<p>Primary phases in carbonate rocks archive a wealth of geochemical information about depositional conditions and environmental changes. Secondary phases may record additional&#8212;albeit more cryptic&#8212;information, potentially complicating interpretation of primary signatures. The ability to compositionally characterize and date multiple, texturally distinct generations of primary, diagenetic, and metamorphic carbonate phases enables deciphering of complex depositional and post-depositional histories carbonate successions have experienced. Combined trace-element mapping and U-Pb geochronology of calcite <em>in situ</em> (in thin sections) by LA-ICP-MS provides opportunities to assign absolute ages to calcite crystallization and recrystallization with petrographic and geochemical context. We have applied this approach to two samples of apparently pristine, unmetamorphosed Ordovician bioclastic limestones from the Viki drill core (western Estonia), representing the eastern part of the Baltoscandian Basin. The depositional ages of the samples are constrained by biostratigraphic correlation to ca. 460 and 445 Ma (Hints et al., 2014). Several lines of evidence&#8212;such as very low organic-matter maturation and properties of clay minerals&#8212;indicate that this sequence did not experience temperatures above 100 &#176;C, and likely not above 50 &#176;C, since deposition (Kirsim&#228;e et al., 2020). Optical petrography and backscatter-electron (&#8220;BSE&#8221;) imaging reveal low-porosity &#8220;BSE-bright&#8221; calcite spar cement in pore spaces between &#8220;BSE-dark&#8221; micro-porous calcite bioclasts. Trace-element mapping of several areas (several mm<sup>2</sup> each) in each thin section by LA-quadrupole-ICP-MS reveals variably elevated Mn/Sr, U concentration, and U/Pb in the calcite spar cement. The trace-element maps were subsequently used to guide the placement of laser spots for U-Pb dating by LA-multicollector-ICP-MS. Primary bioclastic calcite in both samples has low U/Pb (<sup>238</sup>U/<sup>206</sup>Pb < 7) and, thus, does not yield precise Concordia-intercept dates. The primary calcite does, however, yield imprecise intercept dates within uncertainty of the depositional ages. Calcite spar cement has higher U/Pb (<sup>238</sup>U/<sup>206</sup>Pb up to ~15.7) and including all analyses, yields intercept dates of ca. 415 Ma in each sample. Additionally, several of the domains with the highest U/Pb from each sample yield slightly younger dates of ca. 400&#173;-380 Ma. The timing of calcite (re)crystallization and cementation identified here overlaps with the timing of continent collision during the Caledonian orogeny in Scandinavia. We tentatively interpret this to be a result of fluid flow in response to the collision far-inboard (>500 km) from the orogenic front. Furthermore, this work demonstrates that apparently pristine carbonates may have experienced recrystallization (or at least chemical-isotopic perturbation) in open systems long after deposition.</p><p>References</p><p>Hints, O., Martma, T., M&#228;nnik, P., N&#245;lvak, J., P&#245;ldvere, A., Shen, Y., Viira, V. 2014. New data on Ordovician stable isotope record and conodont biostratigraphy from the Viki reference drill core, Saaremaa Island, western Estonia. GFF 136, 100&#8211;104.</p><p>Kirsim&#228;e, K., Somelar, P., J&#245;eleht, A. 2020. Illitization of the lower Cambrian (Terreneuvian) Blue Clay in the northern Baltic Palaeobasin. Estonian Journal of Earth Sciences 69, 200&#8211;213.</p>
Magmatic evolution in Devonian granitic rocks and relation to granophile mineralization in New Brunswick: application of biotite trace element mapping with EPMA and LA-ICP-MS
