Annual Greenland accumulation rates (2009–2012) from airborne snow radar

Koenig, L.; Ivanoff, Alvaro; Alexander, Patrick; MacGregor, Joseph A.; Fettweis, Xavier; Panzer, B.; Paden, John; Forster, R. R.; Das, I.; McConnell, J. R.; Tedesco, Marco; Leuschen, Carl; Gogineni, Prasad

doi:10.5194/tc-10-1739-2016

Cited by 83 publications

(95 citation statements)

References 56 publications

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“…The Snow Radar Layer Detection (SRLD) algorithm was first developed for layer detection on land ice, in which the detection of the a-s interface and s-i interface is determined prior to the subsequent detection of deeper layers within the firn (Koenig et al, 2016). Over sea ice, only the a-s and s-i interfaces are returned by the algorithm.…”

Section: Srldmentioning

confidence: 99%

Intercomparison of snow depth retrievals over Arctic sea ice from radar data acquired by Operation IceBridge

et al. 2017

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Abstract. Since 2009, the ultra-wideband snow radar on Operation IceBridge (OIB; a NASA airborne mission to survey the polar ice covers) has acquired data in annual campaigns conducted during the Arctic and Antarctic springs. Progressive improvements in radar hardware and data processing methodologies have led to improved data quality for subsequent retrieval of snow depth. Existing retrieval algorithms differ in the way the air-snow (a-s) and snow-ice (s-i) interfaces are detected and localized in the radar returns and in how the system limitations are addressed (e.g., noise, resolution). In 2014, the Snow Thickness On Sea Ice Working Group (STOSIWG) was formed and tasked with investigating how radar data quality affects snow depth retrievals and how retrievals from the various algorithms differ. The goal is to understand the limitations of the estimates and to produce a well-documented, long-term record that can be used for understanding broader changes in the Arctic climate system. Here, we assess five retrieval algorithms by comparisons with field measurements from two groundbased campaigns, including the BRomine, Ozone, and Mercury EXperiment (BROMEX) at Barrow, Alaska; a field program by Environment and Climate Change Canada at Eureka, Nunavut; and available climatology and snowfall from ERA-Interim reanalysis. The aim is to examine available algorithms and to use the assessment results to inform the development of future approaches. We present results from these assessments and highlight key considerations for the production of a long-term, calibrated geophysical record of springtime snow thickness over Arctic sea ice.

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Section: Srldmentioning

confidence: 99%

Intercomparison of snow depth retrievals over Arctic sea ice from radar data acquired by Operation IceBridge

et al. 2017

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“…Various algorithms have 5 been developed to produce snow depth estimates from the OIB Snow Radar data (Kwok et al, 2017), with the products showing broad agreement in the regional snow depth distributions, but significant intraregional and interannual differences, due primarily to changes in the radar configuration and algorithm tuning. To account for these differences we use the snow depth data from the (i) Snow Radar Layer Detection (SRLD) (Koenig et al, 2016), (ii) NASA Goddard Space Flight Center (GSFC) (Kurtz et al, 2013) and ( …”

Section: Nasa's Operation Icebridge Datamentioning

confidence: 99%

The NASA Eulerian Snow on Sea Ice Model (NESOSIM): Initial model development and analysis

Petty¹,

Webster²,

Boisvert³

et al. 2018

Preprint

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“…cloud physics (Van Tricht et al, 2016) and turbulent fluxes (Noël et al, 2015;Fausto et al, 2016). Therefore, considerable efforts have been dedicated to evaluating and improving polar RCM output in Greenland (Ettema et al, 2010b;Van Angelen et al, 2013b;Lucas-Picher et al, 2012;Fettweis et al, 2017;Noël et al, 2015;Langen et al, 2017), using in situ SMB observations (Bales et al, 2001(Bales et al, , 2009van de Wal et al, 2012;Machguth et al, 2016), airborne radar measurements of snow accumulation (Koenig et al, 2016;Overly et al, 2016;Lewis et al, 2017) and meteorological records (Ahlstrøm et al, 2008;Kuipers Munneke et al, 2018;Smeets et al, 2018), including radiative fluxes that are required to close the ice sheet surface energy balance (SEB) and hence quantify surface melt energy.…”

Section: Introductionmentioning

confidence: 99%

Modelling the climate and surface mass balance of polar ice sheets using RACMO2 – Part 1: Greenland (1958–2016)

et al. 2018

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Abstract. We evaluate modelled Greenland ice sheet (GrIS) near-surface climate, surface energy balance (SEB) and surface mass balance (SMB) from the updated regional climate model RACMO2 . The new model version, referred to as RACMO2.3p2, incorporates updated glacier outlines, topography and ice albedo fields. Parameters in the cloud scheme governing the conversion of cloud condensate into precipitation have been tuned to correct inland snowfall underestimation: snow properties are modified to reduce drifting snow and melt production in the ice sheet percolation zone. The ice albedo prescribed in the updated model is lower at the ice sheet margins, increasing ice melt locally. RACMO2.3p2 shows good agreement compared to in situ meteorological data and point SEB/SMB measurements, and better resolves the spatial patterns and temporal variability of SMB compared with the previous model version, notably in the north-east, south-east and along the K-transect in south-western Greenland. This new model version provides updated, high-resolution gridded fields of the GrIS presentday climate and SMB, and will be used for projections of the GrIS climate and SMB in response to a future climate scenario in a forthcoming study.

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Annual Greenland accumulation rates (2009–2012) from airborne snow radar

Cited by 83 publications

References 56 publications

Intercomparison of snow depth retrievals over Arctic sea ice from radar data acquired by Operation IceBridge

Intercomparison of snow depth retrievals over Arctic sea ice from radar data acquired by Operation IceBridge

The NASA Eulerian Snow on Sea Ice Model (NESOSIM): Initial model development and analysis

Modelling the climate and surface mass balance of polar ice sheets using RACMO2 – Part 1: Greenland (1958–2016)

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