Monitoring Svalbard’s environment and cultural heritage through citizen science by expedition cruises

2021 ◽  
Author(s):  
Michael Poulsen
Keyword(s):  
Environmental Management ◽  
Cultural Heritage ◽  
Citizen Science ◽  
Scientific Community ◽  
Decision Makers ◽  
The Arctic ◽  
Polar Regions ◽  
Science Program ◽  
Cruise Ship ◽  
Cruise Ships

<p><strong>Monitoring Svalbard’s environment and cultural heritage through citizen science by expedition cruises</strong></p><p>Michael K. Poulsen1, Lisbeth Iversen2, Ted Cheeseman3, Børge Damsgård4, Verena Meraldi5, Naja Elisabeth Mikkelsen6, Zdenka Sokolíčková7, Kai Sørensen8, Agnieszka Tatarek9, Penelope Wagner10, Stein Sandven2, and Finn Danielsen1</p><p>1NORDECO, 2NERSC, 3PCSC, 4UNIS, 5Hurtigruten, 6GEUS, 7University of Oslo, 8NIVA, 9IOPAN, 10MET Norway</p><p><strong>Why expedition cruise monitoring is important for Svalbard. </strong>The Arctic environment  is changing fast, largely due to increasing temperatures and human activities. The continuous areas of wilderness and the cultural heritage sites in Svalbard need to be managed based on a solid understanding.</p><p>The natural environment of Svalbard is rich compared to other polar regions. Historical remains are plentiful. The Svalbard Environmental Protection Act aims at regulating hunting, fishing, industrial activities, mining, commerce and tourism. Expedition cruises regularly reach otherwise rarely visited places.</p><p><strong>Steps taken to improve environmental monitoring. </strong>A workshop for enhancing the environmental monitoring efforts of expedition cruise ships was held in Longyearbyen in 2019, facilitated by the INTAROS project and the Association of Arctic Expedition Cruise Operators  (https://intaros.nersc.no/content/cruise-expedition-monitoring-workshop) with representatives of cruise operators, citizen science programs, local government and scientists. They agreed on a pilot assessment of monitoring programs during 2019.</p><p><strong>Results show the importance of cruise ship observations. </strong>The provisional findings of the pilot assessment suggest thatexpedition cruises go almost everywhere around Svalbard and gather significant and relevant data on the environment, contributing for example to an improved understanding of thestatus and distribution of wildlife. Observations are often documented with photographs. More than 150 persons contributed observations during 2019 to eBird and Happywhale. iNaturalist, not part of the pilot assessment, also received many contributions. The pilot assessment was unable to establish a useful citizen science program for testing monitoring of cultural remains.</p><p><strong>Conclusions relevant for monitoring and environmental management. </strong>Cruise ships collect environmental data that are valuable for the scientific community and for public decision-makers. The Governor of Svalbard isresponsible for environmental management in Svalbard. Data on the environment and on cultural remains from expedition cruises can be useful for the Governor’s office. Improved communication between citizen science programs and those responsible for environmental management decisions is likely to increase the quantity of relevant information that reaches public decision makers.</p><p><strong>Recommendations for improving the use of cruise ship observations and monitoring.</strong></p><ul><li>1) All cruise expedition ships should be equipped with tablets containing the apps for the same small selection of citizen scienceprograms so that they can easily upload records.</li> <li>2) Evaluation of data that can be created and how such data can contribute to monitoring programs, to ensure that data is made readily available in a form that is useful for institutions responsible for planning and improving environmental management.</li> <li>3) Clear lines of communication between citizen science program participants, citizen science program organizers, the scientific community and decision makers should be further developed.</li> <li>4) Developing expedition cruise monitoring is of high priority in Svalbard, but is also highly relevant to other polar regions.</li> <li>5) Further work is necessary to fully understand the feasibility and potential of coordinated expedition cruise operator based environmental observing in the Arctic.</li> </ul>

Open Polar: a new freely search service of publications and research data of Polar Regions

2021 ◽  
Author(s):  
Tamer Abu-Alam ◽  
Karl Magnus Nilsen ◽  
Obiajulu Odu ◽  
Leif Longva ◽  
Per Pippin Aspaas
Keyword(s):  
Scientific Community ◽  
Environmental Changes ◽  
Research Data ◽  
The Arctic ◽  
Polar Regions ◽  
Search Service ◽  
Norwegian Polar Institute ◽  
Under Construction ◽  
Access To Data ◽  
Beta Version

<p>Research data plays a key role in monitoring and predicting any natural phenomena, including changes in the Polar Regions. The limited access to data restricts the ability of researchers to monitor, predict and model environmental changes and their socio-economic repercussions. In a recent survey of 113 major polar research institutions, we found out that an estimated 60% of the existing polar research data is unfindable through common search engines and can only be accessed through institutional webpages. In social science and indigenous knowledge, this findability gap is even higher, approximately 84% of the total existing data. This raises an awareness sign and the call for the need of the scientific community to collect information on the global output of research data and publications related to the Polar Regions and present it in a homogenous, seamless database.</p><p>In this contribution, we present a new, open access discovery service, Open Polar, with the purpose of rendering polar research more visible and retrievable to the research community as well as to the interested public, teachers, students and decision-makers. The new service is currently under construction and will be hosted by UiT The Arctic University of Norway in close collaboration with the Norwegian Polar Institute and other international partners. The beta version of the Open Polar was made available in February 2021. We welcome comments and suggestions from the scientific community to the beta version, while we plan to launch the stable production version of the service by summer 2021. The beta version of the service can already be tested at the URL: www.openpolar.no</p>

Exploring the final frontiers: Cruise tourism in polar regions.

2013 ◽  
Vol 19 (2) ◽  
pp. 183
Author(s):  
Ayesha Tulloch
Keyword(s):  
Sustainable Use ◽  
Social Sustainability ◽  
The Arctic ◽  
Polar Regions ◽  
Cruise Ship ◽  
Cruise Industry ◽  
Large Numbers ◽  
Cruise Tourism ◽  
Negative Impacts

CRUISE ship tourism is expanding rapidly in both the Arctic and Antarctic, with increased numbers and types of vessels, more demanding routes, and yearround activity as the final frontiers are opened to all types of visitors. The increase in access and in cruise activities, risks of accidents and negative impacts, and the effects of the large numbers of tourists in the polar regions bring significant management challenges for sustainable use of polar regions. In this timely context, Lück, Maher and Stewart have collected a range of discussions and viewpoints of the environmental and social sustainability issues concerning the cruise industry in polar regions.

Extending the Ice Watch system as a citizen science project for the collection of In-Situ sea ice observations

2020 ◽  
Author(s):  
Ole Jakob Hegelund ◽  
Alistair Everett ◽  
Ted Cheeseman ◽  
Penelope Wagner ◽  
Nick Hughes ◽  
...  
Keyword(s):  
Sea Ice ◽  
Citizen Science ◽  
European Space Agency ◽  
Earth Observation ◽  
Machine Learning Algorithms ◽  
The Arctic ◽  
Polar Regions ◽  
User Engagement ◽  
The Antarctic

<p>The Ice Watch program coordinates routine visual observations of sea-ice including icebergs and meteorological parameters. The development and use of the Arctic Shipborne Sea Ice Standardization Tool (ASSIST) software has enabled the program to collect over 6 800 records from numerous ship voyages and it is complementary to the Antarctic Sea-ice Processes and Climate (ASPeCt) in the Antarctic. These observations will enhance validation and calibration of data from the Copernicus Sentinel satellites and other Earth Observation missions where the lack of routine spatially and temporally coincident data from the Polar Regions hinders the development of automatic classification products. A critical piece of information for operations and research, photographic records of observations, is often missing. As mobile phones are nearly ubiquitous and feature high-quality cameras, capable of recording accurate ancillary timing and positional information we are developing the IceWatchApp to aid users in supplementing observations with a photographic record.</p><p>The IceWatchApp has been funded by the Citizen Science Earth Observation Lab (CSEOL) programme of the European Space Agency and the Polar Citizen Science Collective, which has successfully implemented similar observation projects within atmospherics, biology and marine geosciences, is collaborating in its development. The image database will aid the training of machine learning algorithms for automatic sea ice type classification and provide a mechanism for crowd-sourcing identification through an “ask a scientist” feedback feature. The app will also have the capability to provide near real-time satellite and Copernicus services products back to the user, thereby educating them on Earth Observation, and giving them an improved understanding of the surrounding environment.</p><p> </p><p><strong>Keywords</strong>: Polar regions, Arctic, Antarctic, data collection, In-Situ measurements, remote sensing, Sea Ice, user engagement, citizen science, Earth Observation.<br><strong>Abstract</strong>: to session 35413</p><p> </p>

A Standards-based Data Catalogue integrating scientific, community-based and citizen science data across the Arctic

2021 ◽  
Author(s):  
Torill Hamre ◽  
Finn Danielsen ◽  
Michael Køie Poulsen ◽  
Frode Monsen
Keyword(s):  
Citizen Science ◽  
Scientific Community ◽  
The Arctic ◽  
Observation System ◽  
Data Systems ◽  
Science Data ◽  
Community Based ◽  
Horizon 2020 ◽  
Research And Innovation ◽  
Data Collections

<p>INTAROS is a Horizon 2020 research and innovation project developing an integrated Arctic Observation System by extending, improving, and unifying existing systems in the different regions of the Arctic. INTAROS integrates distributed repositories hosting data from ocean, atmosphere, cryosphere and land, including scientific, community-based monitoring (CBM) and citizen science (CS) data. Throughout the project, INTAROS has been working closely with several local communities and citizen science programs across the Arctic, to develop strategies and methods for ingestion of data into repositories enabling the communities to maintain and share data. A number of these CBM and CS data collections have been registered in the INTAROS Data Catalogue. Some of these collections are hosted and sustained by large international programs such as PISUNA, eBird, Secchi Disk Study and GLOBE Observer. Registration in the INTAROS Data Catalogue contributes to making these important data collections better known in a wider community of users with a vested interest in the Arctic. It also enables sharing of metadata through open standards for inclusion in other Arctic data systems. This catalogue is a key component in INTAROS, enabling users to search for data across the targeted spheres to assess their usefulness in applications and geographic areas. The catalogue is based on a world-leading system for data management, the Comprehensive Knowledge Archive Network (CKAN). With rich functionality offered out of the box combined with a flexible extension mechanism, CKAN allows for quickly setting up a fully functional data catalogue. The CKAN open-source community offers numerous extensions that can be used as-is or adapted to implement customised functionality for specific user communities. To hold additional metadata elements requested by the partners we modified the standard database schema of CKAN. The presentation will focus on the current capabilities and plans for sustaining and enhancing the INTAROS Data Catalogue.</p>

scholarly journals Open Arctic Research Index: Final report and recommendations

2019 ◽  
Author(s):  
Tamer S. Abu-Alam
Keyword(s):  
Open Access ◽  
Scientific Community ◽  
End Users ◽  
Research Data ◽  
Full Scale ◽  
The Arctic ◽  
Final Report ◽  
Polar Regions ◽  
Management Service ◽  
Scale Management

Access research data and research documents (e.g. publications) and make it more visible and findable through the internet is coming up as one of the major challenges for future development of the next generation of Digital Libraries. This challenge becomes more complicated when data producers (e.g. research institutes) are not aware by the needs of the scientific community for visibility and findability of their data or when the data producers lack the technology or the motivation to make their data available online.Although the Open Arctic Research Index pilot project focused only on the open-access research data and the open-access research documents published on Polar regions, the OpenARI found 60% of these open-access records are unfindable through searchable platforms outside the institutional webpage itself. This raises an awareness sign of the need of the scientific community to harvest the metadata of these open-access records in a homogenous, seamless database and making this database available to researchers, students and publics through one search platform. At present, neither Google Scholar nor any other search platform provide this service.Based on the fact that around 60% of the open-access polar records are unfindable through one search platform, we strongly suggest launching a full-scale management service at the University of Tromsø – the Arctic University of Norway (UiT). This new service will be built on existing experiences from High North Research Documents (i.e. an existing service at the UiT). OpenARI has concluded fifteen needs that are required for the full-scale management model. In addition to the main service (i.e. make open-access polar records more visible and findable through one search platform), we suggest to add three new services: 1) hosting of original data from the Polar regions; 2) creating a research platform; 3) creating an education platform. A new process including four stages of filtration is suggested in order to reduce the time and the overhead costs of using the UiT’s server. End-users will be able to perform search using a map. In addition to the classical way of presenting the results of a search, the end-users will be able to see the search results on a map and/or as a timeline.

scholarly journals All the world’s polar research data in one place

2019 ◽  
Author(s):  
Tamer Abu-Alam
Keyword(s):  
Research Data ◽  
Decision Makers ◽  
The Arctic ◽  
Data Sets ◽  
Polar Regions ◽  
Knowledge Based ◽  
Discovery Service ◽  
Teachers And Students ◽  
Norwegian Polar Institute ◽  
Under Construction

Data from the Polar Regions are of critical importance to modern research. Regardless of their disciplinary and institutional affiliations, researchers rely heavily on the comparison of existing data with new data sets to assess changes that are taking effect. In turn, knowledge based on as broad and comprehensive a selection of polar data sets as possible is used to inform politicians and decision makers. Although individual researchers and their institutions are aware of the importance of making collected data openly available through institutional websites, the infrastructures that are used for these purposes at many institutions, are often poorly interoperable, and therefore make valuable data difficult to find and reuse. In a recent survey of 113 major polar data providers, we found that an estimated 60% of the existing polar research data is unfindable through common search engines and can only be accessed through an institutional webpage. This findability gap limits the ability of researchers to establish robust models by which changes in the polar regions can be predicted. In this contribution, we present a new, free-to-use discovery service covering the global output of openly accessible polar research data and publications, with the purpose of rendering polar research more visible and retrievable to the research community as well as to the interested public, teachers and students and public services. The new service is currently under construction and will be hosted by UiT The Arctic University of Norway in close collaboration with the Norwegian Polar Institute.

The use of expedition cruise ships and citizen science to bridge the gaps in plastic marine litter knowledge in remote areas. 

2021 ◽  
Author(s):  
Verena Meraldi ◽  
Tudor Morgan ◽  
Kai Sørensen ◽  
Bert van Bavel
Keyword(s):  
Citizen Science ◽  
The Arctic ◽  
Science Project ◽  
Remote Areas ◽  
Cruise Ships ◽  
The World ◽  
Citizen Science Project ◽  
The Antarctic ◽  
Term Data

<p>Plastics and microplastics are regularly found in the marine environment around the world. Currently, the spatial and temporal dynamics of microplastics in remote areas, including polar regions, are poorly assessed and only limited long-term data is available on occurrence. Long-term data series are required to address changes in abundances of microplastics including variations in spatial and temporal distribution as well as to understand the influence of, for example, different seasons, changing weather or hydrological conditions. But there is very little data from remote regions of the world<sup>(1)</sup> including the Arctic and Antarctic.</p><p>One approach is to use ships of opportunity (www.norsoop.com) to collect data over replicated transects: these include research vessels as well as commercial vessels and expedition cruise ships. Advances in technology enable assessment of microplastic abundance at large spatial scale using existing infrastructure in addition to the collection of oceanographic meta-data. As part of the Hurtigruten – NIVA collaboration, a microplastic sampling module and a marine monitoring system (Ferry Box) was fitted on Hurtigruten’s Expedition vessel MS Roald Amundsen. The science center in this expedition ship, where single use plastic has been removed from all areas, provides a lab facility for preliminary plastic analysis and also a place for interaction with the passengers and engagement in citizen science. During the first year of operation, NIVA and Hurtigruten have collected microplastic samples in the Arctic and the Antarctic for long time periods. In addition, as part of a citizen science project, data and samples have been collected during beach clean-ups in remote areas and analysed on board using a handheld NIR smartphone scanner directly linked to a NIVA cloud database.</p><p>Average levels of microplastic within the Arctic (1.8-10 n/m<sup>3</sup>) and Antarctic (1.8-4.6) are still relatively low and consist mostly of fibres. The levels found in the Arctic study were comparable with the results from Lusher et al. 2015 and recent work in the Russian Arctic. Cellulose and cotton-based fibres dominate in the Antarctic samples and polyester is the dominant polymeric fibre. A citizen science project involving a beach clean-up and the subsequent analysis of the samples collected was performed on board MS Roald Amundsen in the Falkland/Malvinas Islands. The results showed large amounts of fishery related material including several polymer-based ropes and net pieces but also plastic utensils, food wrapping and plastic bottles.</p><p> (1)        GESAMP (2016). Sources, fate and effects of microplastics in the marine environment: part two of a global assessment (Kershaw, P.J., and Rochman, C.M., eds). Rep. Stud. GESAMP No. 93, 220 p.</p><p>(2)         Lusher, A. L., Tirelli, V., O’Connor, I., and Officer, R. (2015). Microplastics in Arctic polar waters: the first reported values of particles in surface and sub-surface samples. Nature-scientific reports. 9 p.</p><p>(3)         Yakushev E., Gebruk A., Osadchiev A., Pakhomova S., Lusher A., Berezina A., van Bavel B., Vorozheikina E., Chernykh D., Kolbasova G., Razgon I., Semiletov I. Microplastics distribution in the Eurasian Arctic is affected by Atlantic waters and Siberian rivers. Communications Earth & Environment in press. DOI: 10.1038/s43247-021-00091-0</p>

scholarly journals Prevention of microbial species introductions to the Arctic: The efficacy of footwear disinfection measures on cruise ships

NeoBiota ◽  
2018 ◽  
Vol 37 ◽  
pp. 37-49 ◽  
Author(s):  
Sabine B. Rumpf ◽  
Inger Greve Alsos ◽  
Chris Ware
Keyword(s):  
Native Species ◽  
Microbial Growth ◽  
High Arctic ◽  
The Arctic ◽  
Natural Environments ◽  
Cruise Ship ◽  
Svalbard Archipelago ◽  
Operational Conditions ◽  
Cruise Ships ◽  
Before And After

Biosecurity measures are commonly used to prevent the introduction of non-native species to natural environments globally, yet the efficacy of practices is rarely tested under operational conditions. A voluntary biosecurity measure was trialled in the Norwegian high Arctic following concern that non-native species might be transferred to the region on the footwear of travellers. Passengers aboard an expedition cruise ship disinfected their footwear with the broad spectrum disinfectant Virkon S prior to and in-between landing at sites around the remote Svalbard archipelago. The authors evaluated the efficacy of simply stepping through a disinfectant foot bath, which is the most common practice of footwear disinfection aboard expedition cruise ships in the Arctic. This was compared to a more time consuming and little-used method involving drying disinfected footwear, as proposed by other studies. The two practices were evaluated by measuring microbial growth on paired footwear samples before and after disinfection under both conditions. Step-through disinfection did not substantially reduce microbial growth on the footwear. Allowing disinfected footwear to dry, however, reduced the microbial burden significantly to lower levels. Thus, the currently adopted procedures used aboard ships are ineffective at removing microbial burden and are only effective when footwear is given more time to dry than currently granted under operational conditions. These findings underscore results from empirical research performed elsewhere and suggest the need to better relay this information to practitioners. It is suggested that footwear should minimally be wiped dry after step-through disinfection as a reasonable compromise between biosecurity and practicability.

Preserving Irreplaceable National Digital Cultural Heritage in the Arctic World Archive

2019 ◽  
Vol 2019 (1) ◽  
pp. 39-41
Author(s):  
Morten Thorkildsen ◽  
Jahn-Fredrik Sjøvik ◽  
Bendik Bryde
Keyword(s):  
Cultural Heritage ◽  
The Arctic ◽  
Digital Cultural Heritage
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