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Sea ice thickness distribution (ITD) Model for the Arctic, links to NetCDF files

Ungermann, Mischa ; Tremblay, L Bruno ; Martin, Torge ; [et al.]

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In: Supplement to: Ungermann, Mischa; Tremblay, L Bruno; Martin, Torge; Losch, Martin (2017): Impact of the Ice Strength Formulation on the Performance of a Sea Ice Thickness Distribution Model in the Arctic. Journal of Geophysical Research: Oceans, 122(3), 2090-2107, https://doi.org/10.1002/2016JC012128

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Publication Date: 2023-05-12

Description: The impact of a subgrid-scale ice thickness distribution (ITD) and two standard ice strength formulations on simulated Arctic sea ice climate is investigated. To this end different model configurations with and without an ITD were tuned by minimizing the weighted mean error between the simulated and observed sea ice concentration, thickness and drift speed with an semi-automatic parameter optimization routine. The standard ITD and ice strength parameterization lead to larger errors when compared to the simple single-category model with an ice strength parameterization based on the mean ice thickness. Interestingly, the simpler ice strength formulation, which depends linearly on the mean ice thickness, also reduces the model-observation error when using an ITD. For the ice strength parameterization that makes use of the ITD, the effective ice strength depends strongly on the number of thickness categories, so that introducing more categories can lead to overall thicker ice that is more easily deformed.

Keywords: Arctic; File content; File format; File name; File size; pan-Arctic; Uniform resource locator/link to file

Type: Dataset

Format: text/tab-separated-values, 30 data points

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Amplified Arctic Surface Warming and Sea Ice Loss Due to Phytoplankton and Colored Dissolved Material (2021)

Pefanis, Vasileios ; Losa, Svetlana N. ; Losch, Martin ; [et al.]

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Publication Date: 2021-07-05

Description: Optically active water constituents attenuate solar radiation and hence affect the vertical distribution of energy in the upper ocean. To understand their implications, we operate an ocean biogeochemical model coupled to a general circulation model with sea ice. Incorporating the effect of phytoplankton and colored dissolved organic matter (CDOM) on light attenuation in the model increases the sea surface temperature in summer and decreases sea ice concentration in the Arctic Ocean. Locally, the sea ice season is reduced by up to one month. CDOM drives a significant part of these changes, suggesting that an increase of this material will amplify the observed Arctic surface warming through its direct thermal effect. Indirectly, changing advective processes in the Nordic Seas may further intensify this effect. Our results emphasize the phytoplankton and CDOM feedbacks on the Arctic ocean and sea ice system and underline the need to consider these effects in future modeling studies to enhance their plausibility.

Description: Plain Language Summary: The amount of microalgae and colored dissolved organic material in the ocean determines how much light is absorbed in the surface waters and how much can reach greater depths. The vertical distribution of energy affects the upper ocean temperature and general circulation. Here, we use a numerical ocean model with biogeochemistry and sea ice, in which the individual effects of microalgae and colored dissolved organic matter can be turned on and off separately. When both effects are turned on, the summertime surface temperatures in the Arctic are larger and consequently more sea ice melts, so that the sea ice season is shorter by up to one month. We find that, to a large extent, the colored dissolved material is responsible for these changes. An increase of this material due to climate change will amplify the observed Arctic surface warming. For better projections of climate change, new models should account for the effect of these light‐absorbing water constituents.

Description: Key Points: Colored dissolved material is responsible for a significant part of the induced surface warming and sea ice loss in the Arctic Ocean. The combined effect of optical constituents reduces the sea ice season by up to one month. Considering the properties of optical constituents and their variability will enhance the plausibility of future modeling studies.

Description: Federal Agency for Scientific Organizations (FASO) Russia http://dx.doi.org/10.13039/501100013176

Description: German Research Foundation (DFG) http://dx.doi.org/10.13039/501100001659

Description: Helmholtz Climate Initiative (REKLIM)

Keywords: 551,9 ; phytoplankton ; CDOM ; Arctic Ocean ; colored dissolved organic matter ; radiative effect ; light attenuation

Type: article

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