@article { author = {Ghobadi Pour, Mansoureh and Popov, Leonid and Cherns, Lesley}, title = {Climatic changes and astrochronology: an Ordovician perspective}, journal = {Climate Change Research}, volume = {1}, number = {4}, pages = {89-109}, year = {2020}, publisher = {Golestan University}, issn = {2717-2066}, eissn = {2717-2066}, doi = {10.30488/ccr.2020.255527.1030}, abstract = {Review of current progress in Mid to Late Ordovician astrochronological studies exposes some important issues related to cyclostratigraphical studies, including the completeness and correlation of successions, and the connection between inferred astronomical cycles and geological events recorded in the sedimentary record. While bulk, low-field, mass specific magnetic susceptibility methods are widely applied in studies of high resolution cyclostratigraphy, they require close support from sequence stratigraphy and biostratigraphy, and should be linked back to outcrop patterns. Otherwise they risk distortion in the calibration against geological time, through lack of anchoring to well-defined biostratigraphical horizons and unrecognised condensed intervals and larger hiatuses. A significant limitation currently is that few high-resolution radio-isotope ages are linked to well-defined biostratigraphical boundaries. Nevertheless, fourth order sedimentary sequences linked to 405 ky orbital eccentricity cycles, and longer orbital cyclicity impressed in third-order sequences, represent good grounds for development of a reliable astrochronological scale. The astrochronologically calibrated sequence-stratigraphical record documented from high latitude Gondwana shows significant impact from orbital forcing on the Mid to Late Ordovician global climate.}, keywords = {Ordovician,orbital forcing,astrochronology,Cyclostratigraphy,Biostratigraphy}, title_fa = {Climatic changes and astrochronology: an Ordovician perspectiv}, abstract_fa = {Review of current progress in Mid to Late Ordovician astrochronological studies exposes some important issues related to cyclostratigraphical studies, including the completeness and correlation of successions, and the connection between inferred astronomical cycles and geological events recorded in the sedimentary record. While bulk, low-field, mass specific magnetic susceptibility methods are widely applied in studies of high resolution cyclostratigraphy, they require close support from sequence stratigraphy and biostratigraphy, and should be linked back to outcrop patterns. Otherwise they risk distortion in the calibration against geological time, through lack of anchoring to well-defined biostratigraphical horizons and unrecognised condensed intervals and larger hiatuses. A significant limitation currently is that few high-resolution radio-isotope ages are linked to well-defined biostratigraphical boundaries. Nevertheless, fourth order sedimentary sequences linked to 405 ky orbital eccentricity cycles, and longer orbital cyclicity impressed in third-order sequences, represent good grounds for development of a reliable astrochronological scale. The astrochronologically calibrated sequence-stratigraphical record documented from high latitude Gondwana shows significant impact from orbital forcing on the Mid to Late Ordovician global climate.}, keywords_fa = {Ordovician,orbital forcing,astrochronology,Cyclostratigraphy,Biostratigraphy}, url = {https://ccr.gu.ac.ir/article_119416.html}, eprint = {https://ccr.gu.ac.ir/article_119416_bc9a0295fb85f864b1b43ec11172821b.pdf} }