Methods for determining the geographical origin and age of beach litter: Challenges and opportunities

Embargo until September 2, 2023.Beach litter analysis is a cost-effective tool to identify litter sources and subsequent management actions. However, standard beach litter protocols are not generally developed to identify litter's origins and age. Data from Svalbard (North Atlantic/ Arctic Ocean) were therefore used to explore reliable methods to fill this knowledge gap. Written text and country specific brands, as well as printed production or expiry dates proved the most efficient and reliable identifiers. The use of product design and logos considerably increased the proportion of items that could be sourced (by 19%) and dated (by 22%). The successful use of these is defined by the expertise of the analysing team and may introduce bias. The bias can be reduced by developing picture guides and involving stakeholders. The analyses showed that littering is on-going and that the area's major fishing nations, Norway and Russia, dominated the identified litter (38% and 14%, respectively).acceptedVersio

Beach litter sources around Nuuk, Greenland: An analysis by UArctic summer school graduate course students

Modeling studies illustrate the potential for long-range transport of plastics into the Arctic, although the degree to which this occurs remains relatively undocumented. We utilised a teaching exercise at a UArctic summer school graduate course in Nuuk, Greenland to conduct a preliminary in-depth analysis of beach litter sources in the Nuup Kangerlua fjord. Students and instructors collected and analysed 1800 litter items weighing 200 kg from one location in the fjord and another at its mouth. The results suggest a predominance of local sources to macrolitter, rather than long-range transport from Europe. Fisheries-related items and rope were common. Packaging which could be identified was largely suspected to be products distributed in Greenland, and soft plastics, which rarely disperse far from its source, were also common. The results suggest local measures to reduce mismanaged waste and emissions from fisheries are important for reducing marine litter in West Greenland.publishedVersio

Basic principles for development and implementation of plastic clean-up technologies: What can we learn from fisheries management?

Plastic pollution compromises ocean health, with large amounts of plastics continuing to enter marine and coastal environments. Various mitigative engineering solutions are being developed and implemented in response to this threat. While recognising the positive impacts of clean-ups, we highlight two perspectives given little attention to date, which are vital to evaluating the cost-benefit ratio of clean-ups: firstly, clean-up efficiency where density and accessibility of litter are key, and secondly, potential negative externalities that implementation of clean-up technologies may have. These principles, catch per unit effort and the impact on non-target species, are well known from fisheries management.We argue they should also be applied in evaluating marine litter removal schemes

Global marine litter research 2015–2020: Geographical and methodological trends

A systematic review of research on marine macrolitter densities in the past five years (2015–2020) revealed considerable knowledge gaps in the field. Nearly half he reviewed studies were on stranded litter. Data are scarce from many of the regions estimated to mismanage the largest amounts of plastic waste. In regions where data are available these are typically from coastal areas with few data from the high and deep seas; 57% and 87% of studies on pelagic and seafloor litter, respectively, took place within 100 km from shore. Data on pelagic litter are generally constrained to the sea surface and only two of 30 pelagic studies have measured macrolitter deeper in the water column. Reported litter densities are generally highest for stranded litter, although seafloor litter densities by weight are high in some areas. Reported densities of floating litter are several orders of magnitude lower. However, a lack of standardisation of methods makes it difficult both to assess and to compare litter densities within and across the different environmental compartments in time and space. The review illustrates a great need for survey design development within the field of macroplastics and point to some long-established considerations from ecological research pertaining to independence of data points, spatial autocorrelation, sampling scale, and plot size and shape which are highly relevant also for marine litter research. These considerations are relevant both for global standardisation efforts and for independent studies. Furthermore, the knowledge gaps created by geographic and compartment biases in research needs to be addressed to identify further research needs, validate models and inform policy.publishedVersio

Global marine litter research 2015–2020: Geographical and methodological trends

A systematic review of research on marine macrolitter densities in the past five years (2015–2020) revealed considerable knowledge gaps in the field. Nearly half he reviewed studies were on stranded litter. Data are scarce from many of the regions estimated to mismanage the largest amounts of plastic waste. In regions where data are available these are typically from coastal areas with few data from the high and deep seas; 57% and 87% of studies on pelagic and seafloor litter, respectively, took place within 100 km from shore. Data on pelagic litter are generally constrained to the sea surface and only two of 30 pelagic studies have measured macrolitter deeper in the water column. Reported litter densities are generally highest for stranded litter, although seafloor litter densities by weight are high in some areas. Reported densities of floating litter are several orders of magnitude lower. However, a lack of standardisation of methods makes it difficult both to assess and to compare litter densities within and across the different environmental compartments in time and space. The review illustrates a great need for survey design development within the field of macroplastics and point to some long-established considerations from ecological research pertaining to independence of data points, spatial autocorrelation, sampling scale, and plot size and shape which are highly relevant also for marine litter research. These considerations are relevant both for global standardisation efforts and for independent studies. Furthermore, the knowledge gaps created by geographic and compartment biases in research needs to be addressed to identify further research needs, validate models and inform policy

Using temperature-dependent embryonic growth models to predict time of hatch of American lobster, Homarus americanus, in nature

Hatch time of American lobster, Homarus americanus, varies between years and regions, which affects temperature experienced by the developing larvae and hence the time and distance these drift before settling. Hatch time can be assessed by working with fishermen and inspecting the brood of gravid females caught in their traps. However, this would require frequent sampling as the hatch period is protracted (â 7-12 weeks), and would require dedicated sampling in many regions where hatching occurs outside of the fishing season. To address these limitations, we tested the accuracy with which hatch time can be predicted by taking egg samples during the fishing season and estimating embryo development using embryonic eye size (Perkins Eye Index) and lab-derived temperature-dependent development functions. Using a linear development function and observed variability in Perkins Eye Index at hatch, we successfully predicted 100% of the observed 50-day hatch period, and 96% of predicted hatch dates fell within this period. Our results suggest that samples can be obtained in collaboration with fishermen to predict the timing and progression of hatch of American lobsterThe accepted manuscript in pdf format is listed with the files at the bottom of this page. The presentation of the authors' names and (or) special characters in the title of the manuscript may differ slightly between what is listed on this page and what is listed in the pdf file of the accepted manuscript; that in the pdf file of the accepted manuscript is what was submitted by the author

New knowledge for reduction and utilization of marine waste from fisheries (RE-D-USE)

The RE-D-USE project (“New knowledge for reduction and utilization of marine waste from fisheries”) was financed by the Norwegian Ministry for Climate and Environment through the Arctic 2030 programme and led by Nordland Research Institute. The project period was June 2017 – March 2019. The project has been a collaboration between Norwegian, Russian and Canadian researchers, fishers’ organizations, maritime schools and recycling businesses. A high portion of the marine litter in the Barents part of the Arctic relates to fisheries activities that threatens marine life, food safety and food security. The RE-D-USE-project has worked with fishers to identify causes and solutions related to marine waste from fisheries and has developed and tested an educational program for fishers to reduce waste and gear loss. RED-USE also investigated the potential for circular economy ventures based on marine waste as a resource. The project´s geographical focus has been the three northernmost counties of Norway and the Murmansk region in North-West Russia. RE-D-USE has had three work packages.publishedVersio

Female American lobster (Homarus americanus) size-at-maturity declined in Canada during the 20th and early 21st century

Changes in the environment and fishing have been shown to affect life-history characteristics, such as size or age of maturation, in a number of finfish and invertebrates. The American lobster, Homarus americanus, supports Canadaâ s most valuable fishery and exploitation rates are high. Female size-at-maturity (SM) is an important parameter in management of this species, as it is used in establishing minimum-legal-size regulations. In this study, we show with historic and recent data, that SM of female American lobsters has declined across most of Canada, in some areas by as much as 30%, over the past 10-80 years. The spatial patterns of these declines are inconsistent with patterns of rising ocean temperature and lobster abundance (density). They are, however, strongly correlated to the strength of size-based fishery selection, and egg-per-recruit modeling indicates a gain in lifetime egg production associated with observed SM declines under a range of realistic harvesting scenarios. These findings suggest that the marked decrease we document in SM of female American lobsters in Canada over the past century represents an evolutionary response to intense exploitation.The accepted manuscript in pdf format is listed with the files at the bottom of this page. The presentation of the authors' names and (or) special characters in the title of the manuscript may differ slightly between what is listed on this page and what is listed in the pdf file of the accepted manuscript; that in the pdf file of the accepted manuscript is what was submitted by the author

The Norwegian Environment Agency (NEA) aims to strengthen environmental monitoring of macroplastic and litter pollution in Norway. Macroplastic and litter are items above 25 mm. Monitoring of litter in the Northern Fulmar is included (1-25 mm) as this is an established indicator representing biota. The other environmental compartments covered in this report are coastal waters, oceans, lakes, rivers, and terrestrial environments. This report identifies international obligations and national needs

Prosjektleder Jannike Falk-AnderssonThe Norwegian Environment Agency (NEA) aims to strengthen environmental monitoring of macroplastic and litter pollution in Norway. Macroplastic and litter are items above 25 mm. Monitoring of litter in the Northern Fulmar is included (1-25 mm) as this is an established indicator representing biota. The other environmental compartments covered in this report are coastal waters, oceans, lakes, rivers, and terrestrial environments. This report identifies international obligations and national needs for knowledge on litter, reviews international harmonisation efforts for monitoring of litter and evaluates their technological readiness levels for implementation in monitoring programs. Data availability, on-going monitoring activities and initiatives that could contribute to collecting data on litter in Norway is mapped, and the cost of expanding existing monitoring is evaluated. Based on this mapping recommendations are given on how monitoring of macroplastic and litter could be strengthened in the future in Norway.Norwegian Environment AgencypublishedVersio