Commercial fishing, Inuit rights, and internal colonialism in Nunavut

This paper considers the degree to which the concept of ‘internal colonialism’ accurately describes the political economy of Nunavut’s commercial fisheries. Offshore fisheries adjacent to Nunavut were initially dominated by institutions based in southern Canada, and most economic benefits were captured by southern jurisdictions. Decades of political struggle have resulted in Nunavut establishing a role for itself in both the management of offshore resources and the operation of the offshore fishing industry. However, key decisions about fishery management are made by the federal government, and many benefits from Nunavut’s offshore fisheries continue to accrue to southern jurisdictions. The concept of internal colonialism is therefore a useful concept for understanding the historical development and contemporary conflicts over offshore fisheries. By contrast, Nunavut’s inshore fisheries were established as community development initiatives intended to promote economic well-being and stability. While inshore fisheries primarily benefit Inuit community economies, the growth of inshore fisheries has been hampered by small profit margins, inadequate marine infrastructure, and a dearth of baseline data. The federal government’s failure to support the expansion of inshore fisheries is a manifestation of internal colonialism, insofar as it reflects an unequal distribution of public infrastructure and research.

Household Workers Profile System

Estancia is well-known throughout the country as a commercial fishing center, so much so that it shares the name Alaska of the Philippines. It is located in the northern part of the province and is 131 kilometer’s (81 mi) from the provincial capital, Iloilo City. Estancia is politically subdivided into 25 barangays. According to the 2015 Census, it has a population of 48,546 people. This accounted for 2.51% of the total population of Iloilo province, or 0.64 percent of the Western Visayas region's total population. As technology advances, so do the hectic schedules that leave little time for household chores. Aside from tasks, there are other aspects of our everyday lives that are significant. People don't have enough time to take care of their homes, so hiring a housekeeper can assist. Many families place too much emphasis on word-of-mouth referrals and basic background employment.

Integrated conservation of the Whenua Hou Diving Petrel

<p>Seabirds are one of the most threatened taxa on the planet. These species are also considered ecosystem engineers. Therefore, seabirds are of particular conservation interest. One of the most threatened seabirds is the critically endangered Whenua Hou Diving Petrel (Pelecanoides whenuahouensis; WHDP). The WHDP is restricted to a minute (0.018 km2) breeding colony on a single island — Whenua Hou (Codfish Island), Aotearoa (New Zealand). The WHDP population was estimated at 150 adults in 2005. The WHDP is threatened by storms and storm surges, which erode its breeding habitat (fragile foredunes), and potentially by competition for burrows with congenerics. I aimed to inform suitable conservation strategies for the WHDP. I first quantified the efficacy of past conservation actions (eradications of invasive predators). I compiled burrow counts across four decades to estimate and compare population growth before and after predator eradications. I then investigated offshore threats using tracking data to quantify WHDP offshore distribution, behaviour, and overlap with commercial fishing efforts. Subsequently, I estimated the potential impact and success of WHDP translocations. Specifically, I combined capture-recapture, nest-monitoring, and count data in an integrated population model (IPM) to predict the impact of harvesting chicks for translocations on the source population and to project the establishment of a second population. I then informed future translocation protocols using nest-monitoring data to quantify nest survival and breeding biology. Finally, I tested if WHDP presence had a positive influence on unrelated species groups. I counted two skink species at sites with and without burrows and used occupancy modelling to quantify the influence WHDP burrows had on skink occurrence. Estimates of population growth before and after predator eradications illustrated that WHDP population growth remained comparatively low and unaffected by this conservation strategy. Therefore, additional interventions are required. WHDP tracking revealed that the non-breeding distribution did not overlap with commercial fishing efforts. However, considerable fishing efforts were present within the breeding distribution. Despite these findings, onshore threats remain present and conservation strategies aimed at addressing terrestrial threats may be more feasible. Results from my IPM showed that translocations could successfully establish a second WHDP population without impacting the source excessively, provided translocation cohorts remain small and translocations are repeated over long time periods (5-10 years). Nest survival was not clearly influenced by interannual variation, distance to sea, and intra- or interspecific competition. Furthermore, I informed future translocation protocols by identifying the preferred harvest window, measurements of ideal translocation candidates, and feeding regimes. Occurrence of one skink species was 114% higher at sites with burrows than at sites without, suggesting that WHDP presence benefits unrelated species. The information provided in this thesis facilitates the identification of future management strategies for this critically endangered species. However, future conservation management of the WHDP should be based on structured decision-making frameworks that apply iterative adaptive management loops and must acknowledge the unique position of tangata whenua (people of the land). This approach could address the consequences and trade-offs of each alternative, account for uncertainty, facilitate the decolonisation of conservation biology, and would ultimately result in the best potential outcome of the target species in a truly integrated fashion.</p>

From Line to Loop, A Circular 3D Printing Initiative for Upcycling Commercial Fishing Plastics

<p>The current linear use of plastic products follows a take, make and waste process. Commonly used by large scale industries, including the commercial fishing industry, this process results in approximately 8 million tonnes of plastic entering the ocean every year. While the fishing industry supplies livelihoods, a valuable food source and financial capital to millions of people worldwide, it’s also a significant contributor to the ocean plastics crisis. Without effective recycling schemes, an estimated 640,000 tonnes of plastic fishing gear is abandoned, lost or discarded within the ocean every year. New Zealand is no exception to this problem, as China’s waste import ban, as well as a lack of local recycling infrastructures, has resulted in the country’s commercial fishing gear polluting local coastlines as well as islands in the pacific. With the only other option for the plastic fishing gear being landfill, there is a critical need for circular initiatives that upcycle used plastic fishing gear locally into eco-innovative designs. This research examines the issue by investigating how used buoys, aquaculture ropes and fishing nets from New Zealand’s fishing company ‘Sanford’ may be upcycled into eco-innovative designs through distributed manufacturing technologies. It introduces the idea of the circular economy, where plastic fishing gear can be reused within a technical cycle and explores how 3D printing could be part of the solution as it provides local initiatives, low material and energy usage and customisation. Overall, the research follows the research through design based on design criteria approach. Where materials, designs and systems are created under the refined research criteria, to ensure the plastic fishing gear samples are upcycled effectively into eco-innovative designs through 3D printing. The tangible outputs of this research demonstrate how a circular upcycling system that uses distributed manufacturing technologies can create eco-innovative designs and provide a responsible disposal scheme for plastic fishing gear. It provides a new and more sustainable waste management scheme that could be applied to a range of plastic waste streams and diverts materials from entering the environment by continuously reusing them within the economy.</p>

Integrated conservation of the Whenua Hou Diving Petrel

<p>Seabirds are one of the most threatened taxa on the planet. These species are also considered ecosystem engineers. Therefore, seabirds are of particular conservation interest. One of the most threatened seabirds is the critically endangered Whenua Hou Diving Petrel (Pelecanoides whenuahouensis; WHDP). The WHDP is restricted to a minute (0.018 km2) breeding colony on a single island — Whenua Hou (Codfish Island), Aotearoa (New Zealand). The WHDP population was estimated at 150 adults in 2005. The WHDP is threatened by storms and storm surges, which erode its breeding habitat (fragile foredunes), and potentially by competition for burrows with congenerics. I aimed to inform suitable conservation strategies for the WHDP. I first quantified the efficacy of past conservation actions (eradications of invasive predators). I compiled burrow counts across four decades to estimate and compare population growth before and after predator eradications. I then investigated offshore threats using tracking data to quantify WHDP offshore distribution, behaviour, and overlap with commercial fishing efforts. Subsequently, I estimated the potential impact and success of WHDP translocations. Specifically, I combined capture-recapture, nest-monitoring, and count data in an integrated population model (IPM) to predict the impact of harvesting chicks for translocations on the source population and to project the establishment of a second population. I then informed future translocation protocols using nest-monitoring data to quantify nest survival and breeding biology. Finally, I tested if WHDP presence had a positive influence on unrelated species groups. I counted two skink species at sites with and without burrows and used occupancy modelling to quantify the influence WHDP burrows had on skink occurrence. Estimates of population growth before and after predator eradications illustrated that WHDP population growth remained comparatively low and unaffected by this conservation strategy. Therefore, additional interventions are required. WHDP tracking revealed that the non-breeding distribution did not overlap with commercial fishing efforts. However, considerable fishing efforts were present within the breeding distribution. Despite these findings, onshore threats remain present and conservation strategies aimed at addressing terrestrial threats may be more feasible. Results from my IPM showed that translocations could successfully establish a second WHDP population without impacting the source excessively, provided translocation cohorts remain small and translocations are repeated over long time periods (5-10 years). Nest survival was not clearly influenced by interannual variation, distance to sea, and intra- or interspecific competition. Furthermore, I informed future translocation protocols by identifying the preferred harvest window, measurements of ideal translocation candidates, and feeding regimes. Occurrence of one skink species was 114% higher at sites with burrows than at sites without, suggesting that WHDP presence benefits unrelated species. The information provided in this thesis facilitates the identification of future management strategies for this critically endangered species. However, future conservation management of the WHDP should be based on structured decision-making frameworks that apply iterative adaptive management loops and must acknowledge the unique position of tangata whenua (people of the land). This approach could address the consequences and trade-offs of each alternative, account for uncertainty, facilitate the decolonisation of conservation biology, and would ultimately result in the best potential outcome of the target species in a truly integrated fashion.</p>

From Line to Loop, A Circular 3D Printing Initiative for Upcycling Commercial Fishing Plastics

<p>The current linear use of plastic products follows a take, make and waste process. Commonly used by large scale industries, including the commercial fishing industry, this process results in approximately 8 million tonnes of plastic entering the ocean every year. While the fishing industry supplies livelihoods, a valuable food source and financial capital to millions of people worldwide, it’s also a significant contributor to the ocean plastics crisis. Without effective recycling schemes, an estimated 640,000 tonnes of plastic fishing gear is abandoned, lost or discarded within the ocean every year. New Zealand is no exception to this problem, as China’s waste import ban, as well as a lack of local recycling infrastructures, has resulted in the country’s commercial fishing gear polluting local coastlines as well as islands in the pacific. With the only other option for the plastic fishing gear being landfill, there is a critical need for circular initiatives that upcycle used plastic fishing gear locally into eco-innovative designs. This research examines the issue by investigating how used buoys, aquaculture ropes and fishing nets from New Zealand’s fishing company ‘Sanford’ may be upcycled into eco-innovative designs through distributed manufacturing technologies. It introduces the idea of the circular economy, where plastic fishing gear can be reused within a technical cycle and explores how 3D printing could be part of the solution as it provides local initiatives, low material and energy usage and customisation. Overall, the research follows the research through design based on design criteria approach. Where materials, designs and systems are created under the refined research criteria, to ensure the plastic fishing gear samples are upcycled effectively into eco-innovative designs through 3D printing. The tangible outputs of this research demonstrate how a circular upcycling system that uses distributed manufacturing technologies can create eco-innovative designs and provide a responsible disposal scheme for plastic fishing gear. It provides a new and more sustainable waste management scheme that could be applied to a range of plastic waste streams and diverts materials from entering the environment by continuously reusing them within the economy.</p>

Development of a Multi-Objective Optimization Tool for Screening Designs of Taut Synthetic Mooring Systems to Minimize Mooring Component Cost and Footprint

As the offshore wind industry develops, more lease sites in the intermediate water depth (50–85 m) are being released to developers. In these water depths floating wind turbines with chain catenary systems and fixed-bottom turbines with jacketed structures become cost prohibitive. As such, industry and researchers have shifted focus to floating turbines with taut or semi-taut synthetic rope mooring systems. In addition to reducing the cost of the mooring systems, synthetic systems can also reduce the footprint compared to a chain catenary system which frees areas around the turbine for other maritime uses such as commercial fishing. Both the mooring systems component cost and footprint are pertinent design criteria that lend themselves naturally to a multi-objective optimization routine. In this paper a new approach for efficiently screening the design space for plausible mooring systems that balance component cost and footprint using a multi-objective genetic algorithm is presented. This method uses a tiered-constraint method to avoid performing computationally expensive time domain simulations of mooring system designs that are infeasible. Performance metrics for assessing the constraints of candidate designs are performed using open-source software such as Mooring Analysis Program (MAP++), OpenFAST and MoorDyn. A case study is presented providing a Pareto-optimal design front for a taut synthetic mooring system of a 6-MW floating offshore wind turbine.

Juveniles and undersized fish in small-scale fisheries: gillnets are not less implied than trawling

Of particular concern in commercial fishing catch is 'size bycatch', i.e., the death of early stages of resources that would reach a marketable value when they turn into adults. This event is frequently associated with trawling because of the lower size selectivity of this gear as compared to gillnets. However, this is expected when small-scale fisheries (SSF) employ gillnets simultaneously in setnets + driftnets that mix multiple mesh sizes. This work analyzes fishing captures and compares characteristics of fish catch from gillnets and trawlers with respect to size at first maturation, legal size of capture, and expected discards. Data were obtained from 2007-2021 for SSF in Southern Brazil. A total of 112 fish species were represented in the data. Gillnets exploited fewer species than trawlers; however, most of these constitute fishing resources in the study region. Of the 19 species whose maturation size is known, nine occurred in gillnets as juveniles, and of the 14 species for which the legal size of capture is established, seven occurred in gillnets in prohibited sizes. Gillnets and trawlers presented size bycatch and affected different species between them, with four resources that were present in bycatch from both gillnets and trawlers. The broad range of mesh sizes employed by SSF warns of the discarding of undersized captures, and stresses the importance of policies addressing gillnet management.

Phylogenetic relationships, population connectivity, and development of genetic assignment testing in Buller's Albatross (Thalassarche bulleri ssp.)

<p>The Diomedeidae (Albatrosses) family is comprised of 22 recognised species, 13 are of high conservation concern because they are experiencing population declines. The taxonomy of albatrosses has always been problematic, which makes it difficult to estimate the number and size of breeding groups within a species. The Northern Buller’s Albatross (Thalassarche bulleri platei) and Southern Buller’s Albatross (Thalassarche bulleri bulleri) (Robertson & Nunn 1998; Turbott 1990) were recognised as separate species until 2006. A review of morphological data provided a basis for defining them as one species (Thalassarche bulleri); a result that was supported by international conservation agreements. However, there was no genetic data available at the time to corroborate the taxonomic change. The species status of Buller’s Albatross ssp. is an important issue because they are consistently recorded in the top five observed seabird interactions with commercial fishing vessels within New Zealand's Exclusive Economic Zone. Despite their prevalence in fisheries interactions, the relative impact of commercial fishing activity on northern and southern populations is unknown. Incidental mortality of albatrosses in commercial fisheries is recognised as a primary source of population disturbance. The overall goal of this thesis research was to investigate the genetic differences between the two sub-species of Buller’s Albatross. DNA was isolated from blood samples collected from a total of 73 birds from two Northern Buller’s Albatross colonies (n = 26) and two Southern Buller’s Albatross colonies (n = 47). The degree of genetic differentiation between the Northern and Southern taxa was estimated using DNA sequences from a 221 bp fragment of the mitochondrial control region, Domain II (CRII). The genetic differentiation between regional colony groups was high (pairwise ΦST = 0.621, p < 0.00001). Two haplogroups were identified within Northern Buller’s Albatross, while Southern Buller’s Albatross samples composed a single haplogroup. An analysis of molecular variance did not find any significant population structuring at the colony level. All individuals sampled from fisheries bycatch (n = 97) were assigned with maximum probability to either Northern (n = 19) or Southern Buller’s Albatross (n = 78; P = 1.00). The DNA sequences differences found in the mitochondrial control region can be used to assign provenance of T. bulleri ssp. samples, which will be a useful conservation management tool. In addition, a genome wide set of markers was obtained using a Genotyping by Sequencing approach. DNA was digested using restriction enzymes, fragments were labeled adaptor sequences, and shotgun sequenced on an Illumina platform by AgResearch. The Stacks pipeline was used to filter the sequences and obtain a set of single nucleotide polymorphism (SNP) markers across the genome. Estimates of genetic diversity and gene flow were conducted for 26 319 putative loci comprised of 54,061 single nucleotide polymorphisms. Estimates of genetic diversity were consistent across datasets with both taxa exhibiting similar levels of nucleotide diversity (Northern π ≈ 0.002 – 0.004; Southern π ≈ 0.002 – 0.003). However, estimates of genetic differentiation increased slightly as filtering protocols became increasingly restrictive (FST ≈ 0.019 – 0.048). This low level of differentiation was supported by admixture analyses, which identified two distinct ‘clusters’, one corresponding to T. b. platei and the second to T. b. bulleri. The results of this research demonstrate that Northern and Southern Buller’s Albatrosses are two genetically distinct groups.</p>

Phylogenetic relationships, population connectivity, and development of genetic assignment testing in Buller's Albatross (Thalassarche bulleri ssp.)

<p>The Diomedeidae (Albatrosses) family is comprised of 22 recognised species, 13 are of high conservation concern because they are experiencing population declines. The taxonomy of albatrosses has always been problematic, which makes it difficult to estimate the number and size of breeding groups within a species. The Northern Buller’s Albatross (Thalassarche bulleri platei) and Southern Buller’s Albatross (Thalassarche bulleri bulleri) (Robertson & Nunn 1998; Turbott 1990) were recognised as separate species until 2006. A review of morphological data provided a basis for defining them as one species (Thalassarche bulleri); a result that was supported by international conservation agreements. However, there was no genetic data available at the time to corroborate the taxonomic change. The species status of Buller’s Albatross ssp. is an important issue because they are consistently recorded in the top five observed seabird interactions with commercial fishing vessels within New Zealand's Exclusive Economic Zone. Despite their prevalence in fisheries interactions, the relative impact of commercial fishing activity on northern and southern populations is unknown. Incidental mortality of albatrosses in commercial fisheries is recognised as a primary source of population disturbance. The overall goal of this thesis research was to investigate the genetic differences between the two sub-species of Buller’s Albatross. DNA was isolated from blood samples collected from a total of 73 birds from two Northern Buller’s Albatross colonies (n = 26) and two Southern Buller’s Albatross colonies (n = 47). The degree of genetic differentiation between the Northern and Southern taxa was estimated using DNA sequences from a 221 bp fragment of the mitochondrial control region, Domain II (CRII). The genetic differentiation between regional colony groups was high (pairwise ΦST = 0.621, p < 0.00001). Two haplogroups were identified within Northern Buller’s Albatross, while Southern Buller’s Albatross samples composed a single haplogroup. An analysis of molecular variance did not find any significant population structuring at the colony level. All individuals sampled from fisheries bycatch (n = 97) were assigned with maximum probability to either Northern (n = 19) or Southern Buller’s Albatross (n = 78; P = 1.00). The DNA sequences differences found in the mitochondrial control region can be used to assign provenance of T. bulleri ssp. samples, which will be a useful conservation management tool. In addition, a genome wide set of markers was obtained using a Genotyping by Sequencing approach. DNA was digested using restriction enzymes, fragments were labeled adaptor sequences, and shotgun sequenced on an Illumina platform by AgResearch. The Stacks pipeline was used to filter the sequences and obtain a set of single nucleotide polymorphism (SNP) markers across the genome. Estimates of genetic diversity and gene flow were conducted for 26 319 putative loci comprised of 54,061 single nucleotide polymorphisms. Estimates of genetic diversity were consistent across datasets with both taxa exhibiting similar levels of nucleotide diversity (Northern π ≈ 0.002 – 0.004; Southern π ≈ 0.002 – 0.003). However, estimates of genetic differentiation increased slightly as filtering protocols became increasingly restrictive (FST ≈ 0.019 – 0.048). This low level of differentiation was supported by admixture analyses, which identified two distinct ‘clusters’, one corresponding to T. b. platei and the second to T. b. bulleri. The results of this research demonstrate that Northern and Southern Buller’s Albatrosses are two genetically distinct groups.</p>