脉状水流增强了冰中的同位素扩散

IF 4.4 2区地球科学 Q1 GEOGRAPHY, PHYSICAL

Cryosphere Pub Date : 2023-07-26 DOI:10.5194/tc-17-3063-2023

F. Ng

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引用次数: 1

摘要

摘要冰盖中水稳定同位素（18O和D）信号的扩散平滑从根本上限制了从这些冰芯代理中获取的气候信息。过去的理论解释说，在冰下的多晶冰中，内部水脉网络中的快速扩散“短路”了内部晶粒中的缓慢扩散，导致“过度扩散”，使信号平滑率高于冰单晶中的自扩散率。但对过度扩散的控制还远远没有完全理解。在这里，建模表明，矿脉中的水流通过改变同位素浓度的三维场以及矿脉和晶体之间的同位素转移来放大过度扩散。信号平滑的速率不仅取决于温度、纹理和晶粒尺寸以及信号波长，还取决于水流速度的变化，这可以使速率增加1到2个数量级。这种调制可以显著影响格陵兰岛和南极洲的冰芯点的信号平滑，如GRIP（格陵兰冰芯项目）和EPICA（欧洲南极冰芯项目 101–102 m yr−1。这种量级的速度也产生了先前对GRIP全新世冰和EPICA圆顶C海洋同位素第19阶段冰的研究所推断的过量扩散水平。因此，脉流介导的过量扩散可能有助于解释其他冰芯中模拟和光谱推导的扩散长度之间的不匹配。我们还表明，过量扩散使同位素信号对扩散长度的光谱估计产生偏差（使其取决于信号波长），并使表面温度从扩散长度剖面的构建产生偏差（通过增加冰对低于firn的扩散长度的贡献）。我们的研究结果警告不要使用单晶同位素扩散率来表示大块冰的扩散率。预测冰芯中溢出扩散模式的必要性要求对其发生的同位素记录进行系统研究，并提高对冰原中矿脉尺度水文的理解。

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Isotopic diffusion in ice enhanced by vein-water flow

Abstract. Diffusive smoothing of signals on the water stable isotopes (18O and D) in ice sheets fundamentally limits the climatic information retrievable from these ice-core proxies. Past theories explained how, in polycrystalline ice below the firn, fast diffusion in the network of intergranular water veins “short-circuits” the slow diffusion within crystal grains to cause “excess diffusion”, enhancing the rate of signal smoothing above that implied by self-diffusion in ice monocrystals. But the controls of excess diffusion are far from fully understood. Here, modelling shows that water flow in the veins amplifies excess diffusion by altering the three-dimensional field of isotope concentration and isotope transfer between veins and crystals. The rate of signal smoothing depends not only on temperature, the vein and grain sizes, and signal wavelength, but also on vein-water flow velocity, which can increase the rate by 1 to 2 orders of magnitude. This modulation can significantly impact signal smoothing at ice-core sites in Greenland and Antarctica, as shown by simulations for the GRIP (Greenland Ice Core Project) and EPICA (European Project for Ice Coring in Antarctica) Dome C sites, which reveal sensitive modulation of their diffusion-length profiles when vein-flow velocities reach ∼ 101–102 m yr−1. Velocities of this magnitude also produce the levels of excess diffusion inferred by previous studies for Holocene ice at GRIP and ice of Marine Isotope Stage 19 at EPICA Dome C. Thus, vein-flow-mediated excess diffusion may help explain the mismatch between modelled and spectrally derived diffusion lengths in other ice cores. We also show that excess diffusion biases the spectral estimation of diffusion lengths from isotopic signals (by making them dependent on signal wavelength) and the reconstruction of surface temperature from diffusion-length profiles (by increasing the ice contribution to diffusion length below the firn). Our findings caution against using the monocrystal isotopic diffusivity to represent the bulk-ice diffusivity. The need to predict the pattern of excess diffusion in ice cores calls for systematic study of isotope records for its occurrence and improved understanding of vein-scale hydrology in ice sheets.

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来源期刊

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.