

Other options include not just electrolysis but also so-called carbon capture, which is the focus of the work by Porter.

"We want to capture the majority of the CO2 from a steelworks," he says. "We target the gases that contain CO2 and use chemical processes to capture it."

Porter is part of the EU-funded C4U project, which is developing this technology. Running for four years through March 2024, the project aims to test the research in steelworks in Belgium, Spain and Sweden.

If the system works and manages to scale, it would make a big difference. C4U aims for full commercial implementation in 2030.

"Our aim is to capture and mitigate about 90% of the emissions of a steelworks," says Porter.

The captured CO2 would then be either stored – for example in depleted oil and natural gas fields under the sea – or used in other industrial processes, such as cement production, where the carbon isn't re-emitted.

Carbon-capture technology, however, has its fair share of critics because it doesn't require a fundamental rethink of how to make steel in the way that, for example, electrolysis does. Producers can simply pursue business as usual, equipping factories with carbon-capture equipment and prolonging dirty production.

Porter is aware of these critiques.

"Hopefully carbon capture can be a stepping stone to different types of steel production," he says.

Retrofitting steelworks with carbon-capture technology can reduce CO2 emissions as a stopgap measure while fundamentally cleaner forms of steel production are introduced.

Current reactions

That is where SIDERWIN’s activity enters the picture. Instead of coal being used as a reducing agent, electricity would do this job.

 

'Our approach will allow us to drastically reduce CO2.' Jean-Paul Allemand, SIDERWIN

"There are two electrodes that we submerge in a fluid called an electrolyte," says Weber-Zollinger of ArcelorMittal. "When you add current, it will create a reaction that can separate iron from the oxygen in the iron mineral source."

Using electrolysis in this way would reduce the bulk of CO2 emissions from steel production. The question is whether the process can be scaled up.

The project participants built a pilot plant to find out.

In a previous project, ArcelorMittal had already constructed a pilot plant that could produce a plate of about three to four kilograms of iron, which can eventually be transformed into steel. The new system produces plates of about one square metre that weigh between 20kg and 50kg.

"Our approach will allow us to drastically reduce CO2," says Jean-Paul Allemand, research centre manager of ArcelorMittal. "But there will still be remaining emissions that we will need to capture."

All of which means research in this whole area in Europe will remain active on numerous fronts.

"We need to get a move on – both with the deployment of carbon capture as with new production methods," says Porter of C4U. "There are a lot of pilots and exciting developments. But more is needed."