Abstract
Numerous Phanerozoic limestones are comprised of diagenetic calcite microcrystals formed during mineralogical stabilization of metastable carbonate sediments. Previous laboratory experiments show that calcite microcrystals crystallizing under conditions similar to those that characterize meteoric diagenetic settings (impurity-free, low degree of supersaturation, high fluid:solid ratio) exhibit the rhombic form/morphology, whereas calcite microcrystals crystallizing under conditions similar to those that prevail in marine and marine burial diagenetic settings (impurity-rich, high degree of supersaturation, low fluid:solid ratio) exhibit non-rhombic forms. Based on these experimental observations, it is proposed here that rhombic calcite microcrystals form exclusively in meteoric environments. This hypothesis is tested using new and previously published textural and geochemical data from the rock record. These data show that the vast majority of Phanerozoic limestones characterized by rhombic microcrystals also exhibit petrographic and/or geochemical evidence (depleted δ13C, δ18O, and trace elements) indicative of meteoric diagenesis whereas non-rhombic forms are associated with marine burial conditions. By linking calcite microcrystal textures to specific diagenetic environments, our observations bring clarity to the conditions under which the various microcrystal textures form. Furthermore, the hypothesis that rhombic calcite microcrystals form exclusively in meteoric environments implies that this crystal form may be a useful textural proxy for meteoric diagenesis.
Highlights
Study This study Steinen 198221 Moshier 198932 da Silva et al 200927 Perkins 198935 Loucks et al 201333 Loucks et al 201744 Budd 198934 Moshier 198938 Holail and Lohmann 199445
Given that crystal form is dictated by the internal crystal structure and the external growth conditions[13], these experimental observations imply that the rhombic form is the structural form of calcite, and is dictated by its rhombohedral crystal system, whereas non-rhombic forms are growth forms, and are the result of various growth conditions
The absence of the growth conditions that interfere with the growing calcite microcrystals in meteoric settings allows them to achieve their preferred structural rhombic form, and the prevalence of those growth conditions in marine and marine burial settings leads to the various non-rhombic growth forms
Summary
Study (reference) This study Steinen 198221 Moshier 198932 da Silva et al 200927 Perkins 198935 Loucks et al 201333 Loucks et al 201744 Budd 198934 Moshier 198938 Holail and Lohmann 199445. Location Indonesia; Texas, USA; UAE Bahamas Indonesia Spain Texas, USA Texas, USA Louisiana, USA UAE UAE Egypt. Meteoric based on the observation that the sediments are residing in meteoric water Meteoric based on depleted δ13C and δ18O. Meteoric based on depleted δ13C and δ18O, and petrographic observations (clay-filled karstic features, dissolution molds, sparry cement), and proximity to an exposure surface
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