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.

Displaying: 21 - 40 of 196 Next
21. Norwegian greenhouse gas monitoring

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.

Aerosol Arctic haze Atmosphere CH4 chlorofluorocarbons (CFC) CO2 Halocarbons trace gases CO
22. Monitoring of long range transboundary air pollution, greenhouse gases, ozone layer and natural ultraviolet radiation

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. 

AMAP Arctic air Arctic haze Atmosphere Atmospheric chemistry monitoring Atmospheric processes Carbon dioxide chlorofluorocarbons (CFC) Climate heavy metals methane Montreal & Kyoto Protocols PAHs PCBs POPs total gaseous mercury total ozone UV
23. International Arctic Systems for Observing the Atmosphere (IASOA)

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.

Atmosphere Climate
24. The Arctic Station, Qeqertarsuaq, Greenland, University of Copenhagen (AS-Q)

The Arctic Station is located on the south coast of the Disko Island in central west Greenland. It is thus facing the Disko Bay and is characterized by an arctic, marine climate. There are 3 building comprising guest facilities, staff accomodation, laboratory and library that are located in a nature sanctuary, approximately 1 km west of a small town, Qeqertarsuaq (formerly Godhavn), with ca. 1100 inhabitants. Within the town community is located all necessary service facilities, incl. several shops, bank, postoffice, church and a hospital. The station offers a 'state of the art' platform for year-round environmental research. The Arctic Station maintains a stat-of-the-art automatic weather station located in the immediate vicinity of the Arctic Station. The datalogging at Arctic Station (every half hour) comprises: air temperatur, humidity, incoming and outgoing radiation, wind speed and direction, rainfall, ground temperatures (5, 60 and 150 cm below surface) and temperature in solid rock 2 metre below surface. In addition to the above the station also maintains a freshwater, a marine and a terrestrial monitoring program. The whole moitoring program is call DiskoBasic.

Active layer algal blooming aquatic monitoring Snow and ice properties
25. 129I in Arctic seawater

Anthropogenic 129I discharged from European reprocessing plants has widely dispersed in the Nordic waters including the Arctic. Due to the high solubility and long residence time of iodine in seawater, anthropogenic 129I has become an ideal oceanographic tracer for investigating transport pathways and the exchange of water masses.

129I Long-range transport Climate change Central Arctic Ocean Radionuclides Arctic Ocean currents

Multidisciplinary investigations at the LTER (Long-Term Ecological Research) observatory HAUSGARTEN are carried out at a total of 21 permanent sampling sites in water depths ranging between 250 and 5,500 m. From the outset, repeated sampling in the water column and at the deep seafloor during regular expeditions in summer months was complemented by continuous year-round sampling and sensing using autonomous instruments in anchored devices (i.e., moorings and free-falling systems). The central HAUSGARTEN station at 2,500 m water depth in the eastern Fram Strait serves as an experimental area for unique biological in situ experiments at the seafloor, simulating various scenarios in changing environmental settings. Time-series studies at the HAUSGARTEN observatory, covering almost all compartments of the marine ecosystem, provide insights into processes and dynamics within an arctic marine ecosystem and act as a baseline for further investigations of ongoing changes in the Fram Strait. Long-term observations at HAUSGARTEN will significantly contribute to the global community’s efforts to understand variations in ecosystem structure and functioning on seasonal to decadal time-scales in an overall warming Arctic and will allow for improved future predictions under different climate scenarios.

Biodiversity carbon flux Climate change ecology Ice Marine benthos marine ecosystem monitoring Oceanography Plankton
27. GeoBasis - ZERO

The GeoBasis programme collects data describing the physical and geomorphological environment in Zackenberg, North East Greenland. This includes CO2-flux, snowcover and permafrost, soil moisture, –chemistry and nutrient balance, hydrology, river discharge and –sediment. GeoBasis also supports the ClimateBasis programme with service and datahandling during the field season.

Geophysics Climate change Ice Arctic Permafrost Ecosystems
28. Arctic and Alpine Stream Ecosystem Research

The project, Arctic and Alpine Stream Ecosystem Research (AASER), started within EU’s Climate & Environment Programme and now continues with national funding, primarily Norway, Italy and Austria. The objective is to study dynamics and processes in rivers systems in Arctic and Alpine regions. Emphasis is given to the relationships between benthic invertebrates and environmental variables, especially in glacier-fed systems and in relation to climate change scenarios. On Svalbard research is concentrated around Ny Ålesund, particularly Bayelva and Londonelva. In 2004 the focus will be on the use to stable isotopes to detect transfer processes within and between ecosystems.

Glaciers Biology Catchment studies Spatial trends Climate change Biodiversity Arctic Food webs Temporal trends Ecosystems
29. Pallas-Sodankylä, GAW station, Northern Finland

GAW serves as an early warning system to detect further changes in atmospheric concentrations of greenhouse gases and changes in the ozone layer, and in the long-range transport of pollutants, including acidity and toxicity of rain as well as the atmospheric burden of aerosols.

Atmospheric processes Ozone Arctic haze UV radiation Radioactivity Climate variability Long-range transport Climate Acidification Contaminant transport Climate change Radionuclides Arctic Atmosphere Temporal trends
30. Hydrometeorological monitoring

Hydrometeorological monitoring program produces real time information on precipitation and snow water equivalent. Information is utilized in modeling and forecasting floods and snow load. As part of the program, information of evaporation is produced with WMO standards. The program is coordinated by Finnish Environment Institute (SYKE). Finnish meteorological institute and Lapland regional centre for economic development, transport and the environment manage measurements and field work.

Climate Hydrometeorology Climate change snow water equivalent Arctic monitoring evaporation. precipitation
31. Hydrological monitoring

Hydrological monitoring aims produce real time information of water level and discharge, ice thickness including freeze-up and break-up in winter from a network of monitoring stations. Monitoring data is utilized in water resource planning, water management and flood damage prevention. Monitoring is coordinated by Finnish Environmental Institute (SYKE).

Climate Climate change Ice River ice Arctic Temporal trends
32. Monitoring of the effects of air pollution and climatic change on lakes

Monitoring of the water quality reflecting long-range transboundary air pollution including acidifying compounds, metals and POPs, and climatic change. Part of the sites are also including in biological monitoring. Monitoring sites are the most upland lakes and they are not under any significant human impact. Information is distributed to the UN Convention on Long-range Transboundary Air Pollution. Monitoring is managed by Finnish Environmental Institute (SYKE).

Biology air pollution Heavy metals Climate Acidification climate change Ecosystems POPs
33. Hydrogeological monitoring

Monitoring follows groundwater level and quality as well as changes in soil humidity and frost depth in winter.

Soils Climate Climate change frost Arctic Groundwater humidity.
34. JAMSTEC: measurement network in collaboration with Russian, Mongolian and US Institutes

Long-term Obs. Site.   Super-sites、experiment-sites Traverse Obs. Line

Climate Atmosphere
35. GRENE (Green Network of Excellence) (GRENE)

1. Priority Research Theme (1) Clarification of the mechanism of the Arctic amplification. (2) The role of Arctic in the global climate change and future projection. (3) Evaluation on the influence of the Arctic Environmental Change to the weather in the Japan area and fishery. (4) Future projection of the sea ice distribution in relation to the evaluation Arctic route. 2. Basic infrastructure (1) Arctic research cruises by Japanese and foreign ships/ice breaker. (2) Cloud radar system. (3) Data archive system. 3. Establishment of “Japan Consortium for Arctic Environment Research” 4. Budget size: 650, 000, 000 Japanese Yen per year. (appox. 8 million USD per year) Network type: research programme

Hydrography Climate Sea ice Oceanography Atmosphere
36. Ice-drifting buoy observation in sea ice area of the Arctic Ocean

Ice-drifting buoy observation in sea ice area of the Arctic Ocean Main gaps: not well documented…

Hydrography Climate Sea ice Oceanography Atmosphere
37. Observation of Greenhouse Gases using Aircraft and Tower Network in Siberia

Cooperation with: ・Institute of Atmospheric Optics, Tomsk, Russia ・Permafrost Institute, Yakutsk, Russia ・Central Aerological Observatory, Moscow, Russia ・Institute of Microbiology, Moscow, Russia

Climate Pollution sources Atmosphere
38. Arctic Atmospheric Boundary Layer Observing System (ABLOS)

monitoring of thermal and humidity parameters of arctic atmospheric boundary layer in horizontal and vertical profile covering glaciated area, non-glaciated area and mountain peak

Climate Sea ice
39. Network of voluntary marine meteorological observations

Incidental hydrometeorological observations along vessel routes. Monitoring and forecast of the surface layer atmosphere state, hydrometeorological support of safety of navigation and marine activities.

40. POLAR-AOD and the Arctic Oceanographic Observations (AREX)

The Arctic region represents a sensitive ecosystem, which is susceptible to even small changes in the local climate. Special conditions of usually high surface albedo and low solar elevations cause enhanced aerosol/cloud effects due to multiple scattering. It is suspected that this increased interaction between solar radiation and the aerosol particles/clouds magnifies their radiative impact. Thus, for a given aerosol distribution, the specific optical properties are enhanced in the polar regions. For the same reasons, results from field experiments at low latitudes are difficult to transfer to polar regions and as a consequence there is an urgent need to conduct specific measurement programs in high latitude regions. In order to improve the knowledge about the origin, transport pathways, vertical structure of aerosol physical and chemical properties as well as the impact on climate in the polar regions, a combined effort of surface-based, airborne and spaceborne measurements is needed. Therefore, this proposed project is aiming at a determination of the vertical structure of the chemical, physical and optical properties of Arctic aerosol particles, including solar radiative closure between observed and calculated aerosol properties (direct climate effect)