Botryoidal and Spherulitic Aragonite in Carbonates Associated with Microbial Mats: Precipitation or Diagenetic Replacement Product?

Ge, Yuzhu; Porta, Giovanna Della; Pederson, Chelsea L.; Lokier, Stephen W.; Hoffmann, René; Immenhauser, Adrian

doi:10.3389/feart.2021.698952

Cited by 12 publications

(9 citation statements)

References 105 publications

(236 reference statements)

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“…The mineralogical composition of the sublittoral bioherms, the focus of this study, does not differ from the bioherms found adjacent to the present‐day shoreline, implying that mineralogy cannot be used to differentiate environments. The predominance of aragonite precipitates associated with calcite and dolomite in GSL microbial bioherms and ooids as reported in this and previous studies (Della Porta, 2015; Dunham et al, 2020; Eardley, 1938; Ge et al, 2021; Pace et al, 2016; Pedone & Folk, 1996; Sandberg, 1975) is explained by the high carbonate supersaturation and Mg/Ca ratio of lake water, which is between 9.6 and 115.7 (cf. Müller et al, 1972).…”

Section: Discussionsupporting

confidence: 85%

“…The clotted peloidal and laminated micrite-grade fabric observed petrographically resemble the textures interpreted as microbial boundstone in several studies about recent and fossil microbialites. Nanometrescale sub-spherical carbonate structures eventually coalesce to form larger crystals with rational/euhedral crystal faces as similarly described in studies about microbially mediated carbonate precipitation (Bontognali et al, 2010;Ge et al, 2021;Jones, 2017;Jones & Peng, 2014;Pedley, 2014;Pedley et al, 2009;Perri et al, 2012Perri et al, , 2018. Meldrum and Cölfen (2008) have shown that several biominerals of skeletal organisms can form from amorphous precursors represented by nanoparticles, which are favoured by supersaturation.…”

Section: Microbial Bioherm Fabrics and Precipitation Processesmentioning

confidence: 77%

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Characteristics and controls on the distribution of sublittoral microbial bioherms in Great Salt Lake, Utah: Implications for understanding microbialite development

Baskin¹,

Porta

Wright

2021

The Depositional Record

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Side‐scan sonar and Compressed High Intensity Radar Pulse mapping of Great Salt Lake, Utah, linked to reprocessing of acoustic data from bathymetric surveys, has enabled the distribution of microbial bioherms to be assessed. Bioherms occupy an estimated area >700 km2 in the south arm and >300 km2 in the north arm. Distributions vary from statistically dispersed to clustered, and in this latter case, are predominantly located on metre‐scale, fault‐controlled topographic highs, with sediment infilling intervening lows between adjacent offsets. Individual bioherms are circular to oblate and range from centimetres to over 2 m in diameter. In some areas, bioherm heights were measured at more than 1.5 m above adjacent substrate. Sublittoral bioherms are made of aragonite, calcite and minor dolomite precipitated due to physico‐chemical, biologically induced and influenced carbonate mineralization processes in association with microbial mats. Bioherm fabrics vary at the millimetre to centimetre‐scale and consist of leiolitic and clotted peloidal micrite‐grade carbonate, sinuous threads of spherulitic fibrous aragonite crystals, laminated micrite boundstone and internal carbonate mud sediment with peloids and ooids. The identification of factors that influence microbial bioherm occurrence and spatial distribution in Great Salt Lake is limited to a set of collinear physical, chemical and biological variables that are confined to a localised closed system, such as salinity, water depth, wave energy, stable substrate and sediment accumulation. Anthropogenic modifications to Great Salt Lake resulting in increased salinity have exceeded the salinity range in which bioherm‐mediating microbial communities can survive, effectively defining an upper limit of salinity for bioherm microbial community viability. The better understanding of the distribution of microbial bioherms has significant implications for managing and protecting the lake ecosystem and may provide insights into the physical and chemical controls that existed during the formation of fossil microbialites in deep time.

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Section: Discussionsupporting

confidence: 85%

Section: Microbial Bioherm Fabrics and Precipitation Processesmentioning

confidence: 77%

Characteristics and controls on the distribution of sublittoral microbial bioherms in Great Salt Lake, Utah: Implications for understanding microbialite development

Baskin¹,

Porta

Wright

2021

The Depositional Record

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“…The South Arm sediments (carbonate mud) are composed of dolomite, quartz and calcite with a minor amount of aragonite, albite, illite and poorly crystalline Mg‐bearing clay (Table 2). Stromatolite samples collected from the North Arm and South Arm also consist of predominately aragonite with a trace amount of calcite, which agrees with previous observations (Dunham et al ., 2020; Ge et al ., 2021). Carbonate mud samples collected from ridges between ponds in the North Arm have a similar mineral assemblage as carbonate mud from the South Arm with dolomite, quartz and calcite constituting major components and minor amounts of albite, illite and poorly crystalline Mg‐bearing clay.…”

Section: Resultsmentioning

confidence: 99%

Dissolved silica‐driven dolomite precipitation in the Great Salt Lake, Utah, and its implication for dolomite formation environments

et al. 2023

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Since the discovery of dolomite, numerous attempts have been made to understand its precipitation mechanism at Earth's surface conditions. One such mechanism relies on a relationship with microbial life, where laboratory synthesis experiments have shown that specific organic molecules, such as polysaccharides, exopolymeric substances and hydrogen sulphide can promote dolomite precipitation. Other mechanisms for precipitating dolomite focus on abiotic chemical environments, such as adding dissolved silica, which lower the dehydration energy barrier for the surface Mg2+‐water complex and promote disordered dolomite precipitation. Modern occurrences of dolomite in the Great Salt Lake, Utah, have been studied since the early 20th Century. The distribution of primary dolomite in the Great Salt Lake is spatially heterogeneous, with only the carbonate mud in the South Arm and ridge‐site between desiccation cracks in the North Arm being dominated by dolomite and calcite, while stromatolites in both Arms and ooidal sands in the North Arm are composed entirely of aragonite. It was proposed that dolomite precipitation in the Great Salt Lake was possibly induced by microbial activities such as organic degradation, bacteria sulphate reduction, or other microbial metabolic by‐products. However, these hypotheses could not explain the lack of dolomite in microbial mats, especially in the North Arm, which is constituted by mostly aragonite with no dolomite. Our results suggest that dissolved silica concentration is the primary control for dolomite and Mg‐clay formation in the Great Salt Lake. Even though the North Arm has a much more concentrated Mg and Ca water from lack of freshwater input, dissolved silica levels in the South Arm (>0.5 mm) and the Ridge‐site (ca 0.5 mm) are much higher than in the North Arm (<0.2 mm). Our finding could also provide a new proxy for reconstructing climate changes in the Great Salt Lake area based on dolomite content variation. Phanerozoic dolomite abundance variations may be linked to global CO2 level that facilitates global chemical weathering and dissolved silica input into palaeo‐ocean.

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“…The precipitation of disordered dolomite could be triggered by the oversaturation of carbonate in this enclosed region. The spheroidal shape (commonly called spherulite) is very common for carbonate precipitates [38][39][40], which indicates fast precipitation from highly non-equilibrium conditions [41]. The eccentricity of the brown granular core is probably controlled by gravity (relative to the original orientation of the pearl during its formation).…”

Section: Discussionmentioning

confidence: 99%

Disordered dolomite as an unusual biomineralization product found in the center of a natural Cassis pearl

et al. 2023

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Natural pearls are produced without human intervention, mainly due to various irritations from the surrounding environment to their mantle tissues. Pearls usually possess similar mineral compositions to the host shells, which means they are also dominated by aragonite and calcite. In this study, we report a natural pearl from a Cassis species mollusk containing granular central structures. Raman spectroscopy, laser ablation inductively coupled plasma mass spectrometry (LA-ICPMS), energy dispersive X-ray spectroscopy (EDS) coupled with scanning electron microscope (SEM), and X-ray diffraction (XRD) analyses were carried out in order to characterize the mineral composition in the center region of this pearl. Our results showed that this pearl’s center was made of mostly disordered dolomite (Ca0.53Mg0.47CO3) mixing with small amount of aragonite and high magnesium-calcite. To the best of our knowledge, this is the first time disordered dolomite was conclusively identified inside of a natural pearl and such information expanded our knowledge on internal growth structures and formation of natural pearls.

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Botryoidal and Spherulitic Aragonite in Carbonates Associated with Microbial Mats: Precipitation or Diagenetic Replacement Product?

Cited by 12 publications

References 105 publications

Characteristics and controls on the distribution of sublittoral microbial bioherms in Great Salt Lake, Utah: Implications for understanding microbialite development

Characteristics and controls on the distribution of sublittoral microbial bioherms in Great Salt Lake, Utah: Implications for understanding microbialite development

Dissolved silica‐driven dolomite precipitation in the Great Salt Lake, Utah, and its implication for dolomite formation environments

Disordered dolomite as an unusual biomineralization product found in the center of a natural Cassis pearl

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