The full list of projects contains the entire database hosted on this portal, across the available directories. The projects and activities (across all directories/catalogs) are also available by country of origin, by geographical region, or by directory.
The main objective of the project is to describe quantitatively with model calculations the global distribution behaviour of persistent organic contaminants, and to establish credibility in the results of these simulations.
Distributed network (about 180 sites over Finland). Coverage over Finland mainly according to WMO recommendations including all Finnish polar regions. Some of the stations also include automatic daily snow depth observations and soil moisture monitoring instrumentation. Network type: Automatic operational weather station observations
The network of observations of SR phenomena consists of 3 points: Hornsund (Svalbard), Belsk (Poland), Nagycenk (Hungary). The data from this network are used for scientific analysis.
Weather forecasting Main gaps: These observations are operational observations of METNO
Monitoring and forecast of the sea and atmosphere state in the coastal area, support of safety of navigation and marine activities. Main gaps: Initial data before 1977 have not been digitized.
Fluvial transport, its dynamics and structure, constitute a good indicator of the condition of the natural environment in various climatic zones. Analysis of fluvial transport components allows for precise determination of the rate and directions of transformations of geosystems of any importance. In the polar zone, very sensitive to global changes, it seems expedient to identify the mechanisms and structure of fluvial transport, particularly in the conditions of the observed glacier retreat, the main alimentation source of proglacial rivers. Studies carried out in the zone revealed difficulties in determination of fluvial transport structure, particularly the actual bedload of gravel-bed rivers based on direct measurements, resulting from: short measurement series, lack of standardization of research methods and measurement equipment, and strategy of selection of study objects and sampling. The research project presented concerns determination of mechanisms of fluvial transport and sediment supply to Arctic gravel-bed river channels. The mechanisms reflect the processes of adaptation of proglacial rivers of the Arctic zone to changing environmental conditions, and indicate the dominant directions of transformations of paraglacial geosystems of various importance. For studies on Arctic geosystems, the region of the south Bellsund (SW Spitsbergen) was selected due to extensive knowledge on its hydro-meteorological and glacial-geomorphological conditions, and long-term measurement series carried out by the research station of the MCSU, among others within the framework of the international monitoring network: SEDIBUD (IAG) and Small-CATCHMENT program. For detailed studies, rivers with various hydrological regimes were selected, functioning at the forefield of the Scott and Renard Glaciers. The Scott River glacial catchment and glacier-free catchments of the Reindeer Stream and the Wydrzyca Stream (with a snow-permafrost hydrological regime) meet the selection criteria for representative test catchments analyzed for the following programs: SEDIFLUX, SEDIBUD, and POP.
1. The WMO facilitates worldwide cooperation in the establishment of networks of stations for the making of meteorological observations as well as hydrological and other geophysical observations related to meteorology. Observing stations are operated by WMO Members according to agreed standards and recommended practices described in the WMO Regulatory Material, such as Technical regulations, WMO-No. 49 and its Annexes.
2. The WMO requirements for observational data are generally divided into three categories: global, regional and national. For example, surface synoptic stations are expected to report every six hours for global exchange and every three hours for regional exchange, however with higher frequency on bilateral and multilateral arrangements. The details of the observational programmes provided by all stations operated by WMO Members are given in the WMO Observing Systems Capability Analysis and Review Tool (OSCAR) and available on the WMO website at https://oscar.wmo.int/OSCAR/index.html#/.
3. The approved operational procedures and practices are given in the regularly updated Manual on the Global Observing System (WMO-No. 544), and the Manual on the WMO Integrated Global Observing System (WMO-No. 1160) available also on the WMO website at http://www.wmo.int/pages/prog/www/OSY/Manuals_GOS.html and http://www.wmo.int/pages/prog/www/wigos/documents/WIGOS-RM/1160_en.pdf, respectively.
4. Under the Global Observing System of the World Weather Watch Programme, WMO Members operating stations in the Arctic Monitoring and Assessment Programme (AMAP) area (essentially includes the terrestrial and marine areas north of the Arctic Circle (66°32N), and north of 62°N in Asia and 60°N in North America, modified to include the marine areas north of the Aleutian chain, Hudson Bay, and parts of the North Atlantic Ocean including the Labrador Sea), contribute to the implementation of the observational programme by operating 336 surface Regional Basic Synoptic and 156 Regional Basic Climatological stations. A detailed infomration is available through WMO OSCAR: https://oscar.wmo.int/OSCAR/index.html#/.
Continuous measurements of greenhouse gases and particles to monitor changes in the atmosphere. The programme is operated by Norwegian Institute of Air Research (NILU) on behalf of Norwegian Environment Agency. The Zeppelin Observatory is a major contributor of data on a global as well as a regional scale.The programme is decribed in the link.
Aerosols, Clouds, and Trace gases Research InfraStructure - ACTRIS is a research infrastructure on the ESFRI roadmap from March 2016. ACTRIS is currently supported by the European Commission Horizon 2020 Research and Innovation Framework Programme (H2020-INFRAIA-2014-2015) from 1 May 2015 to 30 April 2019.
The objectives of ACTRIS Research Infrastructure
Detecting changes and trends in atmospheric composition and understanding their impact on the stratosphere and upper troposphere is necessary for establishing the scientific links and feedbacks between climate change and atmospheric composition.
The main objective is to quantify the levels of air pollution in the artctic, and to document any changes in the exposures. It includes the necessary components to address impacts on ecosystems, human health, materials and climate change.
These observations was originally funded through IPY projects (iAOOS-Norway and IPYTHORPEX), they are now maintained by the Norwegian Meteorological Institute. The observations at Bjørnøya started April 2008, Jan Mayen October 2008 and Hopen is scheduled 2009.
The main purpose of IMO is to contribute towards increased security and efficiency in society by: • Monitoring, analyzing, interpreting, informing, giving advice and counsel, providing warnings and forecasts and where possible, predicting natural processes and natural hazards; • issuing public and aviation alerts about impending natural hazards, such as volcanic ash, extreme weather, avalanching, landslides and flooding; • conducting research on the physics of air, land and sea, specifically in the fields of hydrology, glaciology, climatology, seismology and volcanology; • maintaining high quality service and efficiency in providing information in the interest of economy, of security affairs, of sustainable usage of natural resources and with regard to other needs of the public; • ensuring the accumulation and preservation of data and knowledge regarding the long-term development of natural processes such as climate, glacier changes, crustal movements and other environmental matters that fall under IMO‘s responsibility. IMO has a long-term advisory role with the Icelandic Civil Defense and issues public alerts about impending natural hazards. The institute participates in international weather and aviation alert systems, such as London Volcanic Ash Advisory Centre (VAAC), the Icelandic Aviation Oceanic Area Control Center (OAC Reykjavík) and the European alarm system for extreme weather, Meteoalarm. Network type: Thematic observations in 6 different fields
The main mission of the International Arctic Systems for Observing the Atmosphere (IASOA) is coordination of atmospheric data collection at existing and newly established intensive Arctic atmospheric observatories. Data of interest to the IASOA consortium include measurements of standard meteorology, greenhouse gases, atmospheric radiation, clouds, pollutants, chemistry, aerosols, and surface energy balances. These measurements support studies of Arctic climate change attribution (why things are changing), not just trends (how things are changing). IASOA is responsive to growing evidence that the earth system may be approaching environmentally critical thresholds within decadal time scales. The information from IASOA will not only enhance scientific understanding but will also support decisions by the global community regarding climate change mitigation and adaptation strategies. Main gaps: Not all observatories are members of established global networks such as GAW and BSRN. It is recommended that IASOA observatories that are not members of these global networks be evaluated for potential membership and that roadblocks to membership be investigated. Other types of measurement gaps include, but are not limited to: (1) Radar-lidar pairs at each observatory to assess cloud properties; (2) Flux towers at each observatory for methane and CO2 fluxes; (3) Aerosol measurements at each observatory; and (4) Surface and upper air ozone measurements at each observatory. Network type: Predominantly atmospheric measurements.
- Provide continuous measurements of high scientific quality of total ozone and solar ultraviolet radiation, to be used in assessments related to health- and environmental issues. - Provide data that can be used for short term forecasting and assessments of long term changes of total ozone and UV radiation. - Provide information to the public and scientific communitee on the status and the development of the ozone layer and UV radiation - Provide information to the public on sun protection when episodes of high UV Index may occur.
The Norwegian Radiation Protection Authority is responsible for a nationwide network of 33 stations that continuously measure background radiation levels. The network was established in the years following the Chernobyl accident in 1986, and was upgraded to a new and modern network in the period 2006-2008. Additional stations were added in 2009. The purpose of the monitoring network is to provide an early warning if radioactive emissions reach Norway.
The UV-monitoring network has provided 15 years of high quality, continuous measurements of solar UV radiation. The network is the hub of all activities related to UV forecasting and information to the public, aiming to reduce the high number of cases of acute and chronic negative health effects from excessive UV exposure.
The Norwegian Radiation Protection Authority is responsible for a network of 5 air filter stations. These collect air samples through high density filters which are analyzed weekly by gamma spectroscopy. The network was established in the early 80s and is continuously updated. The purpose of the network is to assess the levels and composition of emissions from incidents and accidents. In addition, with the help of meteorological data, possible sources of release may be identified.
The Northern Contaminants Program aims to reduce and where possible eliminate long-range contaminants from the Arctic Environment while providing Northerners with the information they need to make informed dietary choices, particularly concerning traditional/country food. To achieve these objectives the NCP conducts research and monitoring related to contaminants in the Arctic environment and people. Monitoring efforts focus on regular (annual) assessment of contaminant levels in a range of media, including air, biota and humans. Environmental research is conducted into the pathways, processes and effects of contaminants on Arctic ecosystems while human health research focuses on assessing contaminant exposure, toxicity research, epidemiological (cohort) studies, and risk-benefit assessment and communications. Main gaps: Contaminant measurements in Arctic seawater, toxicity data specific to Arctic species. Network type: - Thematical observations: Contaminants levels and relevant ancilliary parameters - Field stations: Atmospheric observing stations at Alert, Nunavut and Little Fox Lake, Yukon. - Community based observations: Numerous communities throughout the Canadian Arctic participate in sample collection - Coordination: National coordination of the program provided by the NCP secretariat, which also acts as liaison with AMAP.
As part of the Austrian radioactivity monitoring network an air sampler and a high resolution radioactivity detection system is installed at the high altitude Sonnblick Observatory (3105 m). The objective is to monitor the radioactivity in air at high altitudes.
In order to assess the spatial and temporal patterns of the a-, b- and g-isomers of hexachlorocyclohexane (HCH) in the arctic biotic and abiotic environment, it is proposed that: (1) concentrations and ratios of HCH isomers be compared over time in air, water, seals, beluga, polar bears and seabirds to determine any shifts in isomeric ratios and how those shifts interrelate among the various media, and (2) concentrations and ratios of HCH isomers be compared spatially in the abiotic and biotic media and reasons for any patterns explored.