New lignin based material to replace fossil plastics and adhesives
Researchers at Stockholm University have developed a resource-efficient method to produce new lignin-based materials that can be thermally reprocessed and used to substitute thermosetting resins and adhesives.
Modern societies need to find alternatives to materials that are derived from fossil oil and gas resources. In parallel, there is an urgent need to develop enabling technologies for a transition to a sustainable circular economy. For example, thermosetting resins offer robust performance in today’s demanding applications, but unfortunately these synthetic plastics cannot be readily recycled.
Researchers at Stockholm University have developed a resource-efficient method to produce a material that behaves like thermosets but that can be thermally reprocessed. The team used lignin as the renewable raw material in a catalyst-free reaction with a non-toxic chemical derived from ethylene glycol. Lignin is a by-product from the pulp and paper industry, where it is mainly burned to recover chemicals and heat. However, there is a strong push to use lignin as a building block for new value-added materials that serve as carbon stocks during their lifetime.
"We were amazed by the performance of the new materials, and one of the striking aspects of our results is the simplicity and material-efficiency of the synthetic process. In contrast to earlier examples we do not need any chemical modification or fractionation of the lignin but can simply cook it with the cross-linker in a one-pot reaction"
Dr. Adrian Moreno at Stockholm University and one of the researchers behind the study, clarifies. The result is a black and plastic-like material that could be casted to various shapes using conventional technology such as injection moulding.
The new lignin-based materials can be used several times, which is central to future’s circular materials. To demonstrate this, the researchers measured mechanical strength of the pristine material as such and again from the same material that was reprocesses from the fractured sample. The mechanical strength was comparable to that of engineered plastics and remained unchanged after the reprocessing.
From single use to recoverable adhesives
The scientist also discovered that the material performance could be tailored from hard and brittle to soft and tough simply by changing the amount of lignin used in the formulation. “The ability to tune the material properties opens many opportunities to commercial applications. For example, the formulation containing 50 percent of lignin by weight is an excellent adhesive for several types of soft and hard materials”, Mohammad Morsali, PhD student at Stockholm University and one of the authors of the article, says.
“It is possible to recover the adhesive or simply detach the material and glue it again at mild temperatures comparable to those that are used in the kitchen oven”.
Lignin is one of the nature’s wonder materials that only recently has attracted attention as a candidate for advanced materials. “This is an excellent demonstration of the possibilities that lignin holds as a valuable feedstock. The material that we developed is perfectly in line with the current move towards sustainable circular materials. Owing to its design consisting of so-called dynamic covalent bonds, the material can be formed over and over again by relatively mild heating”, Assistant Professor Mika Sipponen explains.
A bright future for sustainable materials
The ongoing transition towards renewable and circular materials presents a considerable challenge because a large majority of the materials that we use in our everyday life are still made of fossil building blocks. According to Mika Sipponen there will also be many opportunities for involving students in the research projects, especially now that Stockholm University has launched a new MSc programme in Sustainable Chemistry. At the same time, there are exciting initiatives such as the Stockholm University Center for Circular and Sustainable Systems, SUCCeSS, that opens new possibilities for innovative materials chemistry.
“We see a great opportunity in this paradigm shift to phase out the fossil materials. It is evident that fresh ideas and collaboration across disciplines are needed to harness the true potential of lignin and other sustainable materials and eventually commercialize them”, Mika Sipponen says. It is this multifaceted aspect of our research that motivates us to work to solve some of the major challenges that are facing our generation.
The research has been published in ACS Applied Materials & Interfaces on 24 November 2021.
Read more on SUCCeSS, Stockholm University Center for Circular and Sustainable Systems: www.su.se/success
Mika Sipponen, Assistant Professor, Department of Materials and Environmental Chemistry, Stockholm University
Mail: email@example.com, Phone +468161258
Last updated: November 24, 2021