Recognizing microbial manganese reduction in lacustrine carbonate and its linkage to terrestrial biogeochemical processes

IF 7.2 1区地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Gondwana Research Pub Date : 2024-10-01 DOI:10.1016/j.gr.2024.09.013

Xubin Wang , Lin Dong , Yiwu Wang , Zhijun Jin

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Abstract

Carbonate authigenesis, the in situ precipitation of carbonate minerals within the sediment porewaters, is a key pathway for carbonate deposition and plays a crucial role in global biogeochemical cycles. Heterotrophic microorganisms are essential in regulating authigenic carbonate formation, primarily through the consumption of organic matter. Although bacterial manganese reduction is known to influence the formation of rhodochrosite and dolomite, its role in limestone deposition is unclear. Here, we present a systematic investigation of mixed calcareous siliciclastic rocks from a Paleogene freshwater lake to identify the formation of authigenic carbonate, decode the role of microbial Mn reduction, and understand the microbial response to ancient lacustrine environmental changes. The positive correlation between carbonate fraction in bulk samples (Carb%) and Mn content in carbonate minerals (Mn_carb) suggests that carbonate precipitation is stimulated by Mn²⁺ enrichment. The dissimilarity between Mn_carb and Fe_carb, along with the synergic variations of Mn_carb and diagenetic indicators, support an authigenic rather than a hydrogenetic origin for the carbonates. Using a one-dimensional diffusion–advection-reaction model, we quantify the impact of Mn reduction on promoting carbonate precipitation. Furthermore, correlations between P_carb and other values–positive with the chemical index alteration (CIA), negative with Mn_carb, and none with TOC–suggest that nitrogen availability, regulated by continental weathering, is likely the primary factor limiting both the primary productivity and the bacterial reduction intensity at the study site. Overall, this study uncovers the role of microbial Mn reduction in stimulating authigenic carbonate precipitation, and reveals the modulation mechanism of Mn-reducing microorganisms in an ancient lake. These findings shed new light on the authigenic limestone formation mechanisms and provide a new perspective on interpreting the authigenic impacts on carbonate chemistry.

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认识湖沼碳酸盐中的微生物锰还原及其与陆地生物地球化学过程的联系

碳酸盐自生是指碳酸盐矿物在沉积物孔隙水中的原位沉淀，是碳酸盐沉积的一个关键途径，在全球生物地球化学循环中起着至关重要的作用。异养微生物主要通过消耗有机物来调节自生碳酸盐的形成。虽然已知细菌的锰还原作用会影响菱锰矿和白云石的形成，但其在石灰岩沉积中的作用尚不清楚。在此，我们对一个古新世淡水湖的混合钙质硅质岩进行了系统研究，以确定自生碳酸盐的形成，解读微生物锰还原的作用，并了解微生物对古代湖泊环境变化的反应。大块样品中的碳酸盐部分（Carb%）与碳酸盐矿物中的锰含量（Mncarb）呈正相关，这表明碳酸盐沉淀是由富集的 Mn2+ 刺激的。Mncarb 和 Fecarb 之间的差异，以及 Mncarb 和成岩指标的协同变化，支持碳酸盐的自生起源，而不是水成起源。利用一维扩散-对流-反应模型，我们量化了锰还原对促进碳酸盐沉淀的影响。此外，Pcarb 与其他值之间的相关性--与化学指数变化（CIA）呈正相关，与 Mncarb 呈负相关，而与总有机碳（TOC）无相关性--表明受大陆风化作用调节的氮供应可能是限制研究地点初级生产力和细菌还原强度的主要因素。总之，本研究揭示了微生物还原锰在刺激自生碳酸盐沉淀中的作用，并揭示了古湖泊中还原锰微生物的调节机制。这些发现为自生性石灰岩的形成机制提供了新的启示，并为解释自生性对碳酸盐化学的影响提供了新的视角。

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来源期刊

Gondwana Research 地学-地球科学综合

CiteScore

12.90

自引率

6.60%

发文量

298

审稿时长

65 days

期刊介绍： Gondwana Research (GR) is an International Journal aimed to promote high quality research publications on all topics related to solid Earth, particularly with reference to the origin and evolution of continents, continental assemblies and their resources. GR is an "all earth science" journal with no restrictions on geological time, terrane or theme and covers a wide spectrum of topics in geosciences such as geology, geomorphology, palaeontology, structure, petrology, geochemistry, stable isotopes, geochronology, economic geology, exploration geology, engineering geology, geophysics, and environmental geology among other themes, and provides an appropriate forum to integrate studies from different disciplines and different terrains. In addition to regular articles and thematic issues, the journal invites high profile state-of-the-art reviews on thrust area topics for its column, ''GR FOCUS''. Focus articles include short biographies and photographs of the authors. Short articles (within ten printed pages) for rapid publication reporting important discoveries or innovative models of global interest will be considered under the category ''GR LETTERS''.