Transmittance through sea ice from radiation station 2019R8 ...
Solar radiation over and under sea ice was measured by radiation station 2019R8, an autonomous platform, installed on drifting First-Year-Ice (FYI) in the Arctic Ocean during MOSAiC (Leg 1) 2019/20. The resulting time series describes radiation measurements as a function of place and time between 05...
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PANGAEA
2024
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| Online Access: | https://dx.doi.org/10.1594/pangaea.948943 https://doi.pangaea.de/10.1594/PANGAEA.948943 |
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ftdatacite:10.1594/pangaea.948943 |
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openpolar |
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ftdatacite:10.1594/pangaea.948943 2024-09-15T17:54:22+00:00 Transmittance through sea ice from radiation station 2019R8 ... Nicolaus, Marcel Belter, Hans Jakob Rohde, Jan Hoppmann, Mario Tao, Ran Katlein, Christian 2024 text/tab-separated-values https://dx.doi.org/10.1594/pangaea.948943 https://doi.pangaea.de/10.1594/PANGAEA.948943 unknown PANGAEA https://dx.doi.org/10.1594/pangaea.948876 Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 autonomous platform Backscatter buoy chlorophyll Conductivity drift FDOM Ice mass balance Oxygen snow depth solar radiation DATE/TIME LATITUDE LONGITUDE Transmittance Transmittance, photosynthetically active Quality flag, sun elevation Transmittance at 320 nm Transmittance at 321 nm Transmittance at 322 nm Transmittance at 323 nm Transmittance at 324 nm Transmittance at 325 nm Transmittance at 326 nm Transmittance at 327 nm Transmittance at 328 nm Transmittance at 329 nm Transmittance at 330 nm Transmittance at 331 nm Transmittance at 332 nm Transmittance at 333 nm Transmittance at 334 nm Transmittance at 335 nm Transmittance at 336 nm Transmittance at 337 nm Transmittance at 338 nm Transmittance at 339 nm Transmittance at 340 nm Transmittance at 341 nm Transmittance at 342 nm Transmittance at 343 nm Transmittance at 344 nm Transmittance at 345 nm Transmittance at 346 nm Transmittance at 347 nm Transmittance at 348 nm Transmittance at 349 nm Transmittance at 350 nm Transmittance at 351 nm Transmittance at 352 nm dataset Dataset 2024 ftdatacite https://doi.org/10.1594/pangaea.94894310.1594/pangaea.948876 2024-08-01T08:58:27Z Solar radiation over and under sea ice was measured by radiation station 2019R8, an autonomous platform, installed on drifting First-Year-Ice (FYI) in the Arctic Ocean during MOSAiC (Leg 1) 2019/20. The resulting time series describes radiation measurements as a function of place and time between 05 October 2019 and 31 July 2020 in sample intervals of 3 hours. The radiation measurements have been performed with spectral radiometers. All data are given in full spectral resolution interpolated to 1.0 nm, and integrated over the entire wavelength range (broadband, total: 320 to 950 nm). Two sensors, solar irradiance and upward reflected solar irradiance, were mounted on a on a platform about 1 m above the sea ice surface. The third sensor was mounted 0.5 m underneath the sea ice measuring the downward transmitted irradiance. Along with the radiation measurements, this autonomous platform consisted of a 5 m long thermistor chain with sensor spacing of 0.02 m and several other sensor packages, which measured ... : The data set has been processed and contains quality flags for different kinds for erroneous data. Flag values are the sum of individual error codes. The value of 0 refers to no error. Quality flag, position: The geographic position is flagged +1 if the drift velocity, as derived from the GPS longitude and latitude, exceeds a threshold of 10 deg latitude or 50 deg longitude per time step; +2 if the position exceeds extreme values, such as longitude > 360 deg; +4 if the position is exactly 0.0. ... Dataset Arctic Ocean Sea ice DataCite |
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Open Polar |
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DataCite |
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ftdatacite |
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unknown |
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autonomous platform Backscatter buoy chlorophyll Conductivity drift FDOM Ice mass balance Oxygen snow depth solar radiation DATE/TIME LATITUDE LONGITUDE Transmittance Transmittance, photosynthetically active Quality flag, sun elevation Transmittance at 320 nm Transmittance at 321 nm Transmittance at 322 nm Transmittance at 323 nm Transmittance at 324 nm Transmittance at 325 nm Transmittance at 326 nm Transmittance at 327 nm Transmittance at 328 nm Transmittance at 329 nm Transmittance at 330 nm Transmittance at 331 nm Transmittance at 332 nm Transmittance at 333 nm Transmittance at 334 nm Transmittance at 335 nm Transmittance at 336 nm Transmittance at 337 nm Transmittance at 338 nm Transmittance at 339 nm Transmittance at 340 nm Transmittance at 341 nm Transmittance at 342 nm Transmittance at 343 nm Transmittance at 344 nm Transmittance at 345 nm Transmittance at 346 nm Transmittance at 347 nm Transmittance at 348 nm Transmittance at 349 nm Transmittance at 350 nm Transmittance at 351 nm Transmittance at 352 nm |
| spellingShingle |
autonomous platform Backscatter buoy chlorophyll Conductivity drift FDOM Ice mass balance Oxygen snow depth solar radiation DATE/TIME LATITUDE LONGITUDE Transmittance Transmittance, photosynthetically active Quality flag, sun elevation Transmittance at 320 nm Transmittance at 321 nm Transmittance at 322 nm Transmittance at 323 nm Transmittance at 324 nm Transmittance at 325 nm Transmittance at 326 nm Transmittance at 327 nm Transmittance at 328 nm Transmittance at 329 nm Transmittance at 330 nm Transmittance at 331 nm Transmittance at 332 nm Transmittance at 333 nm Transmittance at 334 nm Transmittance at 335 nm Transmittance at 336 nm Transmittance at 337 nm Transmittance at 338 nm Transmittance at 339 nm Transmittance at 340 nm Transmittance at 341 nm Transmittance at 342 nm Transmittance at 343 nm Transmittance at 344 nm Transmittance at 345 nm Transmittance at 346 nm Transmittance at 347 nm Transmittance at 348 nm Transmittance at 349 nm Transmittance at 350 nm Transmittance at 351 nm Transmittance at 352 nm Nicolaus, Marcel Belter, Hans Jakob Rohde, Jan Hoppmann, Mario Tao, Ran Katlein, Christian Transmittance through sea ice from radiation station 2019R8 ... |
| topic_facet |
autonomous platform Backscatter buoy chlorophyll Conductivity drift FDOM Ice mass balance Oxygen snow depth solar radiation DATE/TIME LATITUDE LONGITUDE Transmittance Transmittance, photosynthetically active Quality flag, sun elevation Transmittance at 320 nm Transmittance at 321 nm Transmittance at 322 nm Transmittance at 323 nm Transmittance at 324 nm Transmittance at 325 nm Transmittance at 326 nm Transmittance at 327 nm Transmittance at 328 nm Transmittance at 329 nm Transmittance at 330 nm Transmittance at 331 nm Transmittance at 332 nm Transmittance at 333 nm Transmittance at 334 nm Transmittance at 335 nm Transmittance at 336 nm Transmittance at 337 nm Transmittance at 338 nm Transmittance at 339 nm Transmittance at 340 nm Transmittance at 341 nm Transmittance at 342 nm Transmittance at 343 nm Transmittance at 344 nm Transmittance at 345 nm Transmittance at 346 nm Transmittance at 347 nm Transmittance at 348 nm Transmittance at 349 nm Transmittance at 350 nm Transmittance at 351 nm Transmittance at 352 nm |
| description |
Solar radiation over and under sea ice was measured by radiation station 2019R8, an autonomous platform, installed on drifting First-Year-Ice (FYI) in the Arctic Ocean during MOSAiC (Leg 1) 2019/20. The resulting time series describes radiation measurements as a function of place and time between 05 October 2019 and 31 July 2020 in sample intervals of 3 hours. The radiation measurements have been performed with spectral radiometers. All data are given in full spectral resolution interpolated to 1.0 nm, and integrated over the entire wavelength range (broadband, total: 320 to 950 nm). Two sensors, solar irradiance and upward reflected solar irradiance, were mounted on a on a platform about 1 m above the sea ice surface. The third sensor was mounted 0.5 m underneath the sea ice measuring the downward transmitted irradiance. Along with the radiation measurements, this autonomous platform consisted of a 5 m long thermistor chain with sensor spacing of 0.02 m and several other sensor packages, which measured ... : The data set has been processed and contains quality flags for different kinds for erroneous data. Flag values are the sum of individual error codes. The value of 0 refers to no error. Quality flag, position: The geographic position is flagged +1 if the drift velocity, as derived from the GPS longitude and latitude, exceeds a threshold of 10 deg latitude or 50 deg longitude per time step; +2 if the position exceeds extreme values, such as longitude > 360 deg; +4 if the position is exactly 0.0. ... |
| format |
Dataset |
| author |
Nicolaus, Marcel Belter, Hans Jakob Rohde, Jan Hoppmann, Mario Tao, Ran Katlein, Christian |
| author_facet |
Nicolaus, Marcel Belter, Hans Jakob Rohde, Jan Hoppmann, Mario Tao, Ran Katlein, Christian |
| author_sort |
Nicolaus, Marcel |
| title |
Transmittance through sea ice from radiation station 2019R8 ... |
| title_short |
Transmittance through sea ice from radiation station 2019R8 ... |
| title_full |
Transmittance through sea ice from radiation station 2019R8 ... |
| title_fullStr |
Transmittance through sea ice from radiation station 2019R8 ... |
| title_full_unstemmed |
Transmittance through sea ice from radiation station 2019R8 ... |
| title_sort |
transmittance through sea ice from radiation station 2019r8 ... |
| publisher |
PANGAEA |
| publishDate |
2024 |
| url |
https://dx.doi.org/10.1594/pangaea.948943 https://doi.pangaea.de/10.1594/PANGAEA.948943 |
| genre |
Arctic Ocean Sea ice |
| genre_facet |
Arctic Ocean Sea ice |
| op_relation |
https://dx.doi.org/10.1594/pangaea.948876 |
| op_rights |
Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 |
| op_doi |
https://doi.org/10.1594/pangaea.94894310.1594/pangaea.948876 |
| _version_ |
1810430677349302272 |