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/

Baldwin Technology Company Inc. has forged a new partnership with Blutec S.A. de C.V., which now represents Baldwin’s full range of innovative spray systems and corona/plasma treaters for wovens, knits and nonwovens in Mexico.

Blutec is a leading agency in the textile sector, representing many of the most reputable textile machinery manufacturers worldwide. Present in the Mexican market for more than 25 years, Blutec is committed to collaborating with companies on the forefront of textile manufacturing technology, including Brückner, Mahlo, EFI Reggiani, Ferraro and, now, Baldwin.

Baldwin’s precision spray systems for finishing and remoistening use non-contact spray technology to provide optimal controlled coverage of the exact amount of liquids needed to achieve the specific characteristics of the fabric—saving customers time, money and valuable resources. Because only the required amounts of water and chemicals are applied, water consumption can be reduced by up to 50%, contributing to considerably improved productivity in the finishing process.
In addition, these solutions can process a wide range of low-viscosity water-based chemicals—such as softeners, antimicrobial agents, durable water repellents, flame retardants and more—for woven fabrics, knitted textiles and nonwovens.

Sistema Moda Italia confirms its Innovation Area for the 34th edition of Milano Unica, an area which responds to the growing demand for innovation in products, processes and services able to give specific performances or made with innovative and sustainable systems. And right here we find Sitip’s technical fabrics for clothing, with the COSMOPOLITAN Fashion-tech fabrics collection, modern and comfortable, dedicated to contemporary urbanwear/sportswear style and which perfectly meets the new needs required by the market and by the final consumer: performance and design.

COSMOPOLITAN Fashion-tech is declined into urbanwear through the sartorial technical fabrics that the company has defined Techno Sartorial: a tailoring that combines flawless cuts with exceptional fabric performance.

For the production of contemporary urbanwear, thought for the city, Sitip showcases the man’s suit made of jacket+trousers in warp-knit Cosmopolitan Citylife fabric: bi-stretch nylon with UV protection (UPF 50+), quick drying, easy care and skin comfort. Highly performing, breathable, comfortable, insulating and with an exceptional fit: incredible elegance and comfort that enhance the contemporary urbanwear style.

For women, Sitip presents COSMOPOLITAN Fashiontech fabrics dedicated to athleisure, with leggings made - for the summer version - in Cosmopolitan London, a bi-stretch circular knitted fabric, no seethrough, breathable, comfortable on the skin with UV protection (UPF 50+), with easy care and perfect shape retention, and - for the winter version - in Cosmopolitan Paris GZ, a circular knitted fabric raised on the reverse side, with the same properties as the previous one and thermoregulation characteristics.

The Instinct fabric is available in the recycled and raised version NATIVE INSTINCT GZ: a GRS certified thermal fabric made with pre-consumer recycled yarns, bi-stretch, breathable, resistant to pilling, easy care and high comfort, ideal for sporty knitwear and urbanwear part of the NATIVE SUSTAINABLE TEXTILES family, the Sitip fabric collection produced with GRS certified recycled yarns and low environmental impact chemicals with a lower consumption of natural resources , able to respect the environmental and social criteria extended to all the stages of the production chain, including the traceability of raw materials. Sitip also operates in line with international certifications such as OEKO-TEX®, BLUESIGN®, GRS and adheres to the ZDHC gateway, adding to these an ISO 14001 environmental management system, which certifies the company’s commitment to reducing pollution risks.

CO₂ as renewable carbon source
Carbon is the main element in numerous materials used in industrial processes and in our daily lives. It is currently mostly provided from fossil sources. But what if carbon could be used directly from CO₂ emissions? Biotechnology shows particularly great potential for the eco-effective conversion of climate-damaging CO₂ emissions into valuable basic chemicals. A consortium of 12 partners investigated this pathway in the EU-funded BioRECO₂VER project, examining the conversion of CO₂ emissions from refineries and the cement industry into the chemical building blocks isobutene (C₄H₈) and lactate (C₂H₆O₃).

Innovative chemo-enzymatic concept for CO₂ Capture
Project partner Luleå University of Technology (LTU) focused on the first process step of capturing and concentrating CO₂ from industrial point sources. Their team developed a hybrid chemo-enzymatic process consisting of a novel solvent blend and an ultrastable carbonic anhydrase (CA) enzyme. The solvent blend included an amino acid ionic liquid and a tertiary amine and displayed a good compromise between enzyme compatibility, absorption rate, capacity and desorption potential. In addition, LTU generated ultrastable enzyme mutants that showed 50% increased resistance to selected flue gas inhibitors compared to the original CA. This 3-component CO₂ capture process was scaled up in a pilot rig, and the set-up further used for real off gas pre-treatment in the project.

Two unique pilots for biotechnological CO₂ Conversion/Utilization
The biotechnological conversion of (captured) CO₂ and the co-substrate hydrogen by microorganisms poses technical and economic challenges because it takes place in the liquid phase and the substrates are gases which are poorly soluble. The BioRECO₂VER project investigated two approaches to address this: fermentation under elevated pressure and bio-electrochemistry with in situ production of hydrogen.

Pressurized fermenter
Project coordinator VITO designed a flexible and multifunctional high-pressure fermenter, customized for research activities with advanced online sensors, monitoring and control, and also including a membrane filtration unit to achieve high concentrations of the microbial biocatalysts. The set-up was broadly tested in the BioRECO₂VER project both with pure CO₂ and CO₂-rich off-gases but can also be used for investigations involving other poorly soluble gases, such as methane, oxygen, or synthesis gas. Pressures up to 10 bar can be applied.

First solely CO₂-based bio-electrochemical platform
University of Girona designed and tested a bio-electrochemical platform. The key differentiators of the pilot plant are:

• Two parallel lines to test engineered strains and bio-electrochemical systems
• Fully automated pilot plant capable to control key operational parameters (pCO₂, pO₂, pH₂, pH, Temperature) to intensify the process performance
• Solid-liquid separation unit (membrane) to recover the planktonic cells and return them into the bio-electrochemical systems.

This unique infrastructure will be used beyond the project to support further research and development activities in the broad area of CO₂ capture and conversion.

Indorama Ventures Public Company Limited (IVL) was awarded “Best Sustainability-Linked Transaction & Best ESG-Linked Financing Deal of the Year” for its THB 10 billion Sustainability-Linked Bond (SLB) issued in November 2021.

The award was announced at the 15th Best Deal & Solution Awards 2021 by Alpha Southeast Asia, an institutional publication focused on investment in Southeast Asia. This recognition marks IVL's commitment to sustainable growth and ESG performance as a global leader in the chemical industry.

Yash Lohia, Chairman of ESG Council at Indorama Ventures, said, "This award reflects our long-standing commitment to sustainability and creating opportunities for investors to take part in the positive transformation of the chemical industry. This award confirms that financial markets value our ambitious sustainability and ESG efforts towards a more sustainable future.”

IVL's THB 10 billion issuance sets a new benchmark as the largest SLB transaction in Thailand and the first offered to both institutions and high-net-worth investors. The financial instrument is linked to the company's sustainability goals of reducing GHG emissions intensity by 10% by 2025, increasing recycling of PET bale input to 750,000 tons per year by 2025, and achieving 25% renewable electricity consumption in 2030.

IVL appointed Bangkok Bank, Kasikorn Bank, Krungthai Bank, Siam Commercial Bank, and the Bangkok branch of HSBC as as arrangers and bookrunners for the green transaction.

Microplastic pollution is a global challenge across many industries and sectors – one of critical importance being textiles.

A 2021 study by the California Ocean Science Trust and a group of interdisciplinary scientists acknowledges that microfibres from textiles are among the most common microplastic materials found in the marine environment. Every time synthetic clothes are manufactured, worn, washed, or disposed of, they release microplastics into terrestrial and marine environments, including human food chains. Synthetic fibres represent over two-thirds (69%) of all materials used in textiles, a proportion that is expected to rise to 73% by 2030. The production of synthetic fibres has fuelled a 40-year trend of increased per capita clothing consumption.

Global textile consumption has become:

• more reliant on non-renewable resources,
• less biodegradable, and
• increasingly prone to releasing microplastics.

The increased consumption is also discretionary, driven by consumer desire and remains unchecked. Thus, the long-term trend in the textile industry parallels the intentional addition of microplastics to products such as cosmetics. The contrast is that the European Chemicals Agency (ECHA) has recommended such intentional additions be restricted, whereas the over-consumption of synthetic fibres continues unchecked. One way for the EU to account for and mitigate microplastic pollution is through an EU-backed methodology measuring and reporting microplastic emissions, so that consumers and procurement officers have the information needed to minimise microplastic pollution resulting from their purchasing decisions.

There is a critical opportunity to address microplastic pollution in the fashion textile industry through the EU Product Environmental Footprint (PEF) methodology. To meet the environmental objectives of the Circular Economy Action Plan, the EU is proposing that companies substantiate their products’ environmental credentials using this harmonised methodology. However, microplastic pollution is not accounted for in the PEF methodology. This omission has the effect of assigning a zero score to microplastic pollution and would undermine the efforts of the European Green Deal, which aim “to address the unintentional release of microplastics in the environment.”

The incorporation of microplastic pollution as an indicator would increase the legitimacy of the PEF method as well as better inform consumer purchasing decisions, especially as the European Green Deal seeks to “further develop and harmonise methods for measuring unintentionally released microplastics, especially from tyres and textiles, and delivering harmonised data on microplastics concentrations in seawater.”

Whilst we continue to learn about the damage of microplastics and there is new knowledge emerging on the toxic impacts along the food chain, there is sufficient information on the rate of microplastic leakage into the environment to implement a basic, inventory level indicator in the PEF now. This is consistent with the recommendations of a review of microplastic pollution originating from the life cycle of apparel and home textiles. There are precedents in PEF for basic level (e.g., ‘resource use, fossils’) and largely untested (e.g. land occupation and toxicity indicators) indicators, and therefore an opportunity for the EU to promote research and development in the measurement and modelling of microplastic pollution by including such emissions in the PEF methodology. For such an indicator, the long and complex supply chains of the apparel and footwear industry would be a test case with high-impact and a global reach.

Sateri’s Lyocell facility in Rizhao, Shandong Province, has been awarded the Sustainable Textile Production (STeP) certification for responsible production, making it the first Lyocell producer in China to be certified to the rigorous standards set by independent Swiss-based certification organisation OEKO-TEX®. Sateri’s Lyocell facility has also obtained the highest ranking of level three in the certification assessment scoring for exemplary implementation of best manufacturing practices.

Together with its earlier achievement of the STANDARD 100 by OEKO-TEX® certification that confirms its Lyocell fibre is free from any harmful substances and complies with European standards, Sateri’s lyocell products are qualified to carry the MADE IN GREEN by OEKO-TEX® product label. This label not only attests to Sateri’s Lyocell fibre as safe and manufactured in environmentally-friendly, socially responsible and safe facility, but also the Group’s commitment to higher levels of transparency and accountability through the product traceability feature of the label.

The STeP by OEKO-TEX® certification comprises three levels describing the extent to which a company has achieved sustainable production and working conditions of factories in the textile industry. The areas of assessment include chemicals management, environmental performance, environmental management, social responsibility, quality management, as well as occupational health and safety.

Sateri’s Lyocell fiber factory in Rizhao commenced operation in May 2020, with an annual output of 20,000 tonnes of Lyocell fiber. The same site houses a 5,000 tonne Lyocell pilot production line dedicated for the development of Lyocell application technology. In March 2021, the Group announced plans to expand its Lyocell annual production capacity in China up to 500,000 tonnes by 2025.

A natural and biodegradable fibre, Sateri’s Lyocell is made from wood pulp sourced from certified and sustainable plantations. It is manufactured using closed-loop technology, requiring minimal chemical input during the production process, and utilising an organic solvent that can be almost fully (99.7%) recovered and recycled.

Sateri’s Lyocell is used to produce high quality textiles and personal hygiene materials. Using a unique high technology manufacturing process, it has outstanding dry and wet strength, high uniformity and consistency, and superior quality. It blends well with various textile fibres to create different fabric styles and characteristics for wide downstream applications.

• ADNOC and Borealis confirm final investment agreement to build Borouge 4 in Ruwais, United Arab Emirates (UAE), which will produce 1.4 million tons of polyethylene per annum
• Expansion project includes construction of a 1.5 million tonnes ethane cracker, two state-of-the-art Borstar® polyethylene plants and a cross-linked polyethylene plant
• Borouge 4 will meet growing customer demand across the Middle East, Africa and Asia with differentiated polyolefin solutions in energy, infrastructure, and advanced packaging
• New facility will benefit from industry-leading technologies to significantly improve energy efficiency and lower emissions, with carbon capture study underway
• Upon expansion, Borouge will be the world's largest single-site polyolefin complex and will supply feedstock to TA'ZIZ Industrial Chemicals Zone Body

ADNOC and Borealis AG signed an USD 6.2 billion investment agreement to build the fourth Borouge facility – Borouge 4 – at the polyolefin manufacturing complex in Ruwais, United Arab Emirates (UAE).

The world-scale expansion confirms both partners’ commitment to the growth of Borouge and to support chemical production, and advanced manufacturing and industry in Ruwais, a key pillar of Abu Dhabi and the UAE’s technology, innovation and industrial development strategy. Borouge produces crucial industrial raw materials, which are exported to customers globally and used by local companies, boosting local industrial supply chains and enhancing In-Country Value.

Borouge 4 will capitalize on the projected growth in customer demand for polyolefins, driven by their use in manufactured products in the Middle East, Africa and Asia. The facility will also enable the next phase of growth at the Ruwais Industrial Complex by supplying feedstock to the TA’ZIZ Industrial Chemicals Zone.

Borouge 4 will have an industry-leading focus on sustainability leveraging the capabilities of both shareholders. The facility will utilize Borealis’ proprietary Borstar technology, to produce a product portfolio focused on durable applications for energy, infrastructure, advanced packaging, and agriculture sectors. This unique technology, in combination with hexene co-monomer, will enable the production of advanced packaging grades with up to 50% recycled polyethylene content.

Subject to an in-depth study, a Carbon Capture unit that would reduce CO2 emissions by 80% could also be operational in time for Borouge 4’s start-up. The facility is also designed to capitalize on ADNOC’s recent initiatives on clean energy, decarbonizing its power supply through access to Abu Dhabi’s clean power sources. These initiatives are aligned with the UAE Net Zero by 2050 Strategic Initiative.

The first Borouge facility, producing 450,000 tons of polyethylene per annum was commissioned in 2001. Borouge 2 and Borouge 3 took capacity to 2 million tons and 4.5 million tons of polyethylene and polypropylene per annum in 2010 and 2014 respectively.  Borouge 4 will boost the company’s annual polyolefin production to 6.4 million tons, making Borouge one of the world’s largest single-site polyolefin facilities.

The new Borouge 4 facility will comprise:

• An ethane cracker, with 1.5 million tons ethylene output per annum, which will be the fourth cracker in Borouge’s integrated petrochemical complex in Ruwais
• Two additional Borstar® polyethylene (PE) plants, each with 700 thousand tons per annum capacity, using state-of-the-art Borealis Borstar third generation (3G) technology
• A cross-linked PE (XLPE) plant of 100 thousand tons per annum capacity.
• A hexene-1 unit, which will produce co-monomers for certain grades of polyethylene.

• 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.”

Indorama Ventures Public Company Limited announced it has strengthened its Indorama Management Council (IMC) – the company’s highest operational management committee – by rotating experienced executives and adding the COOs of the Fibers and Integrated Oxides & Derivatives (IOD) segments.

The elevation of Mr Christopher Kenneally, COO of Fibers, and Mr Alastair Port, COO of IOD, to the IMC – will enable more agile decision making as they build their high-growth segments into self-sustaining organizations that maximize value for IVL stakeholders. The appointments are effective immediately.

In a rotation of roles, Mr Sanjay Ahuja, the current CFO of IVL, will switch to Interim COO of Combined PET (CPET) for a period of 2 years, effective January 2022, as part of a rotation of senior expertise across the IMC. He will report to Mr D K Agarwal as CEO, who will take on additional broader responsibilities as CFO. The CPET role rotation will enable new dynamism in this largest segment of IVL and establish a self-sustaining organization for the permanent successor that IMC selects over this period. Mr Agarwal will be supported by Mr Ashok Jain in an enhanced role as Controller, covering Banking & Finance, Global Consolidation, Taxation and M&A.

Further, Mr Klaus Holz will join the IMC as Chief Human Resources Officer, effective 1 January 2022. He replaces Mr Roberto Bettini who will retire at the end of 2021.