Ice and Snow Thickness Variability and Change in the High Arctic Ocean Observed by In Situ Measurements

Haas, Christian; Beckers, Justin; King, Joshua; Silis, Arvids; Stroeve, Julienne; Wilkinson, Jeremy; Notenboom, Bernice; Schweiger, Axel; Hendricks, Stefan

doi:10.1002/2017gl075434

Cited by 52 publications

(61 citation statements)

References 23 publications

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“…8). For a comparison of CryoSat-2 thickness to in situ observations we refer to Haas et al (2017). The misfit to the CryoSat-2 ice thickness in April 2015 is similar to the misfit to the ITRP shown in Fig.…”

Section: Sea Ice-ocean Modelsupporting

confidence: 53%

“…Such rigorous assessments can be performed in an efficient manner by the quantitative network design (QND) approach, allowing for an objective evaluation of the added value of observations for a given aspect of a model simulation or forecast. The technique originates from seismology (Hardt and Scherbaum, 1994) and was first applied to the climate system by Rayner et al (1996), who optimised the spatial distribution of in situ observations of atmospheric carbon dioxide to achieve minimum uncertainty in inferred surface fluxes. After an initial QND study that demonstrated the feasibility of the approach for remote sensing of the column-integrated atmospheric carbon dioxide concentration (Rayner and O'Brien, 2001), QND is now routinely applied in the design of CO 2 space missions (e.g., Patra et al, 2003;Houweling et al, 2004;Crisp et al, 2004;Feng et al, 2009;Kadygrov et al, 2009;Kaminski et al, 2010;Hungershoefer et al, 2010;Rayner et al, 2014;Bovensmann et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Arctic Mission Benefit Analysis: impact of sea ice thickness, freeboard, and snow depth products on sea ice forecast performance

et al. 2018

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Assimilation of remote-sensing products of sea ice thickness (SIT) into sea ice-ocean models has been shown to improve the quality of sea ice forecasts. Key open questions are whether assimilation of lower-level data products such as radar freeboard (RFB) can further improve model performance and what performance gains can be achieved through joint assimilation of these data products in combination with a snow depth product. The Arctic Mission Benefit Analysis system was developed to address this type of question. Using the quantitative network design (QND) approach, the system can evaluate, in a mathematically rigorous fashion, the observational constraints imposed by individual and groups of data products. We demonstrate the approach by presenting assessments of the observation impact (added value) of different Earth observation (EO) products in terms of the uncertainty reduction in a 4-week forecast of sea ice volume (SIV) and snow volume (SNV) for three regions along the Northern Sea Route in May 2015 using a coupled model of the sea ice-ocean system, specifically the Max Planck Institute Ocean Model. We assess seven satellite products: three real products and four hypothetical products. The real products are monthly SIT, sea ice freeboard (SIFB), and RFB, all derived from CryoSat-2 by the Alfred Wegener Institute. These are complemented by two hypothetical monthly laser free-board (LFB) products with low and high accuracy, as well as two hypothetical monthly snow depth products with low and high accuracy.On the basis of the per-pixel uncertainty ranges provided with the CryoSat-2 SIT, SIFB, and RFB products, the SIT and RFB achieve a much better performance for SIV than the SIFB product. For SNV, the performance of SIT is only low, the performance of SIFB is higher and the performance of RFB is yet higher. A hypothetical LFB product with low accuracy (20 cm uncertainty) falls between SIFB and RFB in performance for both SIV and SNV. A reduction in the uncertainty of the LFB product to 2 cm yields a significant increase in performance.Combining either of the SIT or freeboard products with a hypothetical snow depth product achieves a significant performance increase. The uncertainty in the snow product matters: a higher-accuracy product achieves an extra performance gain. Providing spatial and temporal uncertainty correlations with the EO products would be beneficial not only for QND assessments, but also for assimilation of the products.

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Section: Sea Ice-ocean Modelsupporting

confidence: 53%

Section: Introductionmentioning

confidence: 99%

Arctic Mission Benefit Analysis: impact of sea ice thickness, freeboard, and snow depth products on sea ice forecast performance

et al. 2018

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“…Several studies have shown consistent snow depth distribution patterns on MYI in relation to the undulating ice surface with more snow accumulating in low points and thinner snow/snow‐free regions on high elevations (e.g., hummocks; Haas et al, ; Iacozza & Barber, ; Lange, Flores, et al, ). Based on this consistent snow distribution pattern for MYI and the identification of high chl a biomass at the bottom of hummocks (Lange, Flores, et al, ), we hypothesize that MYI provides a more stable under‐ice light environment for ice algae compared to FYI.…”

Section: Introductionmentioning

confidence: 91%

Contrasting Ice Algae and Snow‐Dependent Irradiance Relationships Between First‐Year and Multiyear Sea Ice

Lange

Haas

Charette

et al. 2019

Geophysical Research Letters

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During the 2018 Multidisciplinary Arctic Program‐Last Ice in the Lincoln Sea, we sampled 45 multiyear ice (MYI) and 34 first‐year ice (FYI) cores, combined with snow depth, ice thickness, and transmittance surveys from adjacent level FYI and undeformed MYI. FYI sites show a decoupling between bottom‐ice chlorophyll a (chl a) and snow depth; however, MYI showed a significant correlation between ice‐algal chl a biomass and snow depth. Topographic control of the snow cover resulted in greater spatiotemporal variability of the snow over the level FYI, and consequently transmittance, compared to MYI with an undulating surface. The coupled patterns of snow depth, transmittance, and chl a indicate that MYI provides an environment with more stable light conditions for ice algal growth. The importance of sea ice surface topography for ice algal habitat underpins the potential ecological changes associated with projected increased ice dynamics and deformation.

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“…However, that climatology was developed using data collected between 1954 and 1991 and was from a limited number of stations. While some studies have shown the Warren climatology is similar to contemporary snow depths over MYI (e.g., Haas et al, 2017), it does not include snow depths over the increasing expanse of seasonal ice currently found throughout the Arctic (e.g., Gerland & Haas, 2011;Hansen et al, 2013;Maslanik et al, 2007Maslanik et al, , 2011Nghiem et al, 2007;Renner et al, 2014). Recent snow and ice field measurements have shifted from MYI (e.g., Sturm et al, 2002bSturm et al, , 2006 to relatively new ice, because the predominant ice types have become younger over much of the Arctic (e.g., Haapala et al, 2013;King et al, 2015;Kwok et al, 2009;Kurtz et al, 2013;Kurtz & Farrell, 2011;Meier et al, 2014;Newman et al, 2014;Webster et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

A Distributed Snow‐Evolution Model for Sea‐Ice Applications (SnowModel)

et al. 2018

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Snow‐depth distributions on sea ice have substantial impacts on winter ice growth and summer ice melt. There are two types of wind‐related snow distributions in this environment: snowdrifts that form around ice pressure ridges; and snow dunes and other snow bedforms that form on relatively level, undeformed ice. A snow‐evolution modeling system (SnowModel) was tested against winter snow observations collected during the Norwegian young sea ICE expedition (N‐ICE2015) north of Svalbard, with an emphasis on reproducing these two types of snow distributions. The SnowModel simulation spanned 1 year, summer 2014 through summer 2015, over a 1.5 km by 1.5 km domain, using a 1 m horizontal grid increment and 3 h time step. Existing SnowModel components, created originally for terrestrial applications, performed energy balance, snow property, snowdrift, and data assimilation calculations in response to prescribed meteorological forcings. A new SnowModel component, SnowDunes, was created to simulate snow‐bedform distributions on level, undeformed ice. Model results reproduced observed snowdrift profiles around pressure ridges and snow‐depth distributions over level, undeformed ice, resulting in physically realistic snow heterogeneity and property information. We conclude that the SnowModel toolkit contains the components required to simulate most processes driving the seasonal distribution of snow on sea ice. SnowModel can evolve snow on sea ice over local to pan‐Arctic areas, using grid increments ranging from 1 m to tens of km, and time increments of subhourly to daily.

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Ice and Snow Thickness Variability and Change in the High Arctic Ocean Observed by In Situ Measurements

Cited by 52 publications

References 23 publications

Arctic Mission Benefit Analysis: impact of sea ice thickness, freeboard, and snow depth products on sea ice forecast performance

Arctic Mission Benefit Analysis: impact of sea ice thickness, freeboard, and snow depth products on sea ice forecast performance

Contrasting Ice Algae and Snow‐Dependent Irradiance Relationships Between First‐Year and Multiyear Sea Ice

A Distributed Snow‐Evolution Model for Sea‐Ice Applications (SnowModel)

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