Making sustainability measurable
The main purpose of EPDs is to provide comparable and reliable data for evaluating the environmental impact of construction projects, so it makes sense that EPDs are currently offered primarily for construction end products. They are a recognized means of documenting and demonstrating the environmental footprint of construction products, giving manufacturers a way of providing key data for calculating the life-cycle assessments of buildings and so evaluating the environmental benefits of construction products in the context of a specific building on the basis of scientific criteria.
In recent times, however another aspect has come to the attention of building material manufacturers: value chain optimization. Published EPDs contain only results that are highly aggregated. When they are prepared, it is often the first time that many companies realize what a dominant influence manufacturing processes and the raw materials used can have on the environmental footprints of their own products. In this context, the raw materials are vital levers for improving their environmental profile.
It is hugely beneficial here if the purchased raw materials also come with their own EPD. Not only does this make the accuracy of the results much greater, it also means that the data consolidated in the information modules is often much more up-to-date than generic data and, for this reason alone, shows a reduced environmental footprint. Last but not least, product-specific EPDs for raw materials are the only way of demonstrating a manufacturer’s efforts to reduce the footprints of its products in the first place. In short, EPDs for raw materials create the necessary transparency for effectively optimizing the environmental footprint of our own value chain.
How can raw material suppliers like LANXESS benefit by offering EPDs?
We expect the demand for detailed LCA data across the entire supply chain to grow exponentially. We know that our customers are already working on specific strategies to reduce emissions across their supply chains. At the same time, the data users of EPDS, such as planners and auditors who create sustainability certification for buildings, are placing ever-greater requirements on data quality. The focus is increasingly on the raw materials used by the suppliers. This is why we expect that all raw materials used in the manufacture of construction materials will require an EPD verification in the medium term – and this is something that we welcome.
After all, quantifying environmental impact in the form of EPDs on the basis of uniform assessment parameters gives raw material manufacturers that – like LANXESS – continuously invest in environmentally friendly production processes a competitive advantage. This also includes the transition toward energy-efficient processes. The chemical synthesis of iron oxide pigments, for example, is inherently energy-intensive. Looking to the future, the Inorganic Pigments business unit at LANXESS has laid out a road map for continuously lowering the carbon footprint of its pigments. The aim is to reduce carbon emissions at our main production site in Germany by around 50 percent by 2030 thanks to new technologies and, for example, by switching to green energy and hydrogen. In the past, these kinds of cost-intensive investments were all too rarely factored into purchase decisions. But this is changing now. The environmental profile of raw materials is becoming one of the central purchasing arguments among coatings manufacturers.
As described, EPDs provide a credible and reliable basis for buyers to compare products from different raw material suppliers. Here is an example: An EPD provides a holistic assessment of products with regard to all environmental impacts. In terms of the raw materials used in particular, the primary focus is currently on the product carbon footprint (PCF). Our products for which an EPD is currently available have a PCF – as confirmed by an independent auditor – of around 1.5 kg to 2.5 kg of CO2 equivalent per kilogram of product . This figure can now be compared with that of other product alternatives – provided that an EPD or at least a certified PCF is available. If this is not the case, generic figures have to be used that often reflect a non-specific mean value and can also be prone to major errors. For inorganic pigments, this mean value was quoted some years ago in a publication from a European association of the mineral paint industry as being roughly 6 kg of CO2 equivalent per kilogram of product – ±50 percent depending on the manufacturing process.
Another current example of LANXESS’s efforts in the area of sustainability is that it was recently agreed to also use “green” sodium hydroxide in the manufacture of Bayferrox yellow pigments . The supplier of this vital raw material produces this base by using renewable energies. It is deployed in the so called precipitation process that results in very high-quality yellow pigments with special properties such as high tinting strength and thermal stability. This “green” raw material helps to cut CO2 emissions during the manufacture of these product groups by up to 40 percent per kilogram of pigment.