0℃下天然冰和合成冰的晶粒生长

IF 4.4 2区 地球科学 Q1 GEOGRAPHY, PHYSICAL Cryosphere Pub Date : 2023-08-23 DOI:10.5194/tc-17-3443-2023
Sheng Fan, D. Prior, B. Pooley, H. Bowman, Lucy Davidson, D. Wallis, S. Piazolo, Chao Qi, D. Goldsby, T. Hager
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引用次数: 0

摘要

摘要晶粒生长可以改变天然冰的微观结构,包括晶粒大小和晶体择优取向。为了更好地理解晶粒生长过程和动力学,我们比较了在固相线温度(0 ∘C) 持续数小时至33 d.合成冰具有均匀的初始微观结构,其特征是多边形晶粒、较小的粒内畸变、很少的气泡和近乎随机的CPO。自然样本是从南极普里斯特利冰川采集的冰芯中进行二次采样的。这种天然冰具有不均匀的微观结构,其特征是大量的气泡、广泛的中心颗粒变形和CPO。在退火过程中,天然冰的平均粒度几乎没有变化,而合成冰的平均晶粒度逐渐增加。这些观测结果表明,天然冰中的晶粒生长可能比合成冰慢得多,因此,从合成冰中导出的晶粒生长规律不能直接用于估计具有不同微观结构的天然冰中晶粒尺寸的演变。天然冰的微观结构以许多固定晶界的气泡为特征。先前的研究表明,气泡钉扎提供了一种阻力,降低了晶界迁移的有效驱动力,因此与天然冰中观察到的晶粒生长抑制有关。随着退火的进行,自然晶界上气泡的数量密度(每单位面积的数量)降低,而晶粒内部气泡的数量浓度增加。这一观察结果表明,一些晶界穿过气泡,这将削弱钉扎效应,从而减少晶界迁移的作用力。一些普里斯特利冰粒在退火过程中变得异常大。我们推测,相邻晶粒之间位错密度的对比(有利于低位错密度晶粒的选择性生长)和气泡钉扎(抑制晶粒生长)与异常晶粒生长密切相关。鞋面10 m的Priestley冰芯具有较弱的CPO,并且比更深的样本具有更好的第二极大值。这种差异与退火实验中观察到的变化相似,表明在上部10 在夏季变暖期间,我是普利斯利冰川的一部分。
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Grain growth of natural and synthetic ice at 0 °C
Abstract. Grain growth can modify the microstructure of natural ice, including the grain size and crystallographic preferred orientation (CPO). To better understand grain-growth processes and kinetics, we compared microstructural data from synthetic and natural ice samples of similar starting grain sizes that were annealed at the solidus temperature (0 ∘C) for durations of a few hours to 33 d. The synthetic ice has a homogeneous initial microstructure characterized by polygonal grains, little intragranular distortion, few bubbles, and a near-random CPO. The natural ice samples were subsampled from ice cores acquired from the Priestley Glacier, Antarctica. This natural ice has a heterogeneous microstructure characterized by a considerable number of air bubbles, widespread intragranular distortion, and a CPO. During annealing, the average grain size of the natural ice barely changes, whereas the average grain size of the synthetic ice gradually increases. These observations demonstrate that grain growth in natural ice can be much slower than in synthetic ice and therefore that the grain-growth law derived from synthetic ice cannot be directly applied to estimate the grain-size evolution in natural ice with a different microstructure. The microstructure of natural ice is characterized by many bubbles that pin grain boundaries. Previous studies suggest that bubble pinning provides a resisting force that reduces the effective driving force of grain-boundary migration and is therefore linked to the inhibition of grain growth observed in natural ice. As annealing progresses, the number density (number per unit area) of bubbles on grain boundaries in the natural ice decreases, whilst the number density of bubbles in the grain interiors increases. This observation indicates that some grain boundaries sweep through bubbles, which should weaken the pinning effect and thus reduce the resisting force for grain-boundary migration. Some of the Priestley ice grains become abnormally large during annealing. We speculate that the contrast of dislocation density amongst neighbouring grains, which favours the selected growth of grains with low dislocation densities, and bubble pinning, which inhibits grain growth, are tightly associated with abnormal grain growth. The upper 10 m of the Priestley ice core has a weaker CPO and better-developed second maximum than deeper samples. The similarity of this difference to the changes observed in annealing experiments suggests that abnormal grain growth may have occurred in the upper 10 m of the Priestley Glacier during summer warming.
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来源期刊
Cryosphere
Cryosphere GEOGRAPHY, PHYSICAL-GEOSCIENCES, MULTIDISCIPLINARY
CiteScore
8.70
自引率
17.30%
发文量
240
审稿时长
4-8 weeks
期刊介绍: The Cryosphere (TC) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on all aspects of frozen water and ground on Earth and on other planetary bodies. The main subject areas are the following: ice sheets and glaciers; planetary ice bodies; permafrost and seasonally frozen ground; seasonal snow cover; sea ice; river and lake ice; remote sensing, numerical modelling, in situ and laboratory studies of the above and including studies of the interaction of the cryosphere with the rest of the climate system.
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