Modern stromatolites in a saline maar in the Western District of Victoria, Australia: a possible analogue for Precambrian marine carbonates

Stromatolites and thrombolites are microbially-mediated, sedimentary structures of various size and morphology, found throughout the rock record. Although they do not always contain fossils of microbial cells, ancient stromatolitic structures are considered biogenic in origin and, therefore, evidence of early life. Modern, living stromatolites are found in lacustrine and marine environments and can provide a window in which to observe some of Earth's earliest biological processes. However, secular variation in marine chemistry over geological time means that modern marine settings are not always the best analogues for ancient carbonates. This study describes the occurrence of modern stromatolites in a saline, alkaline maar in Victoria, Australia. Dolomite is a principle carbonate mineral precipitating from this lake, an unusual and poorly understood occurrence in modern environments, but one that was common in the Precambrian. The peculiar lacustrine chemistry in this volcanic region may, therefore, provide a better analogue for Precambrian marine carbonates than modern marine environments. Several types of stromatolites/thrombolites are observed occurring around this maar. Living thrombolites grow just below the shoreline to ~60 cm below the surface of the water. They are nucleating on the cemented surfaces of older lake carbonates, as well as cattle skulls and fence wires that have become submerged. Distinct microbial mats are observed, the uppermost being cyanobacteria, followed by purple sulfur bacteria, and underlain by sulfate reducing bacteria. Older exposed stromatolites are more consolidated and have a more clearly defined laminated and columnar morphology. The thickness ranges from a few to 15 cm and each column is up to a centimeter in diameter. Together these give the surface of the rock a "bubbly" appearance. Along the shore, a sandy-gravel composed of stromatolite remnants has formed, indicating that wind-generated surface waves of substantial strength to break apart stomatolites can form in the lake. The next bench contains mudstone layers with clasts of basalt and olivine from the surrounding volcanic tuff, but lacks stromatolitic features. Visible ostrocod shells are abundant in these layers, perhaps suggesting that microorganisms could not compete with grazers at this time to form mats of sufficient size to form stromatolites. Finally, a bench lying about 1.8 m above the current water level is a carbonate rock containing small cavities (mm to a few cm in size) in which cements have formed. Also present are ooids of ~1-2 cm diameter. The mineralogy of these cements, ooids, and stromatolites will be determined by XRD and SEM. These data will be combined with an assessment of microbial 16S rRNA gene phylogeny in order to interpret the stromatolite morphogenesis of this unique lake. By studying stromatolite morphogenesis and microbial ecology in a modern dolomite-precipitating saline maar, we hope to gain a better understanding of the factors that controlled ancient stromatolite morphogenesis; and to examine the extent to which microorganisms versus the environment drive these processes.