A case for biotic morphogenesis of coniform stromatolites

Batchelor, Murray T.; Burne, Robert V.; Henry, Bryan R.; Jackson, Matthew

doi:10.1016/j.physa.2004.01.065

Cited by 55 publications

(55 citation statements)

References 23 publications

(43 reference statements)

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“…A central point in our analysis consists of ascertaining whether the band interfaces observed in the previous figure can be somehow associated with the sequential profiles of a function h(x,t) which solves equation (1.1) for a suitable choice of the parameters n, l and D therein. This is the basic assumption made [32,33]. For instance, in an earlier study [32] authors assert that, under suitable assumptions on the equation parameters 'numerical solutions of equation (1.1) (our notation) yield interfaces that evolve to a statistical steady state with fractal dimension D f (our notation) ffi 2.6 independent of the initial conditions.…”

Section: A Test For Mathematical Modelling: Stromatolite Band Interfacesmentioning

confidence: 92%

“…Figure 8 provides information on the behaviour in time of the corresponding solutions. It is interesting to compare figure 8 with figure 1 in the study of Batchelor et al [33]. In both cases, one makes use of explicit formulae to represent the solutions.…”

Section: Interface Patterns In Different Transient Regionsmentioning

confidence: 97%

“…In both cases, one makes use of explicit formulae to represent the solutions. However, the authors in [33] are able to derive their plots through formulae (2.1) and (2.2) therein because they consider initial values with a single maximum. In our case, the initial value has several maxima, so that characteristics originating from them may intersect in time, which eventually results in loss of regularity and cusp formation.…”

Section: Interface Patterns In Different Transient Regionsmentioning

confidence: 99%

“…Moreover, analyses and simulation of the corresponding models should shed light into the manner in which stromatolites are formed. To the best of our knowledge, mathematical models of stromatolite formation have been proposed and discussed only recently [32][33][34]. The choice of equations selected to model their formation basically reduces to the so-called Kardar-Parisi-Zhang (KPZ) stochastic equation [35] …”

Section: Introductionmentioning

confidence: 99%

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Pattern formation in stromatolites: insights from mathematical modelling

Cuerno

Escudero

García‐Ruiz

et al. 2011

J. R. Soc. Interface.

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To this day, computer models for stromatolite formation have made substantial use of the Kardar-Parisi -Zhang (KPZ) equation. Oddly enough, these studies yielded mutually exclusive conclusions about the biotic or abiotic origin of such structures. We show in this paper that, at our current state of knowledge, a purely biotic origin for stromatolites can neither be proved nor disproved by means of a KPZ-based model. What can be shown, however, is that whatever their (biotic or abiotic) origin might be, some morphologies found in actual stromatolite structures (e.g. overhangs) cannot be formed as a consequence of a process modelled exclusively in terms of the KPZ equation and acting over sufficiently large times. This suggests the need to search for alternative mathematical approaches to model these structures, some of which are discussed in this paper.

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Section: A Test For Mathematical Modelling: Stromatolite Band Interfacesmentioning

confidence: 92%

Section: Interface Patterns In Different Transient Regionsmentioning

confidence: 97%

Section: Interface Patterns In Different Transient Regionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Pattern formation in stromatolites: insights from mathematical modelling

Cuerno

Escudero

García‐Ruiz

et al. 2011

J. R. Soc. Interface.

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“…Giordano et al (2005) and Raven & Larkum (2007) show that cyanobacteria in stromatolites could have low intracellular CO 2 concentrations and high O 2 concentrations, despite high external CO 2 and negligible O 2 (see Anbar et al 2007;Kaufman et al 2007) in the medium some 2.3-2.5 Gyr ago. The reasoning here is that the cyanobacteria in a stromatolite are separated from the medium by a millimetre or centimetre of unstirred interstitial water in a mineral and organic polymer, which adds tortuosity to the aqueous diffusion path (although the possibility of photomotion by the cyanobacteria, altering their distribution on the illuminated relative to the shaded side, must be acknowledged; Batchellor et al 2004). Here we explore the implications of UV screening as a factor favouring the occurrence of cyanobacteria in stromatolites and other dense benthic populations.…”

Section: Evolutionary Origin Of Ccms: When?mentioning

confidence: 99%

The evolution of inorganic carbon concentrating mechanisms in photosynthesis

Raven

Cockell

Rocha

2008

Phil. Trans. R. Soc. B

283

206

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Inorganic carbon concentrating mechanisms (CCMs) catalyse the accumulation of CO 2 around rubisco in all cyanobacteria, most algae and aquatic plants and in C 4 and crassulacean acid metabolism (CAM) vascular plants. CCMs are polyphyletic (more than one evolutionary origin) and involve active transport of HCO K 3 , CO 2 and/or H C , or an energized biochemical mechanism as in C 4 and CAM plants. While the CCM in almost all C 4 plants and many CAM plants is constitutive, many CCMs show acclimatory responses to variations in the supply of not only CO 2 but also photosynthetically active radiation, nitrogen, phosphorus and iron. The evolution of CCMs is generally considered in the context of decreased CO 2 availability, with only a secondary role for increasing O 2 . However, the earliest CCMs may have evolved in oxygenic cyanobacteria before the atmosphere became oxygenated in stromatolites with diffusion barriers around the cells related to UV screening. This would decrease CO 2 availability to cells and increase the O 2 concentration within them, inhibiting rubisco and generating reactive oxygen species, including O 3 .

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Sedimentology and Geochemistry of the 2930 Ma Red Lake–Wallace Lake Carbonate Platform, Western Superior Province, Canada

McIntyre

Fralick

2017

The Depositional Record

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Chemical sedimentary rocks in the Red Lake-Wallace Lake area of the Canadian Shield form the Earth's oldest known carbonate platform and, as such, provide a unique opportunity to explore the floor of a 2930 Myr old warm, shallow sea. Peritidal depositional features dominate the platform top, ranging from colloform crusts, teepee structures, and evaporate pseudomorphs in the supratidal; pseudomorph crystal fans and laterally linked domal stromatolites, associated with stromatactis-like structures, sheet cracks and liminoid fenestral fabrics extending from the lower supratidal through the intertidal; and herringbone cross-stratification, isolated domal stromatolites and herring-bone calcite cement in tidal channels. These lithofacies indicate a low energy, restricted evaporitic environment. Limited subtidal platform top deposits are characterized by laterally linked domal stromatolites and pseudomorph crystal fans on a larger scale than those found in the intertidal areas. A transitional lithofacies to deeper water were deposited further offshore. It consists of ribbon rock (mixed laminae and beds of carbonate, slate and iron oxide sediments), slump structures composed of intraclastic carbonate lithoclasts in a marl matrix and carbonate-associated iron formation. Basinal deposits consist of chert and chert-oxide facies iron formation. Peritidal lithofacies are composed of ferroan dolomite, whereas deep subtidal to upper slope lithofacies are composed of calcite. The dolomites have O and Sr isotopic ratios which were probably reset during dolomitization, whereas only O is altered in the limestones. The d 13 C values for all the carbonate samples were 0 AE 1Á1& V-PDB , with samples formed in deeper water having lighter d 13 C values, suggesting the deeper open ocean had a lighter d 13 C budget than water in the platform interior. Post Archean Australian Shale normalized rare earth element patterns for the carbonate samples have positive La and Eu anomalies, suprachondritic Y/Ho ratios and slight heavy rare earth element enrichment in most samples. Basin lithofacies are characterized by heavy rare earth element enrichment and positive Eu anomalies. One sample had a significant negative Ce anomaly. These data probably indicate restricted circulation in the supra and intertidal areas and possibly the development of spatially limited areas where oxygen production could move the redox boundary out into the water column.

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A case for biotic morphogenesis of coniform stromatolites

Cited by 55 publications

References 23 publications

Pattern formation in stromatolites: insights from mathematical modelling

Pattern formation in stromatolites: insights from mathematical modelling

The evolution of inorganic carbon concentrating mechanisms in photosynthesis

Sedimentology and Geochemistry of the 2930 Ma Red Lake–Wallace Lake Carbonate Platform, Western Superior Province, Canada

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