Combined GNSS reflectometry–refractometry for automated and continuous in situ surface mass balance estimation on an Antarctic ice shelf

The Cryosphere Pub Date : 2023-11-22 DOI:10.5194/tc-17-4903-2023

L. Steiner, H. Schmithüsen, J. Wickert, O. Eisen

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Abstract

Abstract. Reliable in situ surface mass balance (SMB) estimates in polar regions are scarce due to limited spatial and temporal data availability. This study aims at deriving automated and continuous specific SMB time series for fast-moving parts of ice sheets and shelves (flow velocity > 10 m a−1) by developing a combined global navigation satellite system (GNSS) reflectometry and refractometry (GNSS-RR) method. In situ snow density, snow water equivalent (SWE), and snow deposition or erosion are estimated simultaneously as an average over an area of several square meters and independently on weather conditions. The combined GNSS-RR method is validated and investigated regarding its applicability to a moving, high-latitude ice shelf. A combined GNSS-RR system was therefore installed in November 2021 on the Ekström ice shelf (flow velocity ≈ 150 m a−1) in Dronning Maud Land, Antarctica. The reflected and refracted GNSS observations from the site are post-processed to obtain snow accumulation (deposition and erosion), SWE, and snow density estimates with a 15 min temporal resolution. The results of the first 16 months of data show a high level of agreement with manual and automated reference observations from the same site. Snow accumulation, SWE, and density are derived with uncertainties of around 9 cm, 40 kg m−2 a−1, and 72 kg m−3, respectively. This pilot study forms the basis for extending observational networks with GNSS-RR capabilities, particularly in polar regions. Regional climate models, local snow modeling, and extensive remote sensing data products will profit from calibration and validation based on such in situ time series, especially if many such sensors will be deployed over larger regional scales.

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将全球导航卫星系统反射测量法和折射测量法结合起来，对南极冰架进行自动、连续的原地表面质量平衡估算

摘要。由于空间和时间数据有限，极地地区可靠的原位地表质量平衡（SMB）估算非常稀缺。本研究旨在通过开发全球导航卫星系统（GNSS）反射测量和折射测量（GNSS-RR）相结合的方法，得出冰原和冰架快速移动部分（流速大于 10 m a-1）的自动和连续的特定 SMB 时间序列。原位雪密度、雪水当量（SWE）和雪沉积或侵蚀同时作为几平方米面积的平均值进行估算，不受天气条件的影响。对 GNSS-RR 组合方法进行了验证，并研究了其对移动的高纬度冰架的适用性。因此，2021 年 11 月在南极洲 Dronning Maud Land 的 Ekström 冰架（流速 ≈ 150 米/秒）上安装了全球导航卫星系统和遥感相结合的系统。对该站点的反射和折射全球导航卫星系统观测数据进行后处理，以获得积雪（沉积和侵蚀）、SWE 和雪密度估算值，时间分辨率为 15 分钟。前 16 个月的数据结果表明，与同一地点的人工和自动参考观测结果高度一致。得出的积雪量、SWE 和密度的不确定性分别约为 9 厘米、40 千克 m-2 a-1 和 72 千克 m-3。这项试验研究为扩展具有全球导航卫星系统-RR 功能的观测网络奠定了基础，特别是在极地地区。区域气候模型、当地积雪模型和大量遥感数据产品将受益于基于此类原地时间序列的校准和验证，特别是如果许多此类传感器将部署在更大的区域范围内。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Cryosphere

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