Similar sources but distinct δ13C signatures in adjacent low-temperature travertines from Laguna Amarga (Southern Patagonian Andes)

IF 2.7 2区地球科学 Q1 GEOLOGY

Sedimentary Geology Pub Date : 2024-11-01 DOI:10.1016/j.sedgeo.2024.106758

Paulo Quezada , Leonardo Fadel Cury , Mauricio Calderón , Carolina Henríquez , Luis Mancini , Joicy Micheletto , Gustavo Barbosa Athayde , Anelize Bahniuk Rumbelsperger

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引用次数: 0

Abstract

This study examined the waters and carbonates from two cold spring travertines (ca. 13 °C) located on the sun-exposed (north-facing travertine) and sun-shaded (south-facing travertine) margins of Laguna Amarga, an alkaline lake from the semiarid region of the eastern Patagonian Andes (51°S).

The travertines are composed of calcite + low-Mg calcite ± aragonite. Both exhibit similar sedimentological transitions along their longitudinal profiles. In the proximal zones, biologically-influenced carbonates form in wetland-like environments. Spherulitic calcite precipitates in association with extracellular polymeric substances in microbial biofilms containing cyanobacteria-like molds at the vent of the south-facing travertine, while aragonite spherulite formation at the north-facing travertine vent also involves sulfate-reducing bacteria, as indicated by their close association with framboidal pyrite. Downstream, in the intermediate and distal zones, crystalline dendrites predominantly precipitate due to increased turbulence-induced CO₂ degassing.

Both travertines share a similar range of carbonate ⁸⁷Sr/⁸⁶Sr composition (0.70720–0.70740) and isotopic signatures of the spring waters, including δ²H (ca. −110 ‰ VSMOW), δ¹⁸O_water (ca. −14 ‰ VSMOW) and δ¹³C-DIC (ca. −5 ‰ VPDB), suggesting common sources and processes influencing fluid composition. This points to the dissolution of carbonates from mudstone-rich marine units of the Lower Cretaceous (δ¹³C ca. −1 ‰ VPDB) and Upper Cretaceous (δ¹³C ca. −10 ‰ VPDB) during shallow subsurface circulation of meteoric waters through the bedrock. The carbon isotopic composition of the deposits resembles those of endogenic travertines (δ¹³C_trav −1.2 to 5.3 ‰ VPDB), with the highest δ¹³C_trav values associated with carbonates from the vents. However, the involvement of deep CO₂ sources is unclear and epigenic processes capable of producing the observed ¹³C enrichments are discussed.

Despite their common sources, similar sedimentological features and δ¹⁸O_trav compositional range (−12.4 to −10.1 ‰ VPDB), the δ¹³C_trav values are lower in the south-facing travertine (−1.2 to 1.9 ‰ VPDB) compared to the north-facing travertine (1.8 to 5.3 ‰ VPDB). This disparity is inferred to result from variations in local environmental conditions due to different levels of insolation, which favored the incorporation of soil-derived CO₂ in the south-facing travertine and likely increased photosynthetic productivity in the north-facing travertine, thereby shifting their δ¹³C_trav signatures to lower and higher values, respectively. These relationships highlight the sensitivity of low-temperature spring carbonates to subtle environmental changes at basin scales.

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阿玛尔加湖（巴塔哥尼亚安第斯山脉南部）相邻低温变质岩中相似的来源和不同的δ13C特征

该研究考察了位于巴塔哥尼亚安第斯山脉东部（南纬 51°）半干旱地区的碱性湖泊阿玛加湖（Laguna Amarga）的向阳（北向洞石）和向阴（南向洞石）边缘的两个冷泉洞石（约 13 °C）的水体和碳酸盐。两者的纵向剖面都呈现出类似的沉积转变。在近端区域，受生物影响的碳酸盐在类似湿地的环境中形成。球状方解石沉淀与南向洞石喷口处含有蓝藻类霉菌的微生物生物膜中的胞外聚合物物质有关，而北向洞石喷口处文石球状体的形成也与硫酸盐还原菌有关，这从它们与框架黄铁矿的密切联系中可以看出。在下游的中间区和远端区，由于湍流引起的二氧化碳脱气增加，结晶树枝状岩主要沉淀下来。两个洞穴都具有相似的碳酸盐 87Sr/86Sr 组成范围（0.70720-0.70740）和泉水同位素特征，包括δ2H（约-110 ‰ VSMOW）、δ18Owater（约-14 ‰ VSMOW）和δ13C-DIC（约-5 ‰ VPDB），表明影响流体组成的共同来源和过程。这表明，在陨石水通过基岩的浅层地下循环过程中，下白垩统（δ13C 约-1 ‰ VPDB）和上白垩统（δ13C 约-10 ‰ VPDB）富含泥岩的海相单元中的碳酸盐发生了溶解。沉积物的碳同位素组成类似于内生洞穴岩（δ13Ctrav -1.2至5.3‰VPDB），最高的δ13Ctrav值与来自喷口的碳酸盐有关。尽管它们具有共同的来源、相似的沉积特征和δ18Otrav成分范围（-12.4至-10.1‰VPDB），但与北向洞石（1.8至5.3‰VPDB）相比，南向洞石的δ13Ctrav值较低（-1.2至1.9‰VPDB）。据推断，这种差异是由于日照水平不同导致当地环境条件的变化造成的，日照水平的不同有利于南向洞石吸收土壤中的二氧化碳，而北向洞石的光合生产力可能会提高，从而使它们的δ13Ctrav特征值分别变低和变高。这些关系凸显了低温泉碳酸盐岩对流域尺度上微妙环境变化的敏感性。

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

Sedimentary Geology 地学-地质学

CiteScore

5.10

自引率

7.10%

发文量

133

审稿时长

32 days

期刊介绍： Sedimentary Geology is a journal that rapidly publishes high quality, original research and review papers that cover all aspects of sediments and sedimentary rocks at all spatial and temporal scales. Submitted papers must make a significant contribution to the field of study and must place the research in a broad context, so that it is of interest to the diverse, international readership of the journal. Papers that are largely descriptive in nature, of limited scope or local geographical significance, or based on limited data will not be considered for publication.