Leonard D. Harris 1973 <p>Existing models for dolomitization emphasize that penecontemporaneous&nbsp;dolomitization can occur in both subtidal and&nbsp;supratidal environments if the necessary chemical and physical factors&nbsp;favorable for the development of magnesium-rich hypersaline waters&nbsp;exist. Holocene shallow-water hypersaline environments that have the&nbsp;potential to produce dolomite without deposition of more soluble&nbsp;evaporite minerals are found in Shark Bay, Australia, and on the Great&nbsp;Bahama Bank. These hypersalinity systems are characterized by&nbsp;near-vertical isosalinity layers of increasing concentration landward&nbsp;from the open ocean and show little or no relationship to bottom&nbsp;topography. I suggest that a similar but larger scale epicontinentalsalinity system covering the Late Cambrian and Early Ordovician&nbsp;carbonate continental shelf produced a broad wedge of subtidally&nbsp;deposited dolomite in the eastern half of the United States from&nbsp;Mexico to Canada. The distribution of limestone and dolomite in this&nbsp;region is closely keyed to the salinity gradient and accounts for the&nbsp;natural progression from a normal marine limestone facies through a&nbsp;transition zone to a highly saline dolomite facies phase. Algal&nbsp;stromatolite mats and domes occupied low-energy niches in both the&nbsp;limestone and dolomite facies, whereas stratiform algal stromatolites&nbsp;were confined to the areas of moderate energy within the dolomite&nbsp;facies.</p> application/pdf en U.S. Geological Survey Dolomitization model for Upper Cambrian and Lower Ordovician carbonate rocks in the eastern United States article