During the 18th and 19th centuries, the conquest of deep time emerged as a pivotal achievement when geologists recognized that the age of rocks far exceeded earlier age estimates and exhibited a systematic order of deposition. Geological processes were reframed within an immense temporal framework, prompting efforts to identify and correlate strata worldwide using field-observable discontinuities and lithological traits. As Earth's antiquity became accepted, it also became clear that rock layers preserved records of countless biological and geological events. Biological markers-fossils-offered the most reliable data, but stratigraphers debated whether abrupt changes (catastrophism) or gradual processes (uniformitarianism) should define time slices. They refined biozonation by evaluating species' first and last appearances, ranges, abundance, and geographic distributions. Despite sophisticated biostratigraphic schemes, such subdivisions lacked numerical precision. Only with the discovery of radioactivity and development of radioisotopic dating could geologists assign numerical ages to strata, transforming the geological time scale from a relative framework into one anchored by numerical dates. This breakthrough established a rigid time grid, populated by formally defined periods, epochs, and ages, and with dates geologists could establish the rates of biological and geological processes. Later techniques introduced chemical signatures, magnetic reversal records, and orbital cyclicity as new correlation tools. Today, stratigraphers integrate these diverse markers while continually subdividing intervals to enhance the precision, exactness, and reliability of the Phanerozoic timescale. This multifaceted approach promises even more accurate correlations. By dividing time into thinner intervals and uniting various stratigraphical disciplines, geologists are moving towards a global and finely resolved chronostratigraphic framework. Our aim is to synthesize the principal developments that have shaped the conceptualization of geological time, with the purpose of establishing a rigorous foundation for future advances in the subdivision and quantification of temporal intervals.
Cutting Time in slices / Ferretti, A.; Balini, M.; Harper, D. A. T.; Servais, T.. - In: PALAEOGEOGRAPHY PALAEOCLIMATOLOGY PALAEOECOLOGY. - ISSN 0031-0182. - 683:(2026), pp. 1-15. [10.1016/j.palaeo.2025.113433]
Cutting Time in slices
Ferretti A.
Conceptualization
;
2026
Abstract
During the 18th and 19th centuries, the conquest of deep time emerged as a pivotal achievement when geologists recognized that the age of rocks far exceeded earlier age estimates and exhibited a systematic order of deposition. Geological processes were reframed within an immense temporal framework, prompting efforts to identify and correlate strata worldwide using field-observable discontinuities and lithological traits. As Earth's antiquity became accepted, it also became clear that rock layers preserved records of countless biological and geological events. Biological markers-fossils-offered the most reliable data, but stratigraphers debated whether abrupt changes (catastrophism) or gradual processes (uniformitarianism) should define time slices. They refined biozonation by evaluating species' first and last appearances, ranges, abundance, and geographic distributions. Despite sophisticated biostratigraphic schemes, such subdivisions lacked numerical precision. Only with the discovery of radioactivity and development of radioisotopic dating could geologists assign numerical ages to strata, transforming the geological time scale from a relative framework into one anchored by numerical dates. This breakthrough established a rigid time grid, populated by formally defined periods, epochs, and ages, and with dates geologists could establish the rates of biological and geological processes. Later techniques introduced chemical signatures, magnetic reversal records, and orbital cyclicity as new correlation tools. Today, stratigraphers integrate these diverse markers while continually subdividing intervals to enhance the precision, exactness, and reliability of the Phanerozoic timescale. This multifaceted approach promises even more accurate correlations. By dividing time into thinner intervals and uniting various stratigraphical disciplines, geologists are moving towards a global and finely resolved chronostratigraphic framework. Our aim is to synthesize the principal developments that have shaped the conceptualization of geological time, with the purpose of establishing a rigorous foundation for future advances in the subdivision and quantification of temporal intervals.
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