From the Sector

• Renewable Carbon Initiative (RCI) published a strategy paper on the defossilisation of the chemical and material industry with eleven policy recommendations

The Renewable Carbon Initiative, an interest group of more than 30 companies from the wide field of the chemical and material value chains, was founded in 2020 to collaboratively enable the chemical and material industries to tackle the challenges in meeting the climate goals set by the European Union and the sustainability expectations held by societies around the globe.

RCI addresses the core of the climate problem: 72% of anthropogenic climate change is caused directly by extracted fossil carbon from the ground. In order to rapidly mitigate climate change and achieve our global ambition for greenhouse gas emission reductions, the inflow of further fossil carbon from the ground into our system must be reduced as quickly as possible and in large scale.

In the energy and transport sector, this means a vigorous and fast expansion of renewable energies, hydrogen and electromobility, the so-called decarbonisation of these sectors. The EU has already started pushing an ambitious agenda in this space and will continue to do so, for instance with the recently released ‘Fit for 55’ package.

However, these policies have so far largely ignored other industries that extract and use fossil carbon. The chemical and material industries have a high demand for carbon and are essentially only possible with carbon-based feedstocks, as most of their products cannot do without carbon. Unlike energy, these sectors cannot be “decarbonised”, as molecules will always need carbon. The equivalent to decarbonisation via renewable energy in the energy sector is the transition to renewable carbon in the chemical and derived materials industries. Both strategies avoid bringing additional fossil carbon from the ground into the cycle and can be summarised under the term “defossilisation”.

To decouple chemistry from fossil carbon, the key question is which non-fossil carbon sources can be used in the future. Rapid developments in biosciences and chemistry have unlocked novel, renewable and increasingly affordable sources of carbon, which provide us with alternative solutions for a more sustainable chemicals and materials sector. These alternative sources are: biomass, utilisation of CO2 and recycling. They are combined under the term “renewable carbon”. When used as a guiding principle, renewable carbon provides a clear goal to work towards with sufficient room to manoeuvre for the whole sector. It enables the industry to think out of the box of established boundaries and stop the influx of additional fossil carbon from the ground.

The systematic change to renewable carbon will not only require significant efforts from industry, but must be supported by policy measures, technology developments and major investments. In order to implement a rapid and high-volume transition away from fossil carbon, and to demonstrate its impact, a supportive policy framework is essential. The emphasis should be put on sourcing carbon responsibly and in a manner that does not adversely impact the wider planetary boundaries nor undermines societal foundations. An overarching carbon management strategy is required that also takes specific regional and application-related features into account, to identify the most sustainable carbon source from the renewable carbon family. This will allow for a proper organisation of the complex transition from today’s fossil carbon from the ground to renewable energy and to renewable carbon across all industrial sectors.

RCI has developed eleven concrete policy recommendations on renewable carbon, carbon management, support for the transformation of the existing chemical infrastructure and the transformation of biofuel plants into chemical suppliers. The policy paper “Renewable Carbon as a Guiding Principle for Sustainable Carbon Cycles” is freely available for download in both a short version and a long version.

Link for Download: https://renewable-carbon-initiative.com/media/library/

HeiQ announces the launch of HeiQ Cool, the world’s first textile technology to deliver both instant contact cooling and continuous evaporative cooling.

Addressing the importance of body temperature control, whereby both overheating and feeling chilly are problematic, HeiQ Cool powered fabrics constantly regulate the skin temperature with a dual cooling capability. In a first step, melting energy absorption delivers instant contact cooling before the first sign of sweat and delays the build-up of heat, followed by a vaporizing energy action that mimics the skin’s thermal regulating system by providing continuous evaporative cooling as long as the body is hot and sweaty. Suitable for all fabrics, the initial launch focuses on home textiles, especially sleeping products such as mattress ticking, pillows and bed linen because of its clear benefit to help users get a good night’s sleep. It cools before the first sign of sweat, delays the build-up of heat and continuously regulates the temperature. Instantly cool to the touch, the components synergistically recharge the surface layer ensuring a consistently cool, dry and comfortable body climate.

USDA certified biobased dual action cooling textile technology
The biobased vegetable oil-derived thermo-functional polymer absorbs heat energy, giving an instant cooling sensation. If the body continues to heat up, perspiration is generated and the patented hydro-functional polymer transports moisture away together with the heat, creating a continuous cooling effect that stops once cooling is complete. The combination of a hydro-functional polymer with biobased vegetable oil-derived thermo-functional polymer formulation of HeiQ Cool contains more than 50% USDA® certified biobased content. It is also OEKO-TEX class 1 suited and meets most brand RSL (restricted substances list) requirements.

The OEKO-TEX® Association has published its annual update of the applicable test criteria, limit values and guidelines for its certifications. All new regulations will finally come into force on 1 April 2022 after a transition period. In addition, the new Impact Calculator is now available for STeP by OEKO-TEX® customers. The tool, which was developed specifically for textile industry operations, provides data on the CO2 and water footprint necessary to achieve the climate targets.

In mid-2022, the association will introduce RESPONSIBLE BUSINESS by OEKO-TEX®, a new certification for brands and retailers committed to international agreements for human rights and environmental protection. OEKO-TEX® aims to support companies in fulfilling due diligence obligations within their own operations and their global supply chains. RESPONSIBLE BUSINESS by OEKO-TEX® was developed in accordance with the UN Guiding Principles on Business and Human Rights and the relevant OECD Guidelines on Responsible Business Conduct.

New and updated limited values
OEKO-TEX® has added bisphenol B (BPB) in the STANDARD 100, LEATHER STANDARD and ECO PASSPORT by OEKO-TEX® certifications and to the STeP by OEKO-TEX® MRSL. The same applies to two additional colourants based on Michler’s ketone/base.

New substances under observation
In 2022, OEKO-TEX® will continue to monitor various substances based on the latest scientific findings and conformity with relevant specifications. This primarily concerns some process preservative agents and the bisphenols F, S and AF. The 2022 new regulations are available in detail for all OEKO-TEX® products on the website www.oeko-tex.com/news.

• More than 30 leading pioneers of the chemical and material sector welcome the latest political papers from Brussels, Berlin and Düsseldorf

The political situation for renewable carbon from biomass, CO2 and recycling for the defossilisation of the chemical and materials industry has begun to shift fundamentally in Europe. For the first time, important policy papers from Brussels and Germany take into consideration that the term decarbonisation alone is not sufficient, and that there are important industrial sectors with a permanent and even growing carbon demand. Finally, the need for a sustainable coverage of this carbon demand and the realisation of sustainable carbon cycles have been identified on the political stage. They are elemental to the realisation of a sustainable chemical and derived materials industry.

The goal is to create sustainable carbon cycles. This requires comprehensive carbon management of renewable sources, which includes carbon from biomass, carbon from Carbon Capture and Utilisation (CCU) – the industrial use of CO2 as an integral part – as well as mechanical and chemical recycling. And only the use of all alternative carbon streams enables a true decoupling of the chemical and materials sector from additional fossil carbon from the ground. Only in this way can the chemical industry stay the backbone of modern society and transform into a sustainable sector that enables the achievement of global climate goals. The Renewable Carbon Initiative’s (RCI) major aim is to support the smart transition from fossil to renewable carbon: utilising carbon from biomass, CO2 and recycling instead of additional fossil carbon from the ground. This is crucial because 72% of the human-made greenhouse gas emissions are directly linked to additional fossil carbon. The RCI supports all renewable carbon sources available, but the political support is fragmented and differs between carbon from biomass, recycling or carbon capture and utilisation (CCU). Especially CCU has so far not been a strategic objective in the Green Deal and Fit-for-55.

This will change fundamentally with the European Commission's communication paper on “Sustainable Carbon Cycles” published on 15 December. The position in the paper represents an essential step forward that shows embedded carbon has reached the political mainstream – supported by recent opinions from members of the European parliament and also, apparently, by the upcoming IPCC assessment report 6. Now, CCU becomes a recognised and credible solution for sustainable carbon cycles and a potentially sustainable option for the chemical and  material industries. Also, in the political discussions in Brussels, the term “defossilation” is appearing more and more often, complementing or replacing the term decarbonisation in those areas where carbon is indispensable. MEP Maria da Graça Carvahlo is among a number of politicians in Brussels who perceive CCU as an important future industry, putting it on the political map and creating momentum for CCU. This includes the integration of CCU into the new Carbon Removal Regime and the Emission Trading System (ETS).

As the new policy documents are fully in line with the strategy of the RCI, the more than 30 member companies of the initiative are highly supportive of this new development and are ready to support policy-maker with data and detailed suggestions for active support and the realisation of sustainable carbon cycles and a sound carbon management. The recent political papers of relevance are highlighted in the following.

Brussels: Communication paper on “Sustainable Carbon Cycles”
On 15 December, the European Commission has published the communication paper “Sustainable Carbon Cycles” . For the first time, the importance of carbon in different industrial sectors is clearly stated. One of the key statements in the paper is the full recognition of CCU for the first time as a solution for the circular economy, which includes CCU-based fuels as well. The communication paper distinguishes between bio-based CO2, fossil CO2 and CO2 from direct air capture when addressing carbon removal and it also announces detailed monitoring of the different CO2 streams. Not only CCU, but also carbon from the bioeconomy is registered as an important pillar for the future. Here, the term carbon farming has been newly introduced, which refers to improved land management practices that result in an increase of carbon sequestration in living biomass, dead organic matter or soils by enhancing carbon capture or reducing the release of carbon. Even though the list of nature-based carbon storage technologies is non-exhaustive in our view, we strongly support the paper’s idea to deem sustainable land and forest management as a basis for the bioeconomy more important than solely considering land use as a carbon sink. Surprisingly, chemical recycling, which is also an alternative carbon source that substitutes additional fossil carbon from the ground (i.e. carbon from crude oil, natural gas or from coal), is completely absent from the communication paper.

Berlin: Coalition paper of the new German Government: “Dare more progress – alliance for freedom, justice and sustainability”
The whole of Europe is waiting to see how the new German government of Social Democrats, Greens and Liberals will shape the German climate policy. The new reform agenda focuses in particular on solar and wind energy as well as especially hydrogen. Solar energy is to be expanded to 200 GW by 2030 and two percent of the country's land is to be designated for onshore wind energy. A hydrogen grid infrastructure is to be created for green hydrogen, which will form the backbone of the energy system of the future – and is also needed for e-fuels and sustainable chemical industry, a clear commitment to CCU. There is a further focus on the topic of circular economy and recycling. A higher recycling quota and a product-specific minimum quota for the use of recyclates and secondary raw materials should be established at European level. In the coalition paper, there is also a clear commitment to chemical recycling to be found. A significant change for the industry is planned to occur in regards to the so-called “plastic tax” of 80 cents per kilogram of non-recycled plastic packaging. This tax has been implemented by the EU, but most countries are not passing on this tax to the manufacturers and distributors, or only to a limited extent. The new German government now plans to fully transfer this tax over to the industry.

Düsseldorf: Carbon can protect the climate – Carbon Management Strategy North Rhine-Westphalia (NRW)
Lastly, the RCI highly welcomes North Rhine-Westphalia (NRW, Germany) as the first region worldwide to adopt a comprehensive carbon management strategy, a foundation for the transformation from using additional fossil carbon from the ground to the utilisation of renewable carbon from biomass, CO2 and recycling. For all three alternative carbon streams, separate detailed strategies are being developed to achieve the defossilisation of the industry. This is all the more remarkable as North Rhine-Westphalia is the federal state with the strongest industry in Germany, in particular the chemical industry. And it is here, of all places, that a first master plan for the conversion of industry from fossil carbon to biomass, CO2 and recycling is implemented. If successful, NRW could become a global leader in sustainable carbon
management and the region could become a blueprint for many industrial regions.

Maruti Printing transformed its business as the first printer in India to adopt the latest LED-UV curing technology from AMS Spectral UV, a Baldwin Technology Company. The hybrid system, which includes traditional UV modules, has been in production for nearly two years and has significantly expanded the offset printer’s capabilities for its customers, including adding the ability to print on all types of plastic substrates.

Not only does Maruti have the distinction of being an LED-UV trailblazer in India, but it also is first in the market to upgrade a high-speed, high-performance Heidelberg Speed Master 72F+L six-color printer with coating tower—which prints up to 15,000 sheets per hour—with AMS Spectral UV’s high-power AMS XP9-I Series LED-UV and P3 Smart UV curing modules.

Established in 1986 and headquartered in Ahmedabad, Gujarat, Maruti serves customers throughout India, providing offset printing of scratch cards, banners, booklets, brochures, calendars, danglers, pamphlets, posters, stickers and envelopes.

In January 2020, Maruti took delivery of two AMS XP9-I Series LED-UV modules to cure colors in the interdecks. The modules are ideal for the highest-speed curing situations that require consistent peak intensity to the substrate, which is the case for Maruti’s offset printing standard of perfection with every cure.

To cure ink, as well as a growing variety of LED coatings, Baldwin’s AMS Spectral UV modules can be located after print units, or in the press delivery after the coater. When inks and coatings are cured with LED-UV, they become instantly dry via photopolymerization, allowing for printing on any substrate, including plastics and metallized stocks. Plus, work can be immediately finished and sent to the bindery once it comes off the press, without the need for heat, spray powder or drying time.

In addition, Maruti took delivery of two P3 Smart UV curing modules for installation at the end of the press to cure any type of UV coating and expand the company’s scope of coating compatibility to general UV coatings in order to offer its customers the widest range of UV printed choices in the Indian market.

The P3 Smart UV housings are completely liquid-cooled to ensure safe, consistent performance and increased uptime, and modules feature a universal design, so that any unit can fit any print unit location. P3 modules can be changed, inspected and cleaned quickly and easily, without tools, and lamps slide and lock into place smoothly and securely.

The durability of the equipment and its chipset was a critical deciding factor in India’s climate. The latest-generation power-and-control cabinets are dust- and moisture-resistant, allowing them to withstand extreme heat and humidity, as well as powder and airborne contaminants, making the equipment ideal for operation in stressful conditions anywhere in the world. AMS Spectral UV’s latest generation of LED chips, designed for the highest-intensity curing applications, enable the curing of LED inks and coatings at record-setting speeds. They are built with resilient components, and the semi-conductor components are sealed, which allows the chips to work in a variety of rugged environments. Additionally, integrated circuits incorporated into the design electronically protect the LEDs and the entire system.

Zahlreiche Produkte unserer Industriegesellschaft wie Stahl, Aluminium, Zement oder Kunststoff bestehen aus Kohlenstoff oder benötigen ihn, um hergestellt werden zu können. Zentrale Ansätze, wie der Umgang mit Kohlenstoff neu und nachhaltig gestaltet werden kann, hat das Ministerium für Wirtschaft, Innovation, Digitalisierung und Energie (MWIDE) mit der Carbon Management Strategie NRW vorgelegt. Ziel ist eine klimaneutrale Industrie. Auf einer gemeinsamen Veranstaltung des Thinktanks IN4climate.NRW und des MWIDE hat Wirtschafts- und Energieminister Prof. Andreas Pinkwart mit Expert*innen aus Industrie, Wissenschaft und Zivilgesellschaft die Inhalte diskutiert.

»Für uns ist klar: Kohlenstoff kann Klimaschutz«, so Minister Pinkwart. »Mit unserer Carbon Management Strategie zeigen wir ganz konkret, wie eine klimaneutrale Kohlenstoffwirtschaft in Nordrhein-Westfalen aussehen kann. Wir wollen Kohlenstoff nicht nur reduzieren, sondern auch nachhaltig so oft wie möglich im Kreislauf nutzen und die Gesellschaft transparent einbinden. Wir sind damit das erste Bundesland überhaupt, das sich dem Thema annimmt. So können wir unsere ehrgeizigen Klimaschutzziele erreichen und den Industriestandort von morgen gestalten.«

Eine klimaneutrale Industrie braucht nachhaltige Kohlenstoffquellen
Dr. Iris Rieth, Projektmanagerin für Kohlendioxidwirtschaft und Circular Economy bei IN4climate.NRW: »Eine klimaneutrale Industrie braucht nachhaltige Kohlenstoffquellen. Die Circular Economy und die Nutzung von CO2, dessen Ausstoß nicht vermieden werden kann, müssen wir weiter ausbauen. IN4climate.NRW hat in enger Zusammenarbeit mit Unternehmen und der Wissenschaft wichtige Ansätze erarbeitet, die den unterschiedlichen Industrieprozessen gerecht werden. Die Carbon Management Strategie führt nun die Bausteine der Transformation zusammen und setzt die notwendigen politischen Leitplanken, an denen wir uns in unserer weiteren Arbeit orientieren können.«
Infrastruktur für den Transport von CO2 muss aufgebaut werden

Kohlenstoffdioxid war bislang kein Bestandteil von Infrastrukturplanungen in Deutschland. Dabei wird es auch in Zukunft Prozesse geben, bei denen unvermeidlich CO2 entsteht, wie etwa bei der Herstellung von Zement. Verschiedene Projekte arbeiten bereits daran, CO2 direkt am Ofen abzufangen und anderen Branchen, vor allem der chemischen Industrie, als Rohstoff zur Verfügung zu stellen (engl. Carbon Capture and Utilisation, CCU). Eine Infrastruktur für den Transport muss jedoch erst noch aufgebaut werden.

Konkrete Optionen, wie ein solches Pipeline- und Transportsystem aussehen könnte, hat IN4climate.NRW Mitte Oktober in dem Diskussionspapier »CO2 in einer klimaneutralen Grundstoffindustrie« veröffentlicht. In einem weiteren Diskussionspapier »Circular Economy in der Grundstoffindustrie« hat IN4climate.NRW zudem aktuelle Stoffströme analysiert und Lösungsansätze für eine zukünftige industrielle Circular Economy erarbeitet. Beide Papiere sind maßgeblich in die Carbon Management Strategie des Landes eingeflossen.

An der Paneldiskussion haben neben Wirtschafts- und Energieminister Prof. Andreas Pinkwart teilgenommen:

• Dr. Iris Rieth, Projektmanagerin für Kohlendioxidwirtschaft und Circular Economy bei IN4climate.NRW,
• Prof. Görge Deerberg, stellvertretender Institutsleiter des Fraunhofer UMSICHT,
• Dr. Christoph Sievering, Head of Global Energy and Climate Policy & Site Transformation bei Covestro,
• Arne Grotenrath, Experte für Treibhausgasbilanzierung bei Germanzero sowie
• Michael Theben, Abteilungsleiter Klimaschutz im Ministerium für Wirtschaft, Innovation, Digitalisierung und Energie.

Indorama Ventures Public Company Limited (IVL), a global sustainable chemical company, announced its inclusion in the Dow Jones Sustainability World Index (DJSI World) and the Dow Jones Sustainability Emerging Markets Index (DJSI Emerging Markets) for the third and fifth consecutive year respectively. The successive years of DJSI inclusion reflect IVL’s strong commitment to sustainability with globally recognized industry best-in-class practices.

This year, 139 chemical companies were selected from more than 11,000 companies from 61 industries and about 5,300 companies eligible for S&P Global ESG indices. IVL ranked in the 97th percentile with full scores in the areas of environmental and social compliance, enabling policies through industry associations, human rights protections in the workplace and value chain, and sustainable water management including forecasting potential water related risks in operations.

Yash Lohia, Chief Sustainability Officer at Indorama Ventures, said, "As a global leader, this is an important milestone in our operations as we transform the chemical industry. Our inclusion in the DJSI for the fifth year running is a tribute to how IVL’s operations are contributing to a more sustainable future. Our strategy includes focusing on climate action, aligning with the world's net zero ambitions, strengthening the circular economy and PET recycling with our ambitious targets, and enhancing shared value with our stakeholders.”

The Dow Jones Sustainability Indices (DJSI) are a global benchmark for sustainability-driven companies, evaluating material governance & economic, environmental and social factors.

Stahl, an active proponent of responsible chemistry, today announces that – by the end of Q2 2022 – it will extend its GHG reduction targets to cover Scope 3 emissions. This step underlines Stahl’s commitment to aligning its strategy with the 2015 Paris Climate Agreement goals, updated at the recent COP26 in Glasgow.

Between 2015 and 2020 Stahl reduced its Scope 1 and 2 (direct) GHG emissions by 37%, and has committed to a further 2% reduction each year to 2030. Scope 3 emissions cover all the indirect emissions that can occur in a company’s value chain, including raw material acquisition, transportation, and the end-of-life impact of its products. By focusing on Scope 3 emissions, Stahl is committing to de-fossilizing its supply chain and ensuring further accountability for its total environmental impact.

Michael Costello, Stahl Group ESG Director: “Only by focusing on reducing Scope 3 emissions can we accurately align our de-fossilization strategy with the global goal of limiting global average temperature increase to 1.5°C, as agreed at the 2015 Paris Climate Agreement and the COP26 in Glasgow. We look forward to working with partners across our industry and value chain to make this happen.”

Alchemie Technology, an innovator of low energy, waterless, textile dyeing and finishing technology, is calling on COP26 leaders to support the global fashion industry in the adoption of new manufacturing technology, which will dramatically reduce carbon emissions and fashion’s impact on climate change.

While the fashion industry is one of the most polluting on the planet, second only to oil and gas, and greenhouse gas emissions from textile dyeing at around 3% of global emissions outweigh that of all international flights and maritime shipping combined, it is an industry that can also reduce CO2 emissions the fastest, just by changing the way it dyes fabrics.  

Fabric dyeing is the most polluting part of fashion and activewear manufacturing, involving industrial scale dye baths and huge amounts of dye chemicals, steam, electrical power, and consequent high CO2 emissions.  Repeated washing of the dyed fabric, required to remove dye residue, is responsible for 20% of the world’s wastewater pollution and excess dye is discharged into waterways, affecting the health of some of the world’s poorest communities. In more regulated areas, water pollution is reduced through reliance on energy intensive water treatment plants.

However, an environmental step change can be achieved by adopting new digital technology that can dye fabrics with an 85% reduction in energy consumption and a dramatic 95% reduction of the 1.3 trillion litres of water currently used by the industry each year.

For example, dyeing one polyester shirt using current methods generates 4.5 litres of wastewater and produces 0.17 Kg of CO2, compared to low energy digital technology, which uses less than 0.2 litres of water and reduces carbon emissions to 0.03 Kg.  Multiply these numbers by the billions of garments dyed each year and the scale of the environmental problem, if nothing changes, is clear to see. Equally, the amount by which the textile industry can improve its carbon footprint is dramatic and can be done quickly if action is taken now.

• Alchemie Technology asks world leaders to cut energy and CO2 emissions from global fashion industry

Alchemie Technology, innovator of low energy, waterless, textile dyeing and finishing technology, is calling on COP26 leaders to support the global fashion industry in the adoption of new manufacturing technology, which will dramatically reduce carbon emissions and fashion’s impact on climate change.

While the fashion industry is one of the most polluting on the planet, second only to oil and gas, and greenhouse gas emissions from textile dyeing at around 3% of global emissions outweigh that of all international flights and maritime shipping combined, it is an industry that can also reduce CO2 emissions the fastest, just by changing the way it dyes fabrics.  

Fabric dyeing is the most polluting part of fashion and activewear manufacturing, involving industrial scale dye baths and huge amounts of dye chemicals, steam, electrical power, and consequent high CO2 emissions.  Repeated washing of the dyed fabric, required to remove dye residue, is responsible for 20% of the world’s wastewater pollution and excess dye is discharged into waterways, affecting the health of some of the world’s poorest communities. In more regulated areas, water pollution is reduced through reliance on energy intensive water treatment plants.

However, an environmental step change can be achieved by adopting new digital technology that can dye fabrics with an 85% reduction in energy consumption and a dramatic 95% reduction of the 1.3 trillion litres of water currently used by the industry each year.

For example, dyeing one polyester shirt using current methods generates 4.5 litres of wastewater and produces 0.17 Kg of CO2, compared to low energy digital technology, which uses less than 0.2 litres of water and reduces carbon emissions to 0.03 Kg.  Multiply these numbers by the billions of garments dyed each year and the scale of the environmental problem, if nothing changes, is clear to see.  Equally, the amount by which the textile industry can improve its carbon footprint is dramatic and can be done quickly if action is taken now.
Dr Simon Kew, Managing Director, Alchemie Technology comments “The technology now exists to enable the textile industry to make a significant contribution to helping meet the world’s net zero, climate change goals. But it requires the support of governments through investment, grants and legislation and the critical effort of brands, and their manufacturing supply chains to work together to make the change.”