From the Sector

The transition towards safer and more sustainable chemicals is progressing in some areas, while in others, it is just beginning. This is the finding of a first, joint Europe-wide assessment of the drivers and impact of chemical pollution by the European Environment Agency (EEA) and the European Chemicals Agency (ECHA). The benchmarking found that more work is still needed to reduce the impact of harmful substances on human health and the environment.

The number of industrial chemicals scrutinised under the EU’s chemicals legislation to determine their safety has increased substantially. Authorities now have much better knowledge about the hazardous properties of chemicals that are used across the EU, resulting in many actions to minimise and control the risks of several groups of substances.

According to the joint EEA-ECHA synthesis report on the EU indicator framework for chemicals, the overall use of the most harmful chemicals (in particular those that are carcinogenic, mutagenic and reprotoxic) is still growing but more slowly than the overall chemicals market growth. Pressure is increasing to avoid the use of so-called substances of concern and to implement the principles of the safe and sustainable by design framework.

There is a need to more effectively ensure that consumer products do not contain the most harmful substances, for example chemicals that are endocrine disrupting, that negatively affect the hormone system, or substances that are persistent, bioaccumulative and toxic, which present a risk for years to come even after their use has ceased.

More data and information are needed to better understand human and environmental exposure to those most harmful chemicals and their impacts. Still, the indicators show clearly that the shift to safe and sustainable chemicals must continue and should even be accelerated.

The report is based on a set of 25 key indicators, which monitor the drivers and impacts of chemical pollution in Europe.

Key findings

• Transition towards safer and more sustainable chemicals is progressing in some areas while in others it is just getting started.
• Action by authorities and industry has supported minimising and controlling the risks from several groups of hazardous chemicals. Efforts are ongoing to increase knowledge on chemical hazards and support risk management action where needed.
• Available data suggest that there is little evidence of progress towards eliminating substances of concern from waste and secondary materials. This is a barrier to the transition towards a more circular economy.
• Emissions of certain chemicals to water and air have fallen following specific EU regulations (e.g., on industrial emissions) and international actions, but further measures are needed to reach concentration levels that are not harmful for human health and the environment.
• Emissions from industry still lead to major costs in terms of damages to human and ecosystem health.
• Human biomonitoring offers the opportunity to understand human exposure to chemicals from multiple sources and thus health risks associated with chemical pollution. As such, biomonitoring forms a key tool to measure the effectiveness of chemicals legislation in protecting human health and the environment.

CARBIOS was awarded 1st prize in the "So French So Innovative" Award organized by Business France, the Hong Kong Committee of French Foreign Trade Advisors (CCEF), La French Tech and its partners at InnoEX 2024 (taking place in Hong Kong from 13 to 16 April). The award recognizes French innovation to promote and support French Tech in the Asia-Pacific region. The final awards ceremony was held on the French pavilion in the presence of members of the Hong Kong Government and Christile Drulhe, Consul General of France in Hong Kong.

Emmanuel Ladent, CEO of CARBIOS: "Asia-Pacific is a key market for our PET biorecycling solution, and the 'So French So Innovative' Award is a recognition that supports CARBIOS’ prospection and commercial deployment in the region. CARBIOS' technology is generating a lot of interest, leading to promising discussions and the exploration of commercial agreements to support the sustainability commitments and international operations of current and future partners."

CARBIOS' global presence
In a dynamic global PET market, where the share of recycled PET will increase, CARBIOS' ambition is to become a leading r-PET player by 2035. CARBIOS has extended its international reach to boost its commercial deployment worldwide. Teams in place in key markets are dedicated to identifying business opportunities and establishing commercial partnerships for PET biorecycling technology, with first agreements expected in 2024. To date, CARBIOS is represented in three regions: Europe, North America (including Canada) and Asia (China, Japan, Korea, Singapore, Taiwan, and soon India).

The EU directive on the further development of sustainability reporting (CSRD) poses major challenges for companies and the public sector. Until now, the regulations have only applied to large capital market-oriented companies. However, far-reaching changes to sustainability reporting are expected when the CSRD is transposed into national law in 2024. The German Institutes of Textile and Fiber Research (DITF) are facing up to this challenge of external reporting and at the same time the responsibility for sustainable and resource-conserving science. The Textile Research Center has therefore set up a specialist department reporting to the Executive Board.

The DITF are reaffirming their commitment to sustainability with the appointment of the previous Head of the Competence Center Textile Chemistry, Environment & Energy, Dr.-Ing. habil. Thomas Stegmaier, as Chief Sustainability Officer (CSO). In addition to this new role, Stegmaier will continue to provide his expertise to the Competence Center Textile Chemistry, Environment & Energy as Deputy Head.

The task of the Chief Sustainability Officer is to develop solutions to reduce the DITF's energy and resource consumption, promote renewable energies and implement efficient energy use. The management team, the operational organizational units and all employees are involved in the process.

The CSO also acts as a driving force for both the Executive Board and the research departments to promote sustainability issues.

The Lenzing Group has updated its climate targets to align with the goals of the Paris Agreement to limit the human-induced global temperature increase to 1.5 degrees Celsius. The Science Based Targets Initiative (SBTi) has reviewed and confirmed this target improvement.

By 2030, Lenzing aims to reduce its direct emissions from the production of its fiber and pulp plants (scope 1) and its emissions from purchased energy (scope 2) by 42 percent and its indirect emissions along the value chain (scope 3) by 25 percent on the way to net zero, from 2021 baseline. This corresponds to an absolute reduction of 1,100,000 tons (instead of the previously targeted 700,000 tons).

The following targets were recognized and confirmed by the SBTi:

1. Overall net-zero target: Lenzing AG commits to reach net-zero greenhouse gas emissions along the entire value chain by 2050.
2. Near-term targets: Lenzing AG commits to reduce absolute scope 1 and scope 2 greenhouse gas emissions by 42 percent by 2030 from a base year 2021. Lenzing AG also commits to reduce absolute scope 3 greenhouse gas emissions from purchased goods and services, fuels and energy-related activities as well as upstream transport and distribution by 25 percent within the same timeframe.
3. Long-term targets: Lenzing AG commits to reduce absolute scope 1 and scope 2 greenhouse gas emissions by 90 percent by 2050 from a base year 2021. Lenzing AG also commits to reduce absolute scope 3 greenhouse gas emissions by 90 percent within in the same timeframe.

These updated targets replace the old SBTi approved Lenzing Group’s climate target in 2019.

Growth, digitalisation and re-commerce – the forthcoming INNATEX (the international trade fair for sustainable textiles) is devoted to highly topical themes. From 20 to 22 January 2024 at the Messecenter Hofheim Rhein-Main near Frankfurt, over 200 exhibitors will be meeting up with retailers, experts and journalists. The motto for the winter trade fair is GROW, representing the call for sustainable, social and commercial growth that will not be possible without the green fashion movement.

Optimistic expectations despite the challenges
According to Alexander Hitzel, INNATEX Project Manager, and the organisers, MUVEO GmbH, various new trends are opening up that might, if exploited strategically, unlock new business areas. These range from ‘quiet luxury’, travel, internationalism and focused storytelling to services for specific target groups. On the Monday, members of the expert panel will be discussing re-commerce with the Hessen Retail Federation in the Community Lounge.

From storytelling to digital tools – the INNATEX themes
“Second-hand is in fashion,” says Julia Frings of IFH Köln. “Sales of used and recycled products have been on an upward trend for some years now and with the rising importance of sustainability, their relevance will continue to grow. There is great potential in this area for the trade to reach new target groups and expand the range on offer. To be successful, though, it is essential to have a concept tailored to the needs of consumers.”

Alongside Julia Frings of IFH Köln, other Federation panellists will include Steffen Riegel of Hessnatur. The first Lounge Talk at the start of INNATEX will deal with Strategies for Sensible Growth, borrowing from the motto for the fair. This topic will be followed by Fair Wages in the Global South, Storytelling as a Strategy, and Digital Trends.

Brand portfolio and partners of INNATEX
The collaboration with the Hessen Retail Federation, like that with Fashion Changers and Greenstyle Munich, has already proved its worth at previous fairs, as a way of adding variety to a well balanced fair programme. The new collaborative partners include AMD Academy of Fashion and Design (AMD) in Wiesbaden, the Fashion Campus 2030 Initiative and the Enterprise Europe Network (EEN, a network promoting internationalisation among smaller and medium-sized businesses).

The brand portfolio includes fashion for all generations, tastes and occasions. Labels exhibiting for the first time include businesses such as Fuza Wool from Denmark with its high quality traditional knitwear, and the hemp-based accessories of 8000Kicks from Portugal. The DESIGN DISCOVERIES comprise Anfisa Roumelidi, C/OVER and Consci.

Researchers at the ITA, the University of Bonn and Heimbach GmbH have developed a new method for removing oil spills from water surfaces in an energy-saving, cost-effective way and without the use of toxic substances. The method is made possible by a technical textile that is integrated into a floating container. A single small device can remove up to 4 liters of diesel within an hour. This corresponds to about 100 m2 of oil film on a water surface.
 
Despite the steady expansion of renewable energies, global oil production, oil consumption and the risk of oil pollution have increased steadily over the last two decades. In 2022, global oil production amounted to 4.4 billion tons! Accidents often occur during the extraction, transportation and use of oil, resulting in serious and sometimes irreversible environmental pollution and harm to humans.

There are various methods for removing this oil pollution from water surfaces. However, all methods have various shortcomings that make them difficult to use and, in particular, limit the removal of oil from inland waters.

For many technical applications, unexpected solutions come from the field of biology. Millions of years of evolution led to optimized surfaces of living organisms for their interaction with the environment. Solutions - often rather unfamiliar to materials scientists and difficult to accept. The long-time routine examination of around 20,000 different species showed that there is an almost infinite variety of structures and functionalities. Some species in particular stand out for their excellent oil adsorption properties. It was shown that, e.g., leaves of the floating fern Salvinia molesta, adsorb oil, separate it from water surfaces and transport it on their surfaces (Figure 1, see also the video of the phenomon.).

The observations inspired them to transfer the effect to technical textiles for separating oil and water. The result is a superhydrophobic spacer fabric that can be produced industrially and is therefore easily scalable.

The bio-inspired textile can be integrated into a device for oil-water separation. This entire device is called a Bionic Oil Adsorber (BOA). Figure 2: Cross-section of computer-aided (CAD) model of the Bionic Oil Adsorber. The scheme shows an oil film (red) on a water surface (light blue). In the floating cotainer(gray), the textile (orange) is fixed so that it is in contact with the oil film and the end protrudes into the container. The oil is adsorbed and transported by the BOA textile. As shown in the cross-section, it enters the contain-er, where it is released again and accumulates at the bottom of the container. See also the video regarding the oil absorption on the textile, source ITA).
 
Starting from the contamination in the form of an oil film on the water surface, the separation and collection process works according to the following steps:

• The BOA is introduced into the oil film.
• The oil is adsorbed by the textile and separated from the water at the same time.
• The oil is transported through the textile into the collection container.
• The oil drips from the textile into the collection container.
• The oil is collected until the container is emptied.

The advantage of this novel oil separation device is that no additional energy has to be applied to operate the BOA. The oil is separated from the surrounding water by the surface properties of the textile and transported through the textile driven solely by capillary forces, even against gravity. When it reaches the end of the textile in the collection container, the oil desorbs without any further external influence due to gravitational forces. With the current scale approximately 4 L of diesel can be separated from water by one device of the Bionic Oil Adsorber per hour.

• It seems unlikely that a functionalized knitted spacer textile is cheaper than a conventional nonwoven, like it is commonly used for oil sorbents. However, since it is a functional material, the costs must be related to the amount of oil removed. In this respect, if we compare the sales price of the BOA textile with the sales prices of various oil-binding nonwovens, the former is 5 to 13 times cheaper with 10 ct/L oil removed.
  Overall, the BOA device offers a cost-effective and sustainable method of oil-water separation in contrast to conventional cleaning methods due to the following advantages:
• No additional energy requirements, such as with oil skimmers, are necessary
• No toxic substances are introduced into the water body, such as with oil dispersants
• The textiles and equipment can be reused multiple times
• No waste remains inside the water body
• Inexpensive in terms of the amount of oil removed.
• The team of researchers from the ITA, the University of Bonn and Heimbach GmbH was able to prove that the novel biomimetic BOA technology is surprisingly efficient and sustainable for a self-controlled separation and automatic collection of oil films including their complete removal from the water. BOA can be asapted for open water application but also for the use in inland waters. Furthermore, it is promising, that the textile can be used in various related separation processes. The product is currently being further developed so that it can be launched on the market in 2-3 years.

Australia is one of the highest waste generators in the world, with over 7.6 million tonnes of food ending up in landfill each year, costing over $36.6 billion and producing 17.5 million tonnes of greenhouse gas.

Deakin’s partnership with Jet Technology through REACH will explore ways to transform industry-generated organic waste into new products like organic textiles and stock feed using a rapid composting system.

Jet Technology’s Environmental Recycling System (ERS) will build a circular economy by creating valuable products for a range of industry sectors.

Australia is continuing to generate more landfill each year. A new partnership between Deakin’s Recycling and Clean Energy Commercialisation Hub (REACH) and Japanese-based company Jet Technology aims to turn this around by repurposing organic waste and transforming it into new products.

Australia contributes more than 7.6 million tonnes of food to landfill annually, costing over $36.6 billion and producing 17.5 million tonnes of CO2.

Deakin University scientist Alfred Deakin Professor and Chair in Biotechnology Colin Barrow and his team from the Centre for Sustainable Bioproducts will work with Jet Technology to explore the possible reuses of organic waste using Jet Technology’s Environmental Recycling System (ERS). The project will focus on converting organic waste from the agriculture, dairy and fishery sectors by drastically shortening composting time so it can be used to make new products.

The four-year research project will be undertaken at the BioFactory at Deakin’s Waurn Ponds campus. It will initially focus on processing agricultural waste, converting apple pomace into a bioproduct for the textile industry. Apple pomace consists of the apple skin, pulp, seeds and stems left over from apple juice manufacturing. Its disposal in landfill can lead to greenhouse gas emissions and potential contamination of soil and groundwater.

If successful, it could lead to the establishment of a local multi-million-dollar bioeconomy where organisations such as councils, supermarkets and food and beverage businesses could cut costs while generating new revenue streams and job opportunities.

Deakin’s REACH initiative collaborates with progressive industry, government, and education partners to establish a multi-billion-dollar bioeconomy in Victoria and push the limits of technological innovation to deliver energy and recycling solutions that reduce landfill, fossil fuel emissions, and the devastating costs of global warming.

Deakin University has signed a partnership agreement with Geelong-based company Xefco as part of its Recycling and Clean Energy Commercialisation Hub (REACH) to conduct new research to transform how our clothing, including jeans, get their colour.

Jeans are one of the most worn garments in the world, but they are also one of the least environmentally friendly, taking around 75 litres of water to dye just one pair.

Deakin’s work with Xefco is helping to explore if a waterless manufacturing process can replace the water intensive processes the clothing industry has used for hundreds of years. The new technology in development is called ‘Ausora’.

Associate Professor Alessandra Sutti, from Deakin’s Institute for Frontier Materials, said it was exciting to be on the commercialisation journey with Xefco, working with the company to discover what is possible and hopefully reduce the world’s fashion footprint.

“If successful, the Ausora technology, which colours fabrics without the need for large quantities of water, will put us a step closer to more efficient and sustainable clothing manufacturing,” Associate Professor Sutti said.

Xefco CEO Tom Hussey said the company’s new pilot plant, housed at Deakin in Geelong, will test different materials, including specialised fabrics such as waterproof items like outdoor jackets and jeans.

“This is the first stage of Xefco’s vision for the technology, with the REACH project focused on demonstrating the commercial viability of the technology at pilot scale and developing processes so it can be scaled up for commercial production,” Mr Hussey said.

“Together, Deakin and Xefco will push the limits of innovation and see what is possible.”
Xefco’s pilot plant is co-located with Deakin researchers at ManuFutures, the state-of-the-art advanced manufacturing hub at Deakin’s Waurn Ponds campus.

Founded in 2018 Xefco now employs 17 people and its products are already making a difference across the world. Its XReflex technology, which reduces consumption of insulation materials, is being used by some of the world’s leading apparel and fashion brands including The North Face.

Backed by a $50 million grant from the Australian Government’s inaugural Trailblazer Universities Program, with industry and university support taking the total project value to $380 million, REACH is facilitating the development of greener supply chains and accelerating business success as markets move from a throughput economy to a circular economy.

To reach its goal of being the world’s leading supplier of enhanced recycled polyethylene terephthalate (PET), gr3n is signing a binding Memorandum of Understanding (MOU) with its shareholder Intecsa Industrial to set up a Joint Venture.

gr3n together with Intecsa Industrial will join forces and build a “First-of-a-Kind” manufacturing facility able to produce 40.000 tons of virgin-like PET, commencing EPC phase in Q4-2024 and aiming to be operational in 2027. gr3n’s chemical recycling technology is capable of processing PET from various industries including textile waste, closing the loop for hard-to-recycle PET applications.

The world’s first industrial-scale MADE PET recycling plant will have the capability to process post-industrial and post-consumer PET waste including hard-to-recycle waste, to produce approximately 40.000 tons of virgin PET chips from the recycled monomers saving nearly 2 million tons of CO2 during its operating life. The post-consumer and/or post-industrial polyesters will be both from bottles (colored, colorless, transparent, opaque) and textiles (100% polyester but also mixtures of other materials like PU, cotton, polyether, polyurea, etc. with up to 30% of presence in the raw textile).

The technical concept of the MADE plant is to break down PET into its main components (monomers) so they can potentially be re-polymerized endlessly to provide brand new virgin PET or any other polymer using one of the monomers. Polymers obtained can be used to produce new bottles/trays and/or new garments, essentially completely displacing feedstock material from fossil fuels, as the recycled product has the same functionality as that derived traditionally. This means that gr3n can potentially achieve bottle-to-textile, textile-to-textile, or even textile-to-bottle recycling, moving from a linear to a circular system.

gr3n’s process has the potential to change the way PET is recycled worldwide, enabling huge benefits for both the recycling industry and the entire polyester value chain. Many efforts have been made in the past to transfer enhanced recycling from research laboratories to the manufacturing industry, but the economics and skepticism of the first adopters have constantly blocked the progress of the proposed solutions. Thanks to the MADE technology developed by gr3n, this approach is now feasible and makes gr3n one of the few companies with the potential to provide a reliable enhanced recycling solution that closes the life cycle of PET, and also offers food grade polymer material, processes a large variety of waste and reduces the carbon footprint of these materials usually destined for incineration or landfill.

B.I.G. Yarns unveils its new “SustainableYarns” platform, with Clerkenwell Design Week visitors the first to be invited to get on board and focus on what matters most for the design and manufacture of sustainable soft floorings.

The expert in polyamide (PA) 1 step 3 ply yarns offers a range of options for manufacturers to introduce sustainable yarns into carpet solutions and reach sustainability targets faster and more efficiently.

The Sustainable Yarns range creates opportunities to design with recycled content yarn (EqoCycle), to work with renewable resources (EqoBalance), and, following the launch of new polyamide 6 (PA6) EqoYarn at Clerkenwell Design Week, to also leverage the low-impact value chain.

New addition EqoYarn is a new low-impact PA6 carpet yarn based on the most recent innovations in polymer production, which enable yarn manufacturers to lower their carbon footprint by nearly 50% and give carpet manufacturers more options to reduce their impact.

For its EqoYarn Bulk Continuous Filament (BCF) production process, B.I.G. Yarns has selected the few best-in-class partners that have made major steps forward in terms of sustainability, and reduced their greenhouse gas emissions thanks to continuous investments in process efficiency, green energy, heat optimization and waste reduction. The result is EqoYarn with a carbon footprint of 4 kg CO2 eq/kg yarns, which is a CO2 reduction of up to 50% compared to conventional PA yarns.

EqoBalance PA6 yarns enable customers to reach an even higher CO2 reduction of up to 75%. Manufactured with polymers made from renewable resources such as organic waste from cooking oil instead of virgin or fossil feedstock, these yarns have a carbon footprint of 1.98 kg CO2 eq./ kg yarns. They help carpet manufacturers to create products with an extremely low carbon footprint.

EqoCycle PA6 yarns are fully recyclable and incorporate 75% recycled content originating from recycled and regenerated PA6 granules. With a carbon footprint of 4.64 kg CO2 eq./ kg yarns, they deliver the same high-quality performance of virgin PA6 yarn with the benefit of 37% CO2 reduction. EqoCycle yarns offer carpet manufacturers a sustainable alternative to help reduce the ecological footprint of their products and move towards a circular economy without jeopardizing the end-product quality.

In addition to the different CO2-reducing options, B.I.G. Yarns’ customers can access an unlimited colour range to elevate their designs. Its BCF technology for polyamide yarns, twisted and heat-set yarns, one-colour to multi-colour, between 650 and 15000 dTex, along with its colour studio, are available to support their creation of customised collections.