To better understand recent changes of Arctic sea ice thickness and extent, it is important to distinguish between the contributions of winter growth and summer melt to the sea ice mass balance. In this study we present a Lagrangian approach to quantify summer sea ice melt in which multiyear ice (MYI) floes that were surveyed by airborne electromagnetic thickness sounding within Nares Strait during summer were backtracked, using satellite imagery, to a region in close proximity (3–20 km) to spring ice thickness surveys carried out in the Lincoln Sea. Typical modal total MYI thicknesses, including ~0.4‐m snow, ranged between 3.9 and 4.7 m in the Lincoln Sea during April. Ice‐only modal thicknesses were between 2.2 and 3.0 m in Nares Strait during August. Total thinning including snow and ice was 1.3 ± 0.1 m including 0.4 ± 0.09 m of snow melt and 0.9 ± 0.2 m of ice melt. This translates to a seasonal net heat input of 305 ± 69 MJ/m2 (262 ± 60 MJ/m2 for ice only) and seasonal net heat flux of 57 ± 13 W/m2 (45 ± 10 W/m2 for ice only), which is unlikely to be explained by solar radiation fluxes alone. Furthermore, our approach provides an improvement on traditional ice mass balance buoy estimates because it integrates melt over larger spatial scales, where melt can be highly variable due to differential melt experienced between melt ponds, bare ice, hummocks, and ridges.
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机译:为了更好地了解北极海冰厚度和范围的最新变化,区分冬季增长和夏季融化对海冰质量平衡的贡献非常重要。在这项研究中,我们提出了一种拉格朗日方法来量化夏季海冰融化的方法,其中通过卫星图像将夏季期间在Nares海峡内通过机载电磁厚度测深仪调查的多年冰(MYI)絮凝物回溯到附近区域(3 – 20 km)到林肯海进行的春季冰层厚度调查。 4月在林肯海,典型的模态总MYI厚度(包括约0.4 m的积雪)在3.9至4.7 m之间。在八月的Nares海峡,仅冰的模态厚度在2.2至3.0 m之间。包括雪和冰的总稀疏度为1.3±0.1 m,其中融雪为0.4±0.09 m和融雪为0.9±0.2 m。这意味着季节性净热量输入为305±69 MJ / m 2 (仅对于冰来说为262±60 MJ / m 2 )和季节性净热通量为57± 13 W / m 2 (仅对于冰为45±10 W / m 2 ),不可能仅靠太阳辐射通量来解释。此外,我们的方法对传统的冰块质量平衡浮标进行了改进,因为它在较大的空间尺度上整合了融化,由于融化池,裸露的冰,山岗和山脊之间经历的融化差异,融化可能高度可变。
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