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Not just Good Chemistry

Design at All Levels and for All Stages of Life Going Beyond Sheer Circulation is Key for Chemistry and its Products
  • Klaus Kümmerer

    Klaus Kümmerer

    Klaus Kümmerer <klaus.kuemmerer@uni.leuphana.de> is from the Institute of Sustainable Chemistry, Leuphana University Lüneburg, Lüneburg, Germany; and International Sustainable Chemistry Collaborative Centre, Research and Education Hub, Leuphana University Lüneburg, Lüneburg, Germany; https://orcid.org/0000-0003-2027-6488

     EMAIL logo     and Vânia G. Zuin-Zeidler

    Vânia G. Zuin-Zeidler

    Vânia G. Zuin-Zeidler <vania.zuin@leuphana.de> is from the Institute of Sustainable Chemistry; Green Chemistry Centre of Excellence, University of York, UK; and Department of Chemistry, Federal University of São Carlos, Brazil; https://orcid.org/0000-0003-4452-4570

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Published/Copyright: August 16, 2022
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Chemistry International
From the journal Chemistry International Volume 44 Issue 3

Abstract

Chemistry as a science and an industrial sector plays a determining and indispensable role in all parts of our lives as it is the only science that can change matter (apart from nuclear physics). What we call a chemical product is often highly complex; elements and chemicals are most often applied as mixtures in products. For example, there are several hundred grades of steel (i.e. iron alloys) marketed. Electronics relies on many complex materials. Other examples of products are pesticides, pharmaceuticals, biocides, laundry detergents, personal care products and many others composed of several chemicals each. Estimates indicate that the number of chemicals in use today exceeds 340 000 worldwide. There are many kinds of polymers. The polymers themselves are made-up by manifold building blocks of different size, stereochemical arrangement, functional groups, branched or interlinked segments, etc. Today more than 10 500 plastic-related additives are in use. Often during synthesis, manufacturing, and use, and at the end of their lives, all these materials and products are transformed (“degraded“), resulting in new chemical entities of often unknown properties, impact on the product and toxicity. In other words, at all stages of the chemical products lifespan there is enormous chemodiversity, from the atomic to the molecular, from material to building blocks and products, as well as in sectors of applications and usage. Owing to their high diversity and adaptability, chemicals and synthetic materials are literally used everywhere nowadays.

The downside of this impressive success story is that chemical products are ubiquitous in places also where we do not want to have them, i.e. in human beings, organisms and the environment. Another downside is an increasing shortage of resources and an increase in waste and an increase in energy demand. One attempt to address issues of a shortage of resources, waste and pollution simultaneously is the concept of Circular Economy (CE).

To understand chemistry as an important building block of a future CE, we must understand CE prerequisites, opportunities, and limitations from a chemical point of view. Chemical products (and the downstream products containing them) need to be designed from the very beginning for both circulation and later recycling. This includes design for easy use and further reuse, collection, as well as physical and chemical dismantling and separation processes; all this to keep unintended losses as low as possible. Just applying “good chemistry“ is not sufficient by far. Chemistry, in the broadest sense, has to fit into a CE. If a broader view is taken, there can only be down-cycling, and no up-cycling. Recycling is governed by thermodynamics, i.e., entropy increases. For example, to gain the desired quality of the products of recycling, fresh or virgin material needs to be added often (e.g. alloys, aluminum, fibres for textiles and paper, and polymers and additives in case of plastics). In order to lose as little as possible of materials and to generate as little entropy as possible, we need to avoid unsustainable extraction, mixing and separation, and upgrading processes including the obtention of natural and renewable resources such as (bio)waste. Therefore, we have to design both products and processes for as simple as possible. This relates—among other things—to the chemical structure and its change, as well as the composition of related material flows. Extreme efficiency (either maximal or minimal) may result in rebound effects, when optimization is preferable. The cradle to cradle thinking that everything is abundant and easily available “food” within the technosphere would result in an economy where efficiency is not be taken into consideration. This thinking denies thermodynamic principles which also apply. It is guided by a misunderstanding of natural cycles: in contrast to the matter flows in the technosphere, those in nature consist of a few basic building blocks only and low chemodiversity.

There are always unavoidable losses of products or their constituents during their lifetime, as by thermal degradation in the case of moulding thermoplastics, unintended disaggregation (e.g. plastics and additives) or abrasive losses (e.g. tyres, paint, metal corrosion, and facades). These products cannot be collected and therefore neither can they be recycled. In addition, the use of many chemical products is linked to their direct introduction into the environment (e.g. surfactants and other constituents of laundry powder, pesticides, biocides, personal care products, and pharmaceuticals). For these, a design for full and fast environmental degradation, i.e. mineralisation, is necessary.

This demonstrates that CE in its different forms is neither necessarily a greener nor a more sustainable contribution of chemistry to a more sustainable future. A broader system thinking-based view accounting for needed service and function is integral part of sustainable chemistry (“chemistry for sustainability“). Different behaviours and business models that focus on knowledge instead of tonnage can reduce the number and the amount of chemicals and chemical products. If the desired service and function can only be delivered requiring chemical products, we should aim to making them fit into a CE (“chemistry within a circular economy”). The synthesis and properties of these chemicals and products must be aligned with the principles of green chemistry then, in fact “greener chemicals.”

Becoming more sustainable means to design for less diversity, less complexity, and lower tonnage. This may be the biggest challenge for chemistry and chemists, as the character of chemistry is to invent or to introduce new molecules, materials, and products by changing matter.

The 2030 Agenda for Sustainable Development, adopted by all United Nations Member States in 2015, provides a shared blueprint for peace and prosperity for people and the planet, now and into the future. At its heart are the 17 Sustainable Development Goals (SDGs), which are an urgent call for action by all countries—developed and developing—in a global partnership. Reprinted from [1]. Additional Goal 12 infographic, source: https://unstats.un.org/sdgs/report/2021/

The 2030 Agenda for Sustainable Development, adopted by all United Nations Member States in 2015, provides a shared blueprint for peace and prosperity for people and the planet, now and into the future. At its heart are the 17 Sustainable Development Goals (SDGs), which are an urgent call for action by all countries—developed and developing—in a global partnership. Reprinted from [1]. Additional Goal 12 infographic, source: https://unstats.un.org/sdgs/report/2021/

Über die Autoren

Klaus Kümmerer
Klaus Kümmerer

Klaus Kümmerer

Klaus Kümmerer <> is from the Institute of Sustainable Chemistry, Leuphana University Lüneburg, Lüneburg, Germany; and International Sustainable Chemistry Collaborative Centre, Research and Education Hub, Leuphana University Lüneburg, Lüneburg, Germany; https://orcid.org/0000-0003-2027-6488

Vânia G. Zuin-Zeidler
Vânia G. Zuin-Zeidler

Vânia G. Zuin-Zeidler

Vânia G. Zuin-Zeidler <> is from the Institute of Sustainable Chemistry; Green Chemistry Centre of Excellence, University of York, UK; and Department of Chemistry, Federal University of São Carlos, Brazil; https://orcid.org/0000-0003-4452-4570

Further Reading

1. United Nations. The 17 Sustainable Development Goals. https://sdgs.un.org/goalsSearch in Google Scholar

2. European Commission. Environment: Waste and recycling. https://ec.europa.eu/environment/topics/waste-and-recycling_enSearch in Google Scholar

3. Zuin, V. G. Circularity in green chemical products, processes and services: innovative routes based on integrated eco-design and solution systems. Curr. Opin. Green Sustain. Chem.2, 40-44 (2016). http://doi.org/10.1016/j.cogsc.2016.09.00810.1016/j.cogsc.2016.09.008Search in Google Scholar

4. Kümmerer, K., D. Dionysiou, D., Olsson, O., Fatta-Kassinos, D. A path to clean water. Science361, 222-224 (2018). http://doi.org/10.1126/science.aau2405.10.1126/science.aau2405Search in Google Scholar PubMed

5. Zuin, V. G.; Ramin, L. Z. Green and sustainable separation of natural products from agro-industrial waste: challenges, potentialities, and perspectives on emerging approaches. Top. Curr. Chem.376, 1-54, (2018). https://doi.org/10.1007/s41061-017-0182-z10.1007/s41061-017-0182-zSearch in Google Scholar PubMed PubMed Central

6. Kümmerer, K., Clark, J. H., Zuin, V. G. Rethinking chemistry for a circular economy. Science367, 369-370 (2020). http://www.science.org/doi/10.1126/science.aba497910.1126/science.aba4979Search in Google Scholar PubMed

7. Zuin, V. G.; Eilks, I. ; Elschami, M. ; Kummerer, K. Education in Green Chemistry and in Sustainable Chemistry: perspectives towards sustainability. Green Chem.23, 1594–1608 (2021). https://doi.org/10.1039/D0GC03313H10.1039/D0GC03313HSearch in Google Scholar

8. Zuin, V. G.; Kümmerer, K. Chemistry and materials science for a sustainable circular polymeric economy. Nat. Rev. Mater.7, 76–78 (2022). https://doi.org/10.1038/s41578-022-00415-210.1038/s41578-022-00415-2Search in Google Scholar PubMed PubMed Central

9. Schnarr, L.; Segatto, M. L.; Olsson, O.; Zuin, V.G.; Kümmerer, K. Flavonoids as biopesticides – Systematic assessment of sources, structures, activities and environmental fate. Sci. Total Environ.824, 1-13 (2022). https://doi.org/10.1016/j.scitotenv.2022.15378110.1016/j.scitotenv.2022.153781Search in Google Scholar PubMed

Online erschienen: 2022-08-16
Erschienen im Druck: 2022-07-01

©2022 IUPAC & De Gruyter. This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License. For more information, please visit: http://creativecommons.org/licenses/by-nc-nd/4.0/

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https://doi.org/10.1515/ci-2022-0305

Articles in the same Issue

  1. Masthead - Full issue pdf
  2. Treasurer's Column
  3. Wir schaffen das!
  4. Features
  5. The Garden Party at Wiltzangk
  6. The 2021 IUPAC World Chemistry Leadership Meeting
  7. Benign by Design
  8. Not just Good Chemistry
  9. TSAW—a lifelong challenge or simply an unsolved mystery?
  10. IUPAC Wire
  11. Winners of the 2022 IUPAC-Solvay International Award for Young Chemists
  12. Hanwha-TotalEnergies IUPAC Young Polymer Scientist Award 2022
  13. 8th Polymer International-IUPAC Award Goes to Zachary Hudson
  14. 2023 Distinguished Women in Chemistry/Chemical Engineering Award—Call for Nominations
  15. GWB2023 Sponsorship Opportunities
  16. Scientific Editor for Pure and Applied Chemistry—Call for Nominations
  17. IUPAC Centenary Endowment Board—Call for members
  18. IUPAC Blue Book
  19. IUPAC Emeritus Fellows
  20. Project Place
  21. Terms for Mechanisms of Polymer Growth
  22. Digital Representation of Units of Measurement
  23. IUPAC Green Book—Update and More
  24. Making an imPACt
  25. Seabed mining and blue growth: exploring the potential of marine mineral deposits as a sustainable source of rare earth elements (MaREEs) (IUPAC Technical Report)
  26. Standard atomic weights of the elements 2021 (IUPAC Technical Report)
  27. Terminology and the naming of conjugates based on polymers or other substrates (IUPAC Recommendations 2021)
  28. Glossary of terms used in physical organic chemistry (IUPAC Recommendations 2021)
  29. Synthesis design using mass related metrics, environmental metrics, and health metrics
  30. Bookworm
  31. Cheminformatics: Data and Standards
  32. Systematic Nomenclature of Organic, Organometallic and Coordination Chemistry. Chemical-Abstracts Guidelines with IUPAC Recommendations and Many Trivial Names
  33. Conference Call
  34. InChI Open Meeting
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