Chris Pierce, Mark Skidmore, Lucas Beem, Don Blankenship, Ed Adams, Christopher Gerekos
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引用次数: 0
摘要
在 2023 年的雷达回声探测(RES)勘测中,在德文冰帽下方的平坦阶地之间发现了深达 580 米的冰川下峡谷地貌。最大的峡谷将德文冰帽顶峰附近的假定盐水网络与海洋末端的斯维德鲁普出口冰川连接起来。该峡谷可能是假想水系的排水路线。峡谷底部的雷达床反射率一直比阶地低 30 分贝,这与冰川下水的预期特征相矛盾。我们将这些数据与反向散射模拟进行了比较,以证明反射率模式可能是由地形引起的。我们的模拟结果表明,沿峡谷底部不太可能出现 10 米宽的运河状水特征,但更小的特征可能难以通过 RES 检测到。我们使用二维有限差分法计算了基底温度剖面,发现底层温度可能比阶地高出 18°C。但是,温度仍然低于压力熔点,而且只有有限的证据表明,峡谷底层支持 DIC 峰和斯维尔德鲁普冰川之间的连接排水系统。德文冰帽下的地形显示了 RES 的局限性。未来的研究应评估复杂地形附近的其他校正方法,如我们在此展示的 RES 模拟。
Exploring canyons beneath Devon Ice Cap for sub-glacial drainage using radar and thermodynamic modeling
Sub-glacial canyon features up to 580 m deep between flat terraces were identified beneath Devon Ice Cap during a 2023 radar echo sounding (RES) survey. The largest canyon connects a hypothesized brine network near the Devon Ice Cap summit with the marine-terminating Sverdrup outlet glacier. This canyon represents a probable drainage route for the hypothesized water system. Radar bed reflectivity is consistently 30 dB lower along the canyon floor than on the terraces, contradicting the signature expected for sub-glacial water. We compare these data with backscattering simulations to demonstrate that the reflectivity pattern may be topographically induced. Our simulated results indicated a 10 m wide canal-like water feature is unlikely along the canyon floor, but smaller features may be difficult to detect via RES. We calculated basal temperature profiles using a 2D finite difference method and found the floor may be up to 18°C warmer than the terraces. However, temperatures remain below the pressure melting point, and there is limited evidence that the canyon floor supports a connected drainage system between the DIC summit and Sverdrup Glacier. The terrain beneath Devon Ice Cap demonstrates limitations for RES. Future studies should evaluate additional correction methods near complex terrain, such as RES simulation as we demonstrate here.
期刊介绍:
Journal of Glaciology publishes original scientific articles and letters in any aspect of glaciology- the study of ice. Studies of natural, artificial, and extraterrestrial ice and snow, as well as interactions between ice, snow and the atmospheric, oceanic and subglacial environment are all eligible. They may be based on field work, remote sensing, laboratory investigations, theoretical analysis or numerical modelling, or may report on newly developed glaciological instruments. Subjects covered recently in the Journal have included palaeoclimatology and the chemistry of the atmosphere as revealed in ice cores; theoretical and applied physics and chemistry of ice; the dynamics of glaciers and ice sheets, and changes in their extent and mass under climatic forcing; glacier energy balances at all scales; glacial landforms, and glaciers as geomorphic agents; snow science in all its aspects; ice as a host for surface and subglacial ecosystems; sea ice, icebergs and lake ice; and avalanche dynamics and other glacial hazards to human activity. Studies of permafrost and of ice in the Earth’s atmosphere are also within the domain of the Journal, as are interdisciplinary applications to engineering, biological, and social sciences, and studies in the history of glaciology.
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