Chemical abrasion: the mechanics of zircon dissolution

IF 2.7 Q2 GEOCHEMISTRY & GEOPHYSICS

Geochronology Pub Date : 2023-04-03 DOI:10.5194/gchron-5-127-2023

A. McKanna, Isabel Koran, B. Schoene, R. Ketcham

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引用次数: 4

Abstract

Abstract. Chemical abrasion is a technique that combines thermal annealing and partial dissolution in hydrofluoric acid (HF) to selectively remove radiation-damaged portions of zircon crystals prior to U–Pb isotopic analysis, and it is applied ubiquitously to zircon prior to U–Pb isotope dilution thermal ionization mass spectrometry (ID-TIMS). The mechanics of zircon dissolution in HF and the impact of different leaching conditions on the zircon structure, however, are poorly resolved. We present a microstructural investigation that integrates microscale X-ray computed tomography (µCT), scanning electron microscopy, and Raman spectroscopy to evaluate zircon dissolution in HF. We show that µCT is an effective tool for imaging metamictization and complex dissolution networks in three dimensions. Acid frequently reaches crystal interiors via fractures spatially associated with radiation damage zoning and inclusions to dissolve soluble high-U zones, some inclusions, and material around fractures, leaving behind a more crystalline zircon residue. Other acid paths to crystal cores include the dissolution of surface-reaching inclusions and the percolation of acid across zones with high defect densities. In highly crystalline samples dissolution is crystallographically controlled with dissolution proceeding almost exclusively along the c axis. Increasing the leaching temperature from 180 to 210 ∘C results in deeper etching textures, wider acid paths, more complex internal dissolution networks, and greater volume losses. How a grain dissolves strongly depends on its initial radiation damage content and defect distribution as well as the size and position of inclusions. As such, the effectiveness of any chemical abrasion protocol for ID-TIMS U–Pb geochronology is likely sample-dependent. We also briefly discuss the implications of our findings for deep-time (U-Th)/He thermochronology.

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化学磨损:锆石溶解的机理

摘要化学磨损是一种结合热退火和氢氟酸(HF)部分溶解的技术，在U-Pb同位素分析之前选择性地去除锆石晶体中辐射损伤的部分，在U-Pb同位素稀释热电离质谱分析(ID-TIMS)之前普遍应用于锆石。然而，对于HF中锆石的溶解机理以及不同浸出条件对锆石结构的影响，目前还没有得到很好的解决。我们提出了一项显微结构研究，结合了微尺度x射线计算机断层扫描(µCT)，扫描电子显微镜和拉曼光谱来评估HF中的锆石溶解。我们发现µCTis是三维成像元化和复杂溶解网络的有效工具。酸经常到达与辐射损伤分区和包裹体相关的裂缝晶体内部，溶解可溶性高u带，一些包裹体和裂缝周围的物质，留下更结晶的锆石残留物。其他酸途径包括到达表面的包裹体的溶解和酸在高缺陷密度区域的渗透。在高结晶样品中，溶解受晶体学控制，溶解过程几乎完全沿着c轴进行。将浸出温度从180°C增加到210°C，会造成更深的蚀刻纹理、更宽的酸路、更复杂的内部溶解网络和更大的体积损失。晶粒的溶解程度取决于其初始辐射损伤含量、缺陷分布以及夹杂物的大小和位置。因此，任何用于ID-TIMS U-Pb地质年代学的化学磨损方案的有效性都可能取决于样品。我们还简要讨论了我们的发现对深时(U-Th)/He热年代学的意义。

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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来源期刊

Geochronology Earth and Planetary Sciences-Paleontology

CiteScore

6.60

自引率

0.00%

发文量

审稿时长

19 weeks