21.02.23 – Article on Dsolve in Korea JoongAng Daily
26.10.22 – Terje E. Martinussen new chairman of Dsolve
10.10.22 – Newsletter #2: First annual meeting of SFI Dsolve
07.07.22 – Newsletter #1
25.04.22 – Working to prevent plastic litter in the marine environment
06.04.22 – Dsolve on Lofotfishing
03.01.22 – Hermes has tested dolly ropes made of wood
10.11.21 – Defining status quo for the material flow of fishing gear on a national and regional level
14.10.21 – Dsolve partner LG-Chem teams up with TK Chemical to produce biodegradable plastics
23.09.21 – Isabelle Sande Chair of the SFI Dsolve
13.05.21 – Combating marine waste and ghost fishing with new materials (Gemini)
30.04.21 – Bionedbrytbare garn kan være i utstrakt bruk om åtte år (Teknisk Ukeblad)
28.04.21 – NRK Radio Troms, morgensending (01:29:39)
28.04.21 – Åpning av Dsolve – Senter for utvikling av bionedbrytbar plast i marine applikasjoner
28.02.21 – Forurenser bør betale – også for plast i havet (Fiskeribladet)
16.02.21 – Nedbrytbar plast kan stoppe plastforsøpling fra fiskeri (UiT.no)
15.01.21 – Hvor mye mikroplast kommer fra slitasje på fiskeredskap? (Fiskeridirektoratet)
24.11.20 – "Tidsinnstilt» plast skal ta spøkelsesfisket og mikroplasten ved roten (Fiskeribladet)
24.10.20 – Vi skal bekjempe plastforsøpling i havet med bionedbrytbar plast (Forskersonen.no)
27.06.20 – Tar grep for å sikre dyrevelferden i havet (itromso.no)
This research area will develop a range of biodegradable plastic materials with controlled biodegradability and the properties needed for products used in the fishing and aquaculture industries.
The main objective of this work package is to develop a range of biodegradable plastic materials with controlled biodegradability and the properties needed for products used in fishing and aquaculture industries (e.g., twines and netting, ropes, gillnets, coatings, pots and traps, foils and boxes, pipes and connectors). The developed materials shall meet a range of processing and performance requirements, including biodegradability.
Biodegradable polymers shall be modified using well known approaches such as upgrading with additives, blending with other polymers and compatibilization. Controlled biodegradability will be developed by identifying additional components that may promote or delay biodegradation mechanisms. In addition, new product design strategies shall be developed and tested. In such concepts, the surface material is developed to meet the performance needs and the bulk material is designed to provide fast degradation after the service life. The bulk material can be the same as the surface material but may contain suitable additives for faster degradation or it can be a different material with fast degradation. Further, commercially available biodegradable additives and enzymes shall be evaluated. Furthermore, surface coating concepts shall also be developed and evaluated.
The key research and development tasks are:
Task 1.1 – Biodegradable polymers – general knowledge
Task 1.2 – Biodegradable polymer material concepts for fiber applications (twines, netting, ropes, etc.)
Task 1.3 – Biodegradable polymer material concepts for injection molding applications (pots, traps, boxes, etc.)
Task 1.4 – Biodegradable polymer material concepts for coating applications (steel rope coatings)
Task 1.5 – Potential microplastics formation from biodegradable plastics
Task 1.6 – Establish new collaborations
Task 1.7 – New material and design concepts for polymer materials in selected applications in fishing and aquaculture
Norner Research will work closely with DSOLVEs R&D and industry partners in other AREAS in order to develop biodegradable materials that meet requested performance requirements including biodegradability. Norner Research will also evaluate end-of-life options for fishing gear collected on land after service time. Norner Research will evaluate results and implement learnings in an iterative process throughout the project period.
This research area will create a sustainable framework for testing biodegradability and environmental impact. Lab and field testing will be carried out in conditions representing different marine environmental factors. Marine biodegradation will be tested in different marine habitats and climate zones, and biodegradable and conventional tools be compared.
Problems associated with marine plastic litter caused by the fishery and aquaculture sectors can be significantly reduced if traditional plastics like Polyethylene (PE) or Polyamid (PA) in these sectors are replaced by new biodegradable materials. As shown in previous studies, these biodegradable materials are intended to degrade or decompose after a certain period under water and thereby lose their ghost fishing capacity more quickly than conventional gear. However, small-scale tests have revealed that further research and industrial development is necessary for the commercialization and incorporation of biodegradable plastics in these ocean-based industries. It was shown that biodegradable gillnets experienced a 10-20% strength reduction due to a degradation after one year at sea without leaving traces of microplastics. However, biodegradable gillnets had a 10-15% poorer fishing efficiency than traditional gillnets.
To address this issue, work package 2 will create a framework for testing of biodegradability and environmental impacts. Lab and field testing of biodegradable fishing gear (twine, ropes, nets, etc.) will be carried out in conditions representing different marine environmental conditions. The physical and chemical integrity and degradation of biodegradable and conventional nets and twines will be evaluated during an extended test period (5 years or full degradation) starting in 2021. Marine biodegradation of nets and twines (biodegradable polymers as the test and non-degradable PA/PE as the control) will be tested in situ in different marine habitats (seafloor, water column) in different climate zones (Skagerrak Sea, North Sea, Baltic Sea, Adriatic Sea, and Norwegian Sea) to cover a wide temperature range of 4 to 27°C. The test conditions will be carefully monitored any changes in the physical and chemical properties of the used materials (surface changes, mechanical properties and change in chemical compositions). The long-term study of biodegradable polymers and fossile polymers as reference materials will make an important contribution to a better understanding of the degradation of polymers in the sea and the degradation mechanisms. In this context, the microbiological, UV, thermal, and chemical degradation will be studied in detail. The tailoring of mechanical properties of the materials used for fishing gear and the degradation as well as its processes will be addressed.
Starkova O., Gagani A., Karl C., Rocha I., Burlakovs J., Kraukalis A. (2022). Modelling of Environmental Ageing of Polymers and Polymer Composites—Durability Prediction Methods. Polymers 2022, 14(5), 907.
Kraukalis A., Karl C., Rocha I., Burlakovs J., Ozola-Davidane R., Gagani A., Starkova O. (2022). Modelling of Environmental Ageing of Polymers and Polymer Composites—Modular and Multiscale Methods. Polymers 2022, 14(1), 216.
The industry will need robust and convincing results before production, sales, and practical use (fishing) on a large scale can take place. We expect that identification of accurate needs, development of products, and testing (documentation) will take several years for each research area. Furthermore, a change from traditional to new smart biodegradable materials must include performance, catch pattern, and efficiency analyses (in the case of fishing gears) of existing and new technology. Sea trials will be conducted in Norway, Denmark, Germany and Croatia.
The key research and development tasks are:
Task 3.1: For gillnets (inshore and deep-sea gillnetting), find a combination of strength/elasticity and catchability that is comparable to or better than existing PA twines during multiple trials conducted on board commercial gillnetters;
Task 3.2: Develop pots and traps based on biodegradable materials targeting brown crab, snow crab, red king crab, and lobster, including recreational pot fisheries;
Task 3.3: Develop biodegradable ropes and components for coastal and deep sea longlines, because millions of nylon and polyester snoods are used every season and a large proportion of these get lost at sea;
Task 3.4: Identify several possibilities for replacing PE, PA, and PES fibres with biodegradable fibres for use in twines, ropes, and netting (all fishing gears), as all fishing gears and aquaculture equipment are composed of a range of twines with various tensile strengths, abrasion resistance, twine surface area, etc.;
Task 3.5: Full-scale tests of dolly-ropes and chafing mats for use in demersal (bottom) trawling;
Task 3.6: Develop an alternative to combination ropes (30–60 mm thick PE coating with steel-wire core) for demersal seining; while they help to herd fish, thus increasing catch efficiency, they lose almost half their mass as microplastics during their service time due to abrasion by the seabed.
Testing in the Norwegian, North, Baltic, and Adriatic Seas will ensure that we obtain data about the performance of biodegradable twines and ropes, the catch efficiency of nets, and how degradation varies in relation to different environmental conditions. This will enable extrapolation to other fisheries and help to promote use of biodegradable fishing gears internationally. In Norway, sea trials will be conducted under commercial conditions on board fishing vessels. Catch comparison analysis will be based on comparing length size distributions of species caught and will be carried out using appropriate software and following published statistical methods and models. Catch quality will be assessed if needed. Assessing the extent of unaccounted for fishing mortality of gillnets and pots will be conducted by simulating lost gears in pre-defined and controlled areas. Full-scale testing will be conducted by building codends with dolly-ropes made of conventional PE rope and bio ropes. The codends will be fished simultaneously in a twin trawl setup and used by a trawler during an entire fishing season. Researchers will weigh the amount (and measure the length) of dolly-ropes in the codend before and after the fishing trials, and they will measure the length of the dolly-rope fibres monthly. In Denmark, Germany, and Croatia, a similar methodology will be used to evaluate catch efficiencies and gear degradation.
This research area will assess the economic effects of non-biodegradable materials used in fisheries and aquaculture and evaluate the costs and benefits related to ecosystem services from introducing biodegradable materials in the marine industries. Further analyse institutional incentive mechanisms, and assess public support systems to reduce risk and promote implementation of biodegradable innovations.
Little is known about the consequences of using biodegradable versus non-biodegradable materials in fisheries and aquaculture industries. This lack of knowledge relates to the environments where these industries operate, the costs and benefits involved, and potential management and governance approaches of relevance for policy goals.
We will assess the economic effects of non-biodegradable materials used in fisheries and aquaculture, evaluate the costs and benefits related to ecosystem services from introducing biodegradable materials in the marine industries, and analyse institutional incentive mechanisms to increase the use of biodegradable applications. Furthermore, we will assess public support systems to reduce risk and promote implementation of biodegradable innovations.
Comparative economic studies between non-users and users of biodegradable gears in fisheries and aquaculture, and studies on regulatory changes needed to enhance the use of biodegradable materials in these industries will be developed. In fisheries this involves biological dynamics, catch efficiency and market performance, and must be studied in state-of-the-art bioeconomic models. The aquaculture production setting is very different, while materials in gears and equipment to some extent can be compared. Waste and discards are problems in both industries but in different ways requiring different approaches for analysis. Furthermore, we will study governance structures and how to promote incentives in the use of biodegradable plastics in fisheries and aquaculture by management means. Since use of biodegradable input factors will likely increase internal factor costs, while the external costs may be expected to decline, institutional incentives and other regulations will be needed in order to reduce the use of plastics.
This research area will develop sustainable circular solutions for existing non-degradable and future biodegradable fishing gear. The goal is to develop environmentally sustainable value chains which also take the level of circularity into account.
The work will be based on LCA (Life Cycle Assessment) methodology, an established method that evaluates the environmental burdens associated with a product system by identifying and describing the energy and material uses and releases into the environment. An LCA includes the entire life cycle of the product, from raw material extraction, through materials processing, transport, use and disposal or recycling at the end of the product's life (from "cradle to grave" or “cradle to cradle”). LCA can be used to understand if changes in one part of a product life cycle can lead towards greater overall sustainability. It focuses on the function(s) that the product system fulfils. LCA does not currently account for the impacts of plastic losses in value chains (e.g., littering). Hence, the issue of how macro and microplastic emission data are translated into environmental impacts represents a knowledge gap in the international LCA field.
Key research tasks in research area 5 are:
Sadeleer I., Askham C., Alnes R. B. (2021). Defining status quo for the material flow of fishing gear on a national and regional level
This research area will develop and carry out a dynamic plan for outreach through communication, dissemination and exploitation of results in order to maximise the impact of the project results.
The aim of this research area is to develop and carry out a dynamic plan for outreach through communication, dissemination, and exploitation of results in order to maximise the impact of the results from Dsolve. A plan for communication, dissemination and exploitation of results (DEP) is to be developed in the beginning of the CRI and updated on a regular basis during the centre's life span. The plan is to include not only plans for suitable conferences, trade fairs, and national and international exhibitions, but also specifications about the promotion channels to be used, the timing for awareness raising about results, and the responsible partner. The outcomes of this area will include seminar and workshop proceedings, a public website, presentations at major events, publications in specialised and extension journals and magazines, a collection of press releases, video production, asocial media strategy (SoMe), and public datasets used in the CRI. Dialogue with affected industries and stakeholders through seminars, workshops, and networking will be emphasized. Existing meeting arenas within the industry and networks, will be used for effective outreach to industry and stakeholders.
Key tasks are
Task 6.1: Dissemination activities
Task 6.2: Communication activities
Task 6.3: Exploitation of results
Do, H.-L., & Armstrong, C. W. (2023). Ghost fishing gear and their effect on ecosystem services – Identification and knowledge gaps. Marine Policy, 150, 105528.
Askham, C., Pauna, V. H., Boulay, A.-M., Fantke, P., Jolliet, O., Lavoie, J., Booth, A. M., Coutris, C., Verones, F., Weber, M., Vijver, M. G., Lusher, A., & Hajjar, C. (2023). Generating environmental sampling and testing data for micro- and nanoplastics for use in life cycle impact assessment. Science of The Total Environment, 859, 160038.
Brakstad O. G., Sørensen L., Hakvåg S., Føre H. M., Su B., Aas M., Ribicic D., Grimaldo E. (2022). The fate of conventional and potentially degradable gillnets in a seawater-sediment system. Marine Pollution Bulletin 180, 2022.
Cerbule K., Savina E., Herrmann B., Larsen R. B. , Feekings J. P., Krag L. A. (2022). Quantification of catch composition in fisheries: A methodology and its application to compare biodegradable and nylon gillnets. Journal for Nature Conservation 2022.
Cerbule K., Herrmann B., Grimaldo E., Larsen R. B., Savina E., Vollstad J.: Comparison of the efficiency and modes of capture of biodegradable versus nylon gillnets in the Northeast Atlantic cod (Gadus morhua) fishery. Marine Pollution Bulletin 2022.
Cerbule K., Grimaldo E., Herrmann B., Larsen R. B., Brčić J., Vollstad J.: Can biodegradable materials reduce plastic pollution without decreasing catch efficiency in longline fishery? Marine Pollution Bulletin 2022.
Brinkhof I. (2022). How does twine thickness and mesh size affect catch efficiency and ways of capture in the Northeast Arctic cod (Gadus morhua) gillnet fishery? Master’s thesis, UiT 2022.
Alnes R. (2022). Investigating dynamic quantum of plastics from Fishing Gear in Norway. Master’s thesis in Energy and Environmental Engineering, NTNU 2022
Starkova O., Gagani A., Karl C. W., Rocha I., Burlakovs J., Krauklis A. (2022). Modelling of Environmental Ageing of Polymers and Polymer Composites—Durability Prediction Methods. Polymers 2022, 14(5), 907.
Krauklis A., Karl C. W., Rocha I., Burlakovs J., Ozola-Davidane R., Gagani A., Starkova O. (2022). Modelling of Environmental Ageing of Polymers and Polymer Composites—Modular and Multiscale Methods. Polymers 2022, 14(1), 216.
Sadeleer I., Askham C., Alnes R. B. (2021). Defining status quo for the material flow of fishing gear on a national and regional level
Standal D., Grimaldo E., B. Larsen R. (2020). Governance implications for the implementation of biodegradable gillnets in Norway. Marine policy, Volume 122.
Grimaldo E., Herrmann B., Jacques N., Vollstad J., Su B. (2020). Effect of mechanical properties of monofilament twines on the catch efficiency of biodegradable gillnets. PLOSONE
Grimaldo E., Herrmann B., Vollstad J., Su B., Moe-Føre H., Larsen R.B. (2019). Comparison of fishing efficiency between biodegradable gillnets and conventional nylon gillnets. Fish. Res. 213: 67–74.
Su B., Føre H., Grimaldo E. (2019). A Comparative Study of Mechanical Properties of Biodegradable PBSAT and PA Gillnets in Norwegian Coastal Waters. OMAE2019-95350, V004T03A001.
Grimaldo E., Herrmann B., Tveit G., Vollstad J., Schei M. (2018a). Effect of using biodegradable PBSAT gillnets on the catch efficiency and quality of Greenland halibut (Reinhardtius hippoglossoides). Mar. Coast. Fish. 10: 619–629.
Grimaldo E., Herrmann B., Vollstad J., Su B., Moe-Føre H., Larsen R.B. (2018b). Fishing efficiency of biodegradable PBSAT gillnets and conventional nylon gillnets used in Norwegian cod (Gadus morhua) and saithe (Pollachius virens) fisheries. ICES J. Mar. Sci. 75(6): 2245–2256.
Biodegradability of Plastics in the Open Environment / European Commission
Plastic pollution: 14 million tonnes of microplastic on ocean floor / BBC
Ocean Solutions that Benefit People, Nature and the Economy / Oceanpanel.com
Waste Management on Fishing Vessels and in Fishing Harbors in the Barents Sea: Gaps in Law, Implementation and Practice / Taylor & Francis Online
Our ambition is to place Norway at the forefront of research, development and use of smart biodegradable materials to reduce the global problem of marine litter caused by the use of plastic in fisheries and aquaculture.
The centre will develop research-based solutions and help the industry to develop sustainable innovations for the global market, including:
Our focus areas are:
Data management plan Partners Annual report 2020 Annual report 2021 Annual report 2022
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