Episodes of fissure formation in the Alps: connecting quartz fluid inclusion, fissure monazite age, and fissure orientation data.

IF 1.8 2区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY Swiss Journal of Geosciences Pub Date : 2021-01-01 Epub Date: 2021-05-10 DOI:10.1186/s00015-021-00391-9
Edwin Gnos, Josef Mullis, Emmanuelle Ricchi, Christian A Bergemann, Emilie Janots, Alfons Berger
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引用次数: 6

Abstract

Fluid assisted Alpine fissure-vein and cleft formation starts at prograde, peak or retrograde metamorphic conditions of 450-550 °C and 0.3-0.6 GPa and below, commonly at conditions of ductile to brittle rock deformation. Early-formed fissures become overprinted by subsequent deformation, locally leading to a reorientation. Deformation that follows fissure formation initiates a cycle of dissolution, dissolution/reprecipitation or new growth of fissure minerals enclosing fluid inclusions. Although fissures in upper greenschist and amphibolite facies rocks predominantly form under retrograde metamorphic conditions, this work confirms that the carbon dioxide fluid zone correlates with regions of highest grade Alpine metamorphism, suggesting carbon dioxide production by prograde devolatilization reactions and rock-buffering of the fissure-filling fluid. For this reason, fluid composition zones systematically change in metamorphosed and exhumed nappe stacks from diagenetic to amphibolite facies metamorphic rocks from saline fluids dominated by higher hydrocarbons, methane, water and carbon dioxide. Open fissures are in most cases oriented roughly perpendicular to the foliation and lineation of the host rock. The type of fluid constrains the habit of the very frequently crystallizing quartz crystals. Open fissures also form in association with more localized strike-slip faults and are oriented perpendicular to the faults. The combination of fissure orientation, fissure quartz fluid inclusion and fissure monazite-(Ce) (hereafter monazite) Th-Pb ages shows that fissure formation occurred episodically (1) during the Cretaceous (eo-Alpine) deformation cycle in association with exhumation of the Austroalpine Koralpe-Saualpe region (~ 90 Ma) and subsequent extensional movements in association with the formation of the Gosau basins (~ 90-70 Ma), (2) during rapid exhumation of high-pressure overprinted Briançonnais and Piemontais units (36-30 Ma), (3) during unroofing of the Tauern and Lepontine metamorphic domes, during emplacement and reverse faulting of the external Massifs (25-12 Ma; except Argentera) and due to local dextral strike-slip faulting in association with the opening of the Ligurian sea, and (4) during the development of a young, widespread network of ductile to brittle strike-slip faults (12-5 Ma).

Supplementary information: The online version contains supplementary material available at 10.1186/s00015-021-00391-9.

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阿尔卑斯地区裂缝形成时期:连接石英流体包裹体、裂缝独居石年龄和裂缝定向资料。
流体辅助的高寒裂隙脉和裂缝形成始于450-550℃、0.3-0.6 GPa及以下的进阶、峰值或逆行变质条件,通常在韧性-脆性岩石变形条件下形成。早期形成的裂缝被随后的变形覆盖,局部导致重新定向。裂缝形成后的变形启动了溶蚀、溶蚀/再沉淀或包裹流体包裹体的裂隙矿物新生长的循环。虽然上绿片岩和角闪岩相岩石中的裂缝主要形成于逆行变质条件下,但本研究证实了二氧化碳流体带与高寒变质最高级区域相关,表明二氧化碳的产生是通过裂缝充填流体的递进脱挥发反应和岩石缓冲作用进行的。因此,在以高烃、甲烷、水和二氧化碳为主的含盐流体中,变质推覆体和出土推覆体的流体组成带发生了系统的变化,从成岩相到角闪岩相变质岩。在大多数情况下,开放裂缝的方向大致垂直于寄主岩石的面理和线理。流体的类型限制了频繁结晶的石英晶体的习性。开放裂缝也与更局部的走滑断层联合形成,并垂直于断层。裂缝取向、裂缝石英流体包裹体和裂缝独居石-(Ce)(以下简称独居石)Th-Pb年龄的综合分析表明,裂缝的形成是在白垩纪(eo-Alpine)变形旋回(~ 90 Ma)与奥阿尔卑斯山脉Koralpe-Saualpe地区的挖掘(~ 90 Ma)和随后的伸展运动(~ 90-70 Ma)与戈索盆地的形成(~ 90-70 Ma)期间幕式发生的。(2)高压叠印brianonnais和Piemontais单元的快速挖掘(36-30 Ma); (3) taauern和Lepontine变质圆顶的拆顶,外部地块的侵位和反向断裂(25-12 Ma);(4)与利古里亚海的张开有关的局部右旋走滑断裂,以及在一个年轻的、广泛的韧性-脆性走滑断层网络的发展期间(12-5 Ma)。补充资料:在线版本包含补充资料,下载地址:10.1186/s00015-021-00391-9。
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
Swiss Journal of Geosciences
Swiss Journal of Geosciences 地学-地质学
CiteScore
4.50
自引率
12.90%
发文量
21
审稿时长
>12 weeks
期刊介绍: The Swiss Journal of Geosciences publishes original research and review articles, with a particular focus on the evolution of the Tethys realm and the Alpine/Himalayan orogen. By consolidating the former Eclogae Geologicae Helvetiae and Swiss Bulletin of Mineralogy and Petrology, this international journal covers all disciplines of the solid Earth Sciences, including their practical applications. The journal gives preference to articles that are of wide interest to the international research community, while at the same time recognising the importance of documenting high-quality geoscientific data in a regional context, including the occasional publication of maps.
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