The Regional Ice Ocean Prediction System v2: a pan-Canadian ocean analysis system

Canada has the longest coastline in the world and includes a diversity of ocean environments, from the frozen waters of the Canadian Arctic Archipelago to the confluence region of Labrador and Gulf Stream waters on the East Coast. There is a strong need for a pan-Canadian operational regional ocean...

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Main Authors: Smith, Gregory C., Liu, Yimin, Benkiran, Mounir, Chikhar, Kamel, Surcel Colan, Dorina, Testut, Charles-Emmanuel, Dupont, Frederic, Lei, Ji, Roy, François, Lemieux, Jean-Francois, Davidson, Fraser
Format: Text
Language:English
Published: 2020
Subjects:
Arctic
Arctic Ocean
Canada
Canadian Arctic Archipelago
Pacific
Arctic Archipelago
Beaufort Sea
Online Access:https://doi.org/10.5194/gmd-2020-255
https://gmd.copernicus.org/preprints/gmd-2020-255/
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record_format openpolar
spelling ftcopernicus:oai:publications.copernicus.org:gmdd87816 2023-05-15T14:29:03+02:00 The Regional Ice Ocean Prediction System v2: a pan-Canadian ocean analysis system Smith, Gregory C. Liu, Yimin Benkiran, Mounir Chikhar, Kamel Surcel Colan, Dorina Testut, Charles-Emmanuel Dupont, Frederic Lei, Ji Roy, François Lemieux, Jean-Francois Davidson, Fraser 2020-08-26 application/pdf https://doi.org/10.5194/gmd-2020-255 https://gmd.copernicus.org/preprints/gmd-2020-255/ eng eng doi:10.5194/gmd-2020-255 https://gmd.copernicus.org/preprints/gmd-2020-255/ eISSN: 1991-9603 Text 2020 ftcopernicus https://doi.org/10.5194/gmd-2020-255 2020-08-31T16:22:12Z Canada has the longest coastline in the world and includes a diversity of ocean environments, from the frozen waters of the Canadian Arctic Archipelago to the confluence region of Labrador and Gulf Stream waters on the East Coast. There is a strong need for a pan-Canadian operational regional ocean prediction capacity covering all Canadian coastal areas, in support of marine activities including emergency response, search and rescue as well as safe navigation in ice-infested waters. Here we present the first pan-Canadian operational regional ocean analysis system developed as part of the Regional Ice Ocean Prediction System version 2 (RIOPSv2) running in operations at the Canadian Centre for Meteorological and Environmental Prediction (CCMEP). The RIOPSv2 domain extends from 26° N in the Atlantic Ocean through the Arctic Ocean to 44° N in the Pacific Ocean, with a model grid-resolution that varies between 3 and 8 km. RIOPSv2 includes a multi-variate data assimilation system based on a reduced-order extended Kalman filter together with a 3DVar bias correction system for water mass properties. The analysis system assimilates satellite observations of sea level anomaly and sea surface temperature, as well as in situ temperature and salinity measurements. Background model error is specified in terms of seasonally varying model anomalies from a 10-year forced model integration allowing inhomogeneous anisotropic multi-variate error covariances. A novel online tidal harmonic analysis method is introduced that uses a sliding-window approach to reduce numerical costs and to allow time-varying harmonic constants, necessary in seasonally ice-infested waters. As compared to the Global Ice Ocean Prediction System (GIOPS) running at CCMEP, RIOPSv2 also includes a spatial filtering of model fields as part of the observation operator for sea surface temperature. In addition to the tidal harmonic analysis, the observation operator for sea level anomaly is also modified to remove the inverse barometer effect due to the application of atmospheric pressure forcing fields. RIOPSv2 is compared to GIOPS and shown to provide similar innovation statistics over a 3-year evaluation period. Specific improvements are found in the vicinity of the Gulf Stream for all model fields due to the higher model grid-resolution, with smaller root-mean-squared (RMS) innovations for RIOPSv2 of about 5 cm for SLA and 0.5 °C for SST. Verification against along-track satellite observations demonstrates the improved representation of meso-scale features in RIOPSv2 compared to GIOPS, with increased correlations of SLA (0.83 compared to 0.73) and reduced RMS differences (12 cm compared to 14 cm). While the RIOPSv2 grid resolution is 3 times higher than GIOPS, the power spectral density of surface kinetic energy provides an indication that the effective resolution of RIOPSv2 is roughly double that of the global system (35 km as compared to 66 km). Observations made as part of the Year of Polar Prediction (2017–19) provide a rare glimpse at errors in Arctic water mass properties and show salinity biases of 0.3–0.4 psu in the eastern Beaufort Sea in RIOPSv2. Text Arctic Archipelago Arctic Arctic Ocean Beaufort Sea Canadian Arctic Archipelago Copernicus Publications: E-Journals Arctic Arctic Ocean Canada Canadian Arctic Archipelago Pacific
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description Canada has the longest coastline in the world and includes a diversity of ocean environments, from the frozen waters of the Canadian Arctic Archipelago to the confluence region of Labrador and Gulf Stream waters on the East Coast. There is a strong need for a pan-Canadian operational regional ocean prediction capacity covering all Canadian coastal areas, in support of marine activities including emergency response, search and rescue as well as safe navigation in ice-infested waters. Here we present the first pan-Canadian operational regional ocean analysis system developed as part of the Regional Ice Ocean Prediction System version 2 (RIOPSv2) running in operations at the Canadian Centre for Meteorological and Environmental Prediction (CCMEP). The RIOPSv2 domain extends from 26° N in the Atlantic Ocean through the Arctic Ocean to 44° N in the Pacific Ocean, with a model grid-resolution that varies between 3 and 8 km. RIOPSv2 includes a multi-variate data assimilation system based on a reduced-order extended Kalman filter together with a 3DVar bias correction system for water mass properties. The analysis system assimilates satellite observations of sea level anomaly and sea surface temperature, as well as in situ temperature and salinity measurements. Background model error is specified in terms of seasonally varying model anomalies from a 10-year forced model integration allowing inhomogeneous anisotropic multi-variate error covariances. A novel online tidal harmonic analysis method is introduced that uses a sliding-window approach to reduce numerical costs and to allow time-varying harmonic constants, necessary in seasonally ice-infested waters. As compared to the Global Ice Ocean Prediction System (GIOPS) running at CCMEP, RIOPSv2 also includes a spatial filtering of model fields as part of the observation operator for sea surface temperature. In addition to the tidal harmonic analysis, the observation operator for sea level anomaly is also modified to remove the inverse barometer effect due to the application of atmospheric pressure forcing fields. RIOPSv2 is compared to GIOPS and shown to provide similar innovation statistics over a 3-year evaluation period. Specific improvements are found in the vicinity of the Gulf Stream for all model fields due to the higher model grid-resolution, with smaller root-mean-squared (RMS) innovations for RIOPSv2 of about 5 cm for SLA and 0.5 °C for SST. Verification against along-track satellite observations demonstrates the improved representation of meso-scale features in RIOPSv2 compared to GIOPS, with increased correlations of SLA (0.83 compared to 0.73) and reduced RMS differences (12 cm compared to 14 cm). While the RIOPSv2 grid resolution is 3 times higher than GIOPS, the power spectral density of surface kinetic energy provides an indication that the effective resolution of RIOPSv2 is roughly double that of the global system (35 km as compared to 66 km). Observations made as part of the Year of Polar Prediction (2017–19) provide a rare glimpse at errors in Arctic water mass properties and show salinity biases of 0.3–0.4 psu in the eastern Beaufort Sea in RIOPSv2.
format Text
author Smith, Gregory C.
Liu, Yimin
Benkiran, Mounir
Chikhar, Kamel
Surcel Colan, Dorina
Testut, Charles-Emmanuel
Dupont, Frederic
Lei, Ji
Roy, François
Lemieux, Jean-Francois
Davidson, Fraser
spellingShingle Smith, Gregory C.
Liu, Yimin
Benkiran, Mounir
Chikhar, Kamel
Surcel Colan, Dorina
Testut, Charles-Emmanuel
Dupont, Frederic
Lei, Ji
Roy, François
Lemieux, Jean-Francois
Davidson, Fraser
The Regional Ice Ocean Prediction System v2: a pan-Canadian ocean analysis system
author_facet Smith, Gregory C.
Liu, Yimin
Benkiran, Mounir
Chikhar, Kamel
Surcel Colan, Dorina
Testut, Charles-Emmanuel
Dupont, Frederic
Lei, Ji
Roy, François
Lemieux, Jean-Francois
Davidson, Fraser
author_sort Smith, Gregory C.
title The Regional Ice Ocean Prediction System v2: a pan-Canadian ocean analysis system
title_short The Regional Ice Ocean Prediction System v2: a pan-Canadian ocean analysis system
title_full The Regional Ice Ocean Prediction System v2: a pan-Canadian ocean analysis system
title_fullStr The Regional Ice Ocean Prediction System v2: a pan-Canadian ocean analysis system
title_full_unstemmed The Regional Ice Ocean Prediction System v2: a pan-Canadian ocean analysis system
title_sort regional ice ocean prediction system v2: a pan-canadian ocean analysis system
publishDate 2020
url https://doi.org/10.5194/gmd-2020-255
https://gmd.copernicus.org/preprints/gmd-2020-255/
geographic Arctic
Arctic Ocean
Canada
Canadian Arctic Archipelago
Pacific
geographic_facet Arctic
Arctic Ocean
Canada
Canadian Arctic Archipelago
Pacific
genre Arctic Archipelago
Arctic
Arctic Ocean
Beaufort Sea
Canadian Arctic Archipelago
genre_facet Arctic Archipelago
Arctic
Arctic Ocean
Beaufort Sea
Canadian Arctic Archipelago
op_source eISSN: 1991-9603
op_relation doi:10.5194/gmd-2020-255
https://gmd.copernicus.org/preprints/gmd-2020-255/
op_doi https://doi.org/10.5194/gmd-2020-255
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