Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- Acknowledgments
- List of abbreviations and acronyms
- Part I INTRODUCTION
- Part II CONCEPTS AND METHODS
- 3 Biostratigraphy: time scales from graphic and quantitative methods
- 4 Earth's orbital parameters and cycle stratigraphy
- 5 The geomagnetic polarity time scale
- 6 Radiogenic isotope geochronology
- 7 Strontium isotope stratigraphy
- 8 Geomathematics
- PART III GEOLOGIC PERIODS
- Part IV SUMMARY
- Appendix 1 Recommended color coding of stages
- Appendix 2 Orbital tuning calibrations and conversions for the Neogene Period
- Appendix 3 Geomathematics
- Bibliography
- Stratigraphic Index
- General Index
4 - Earth's orbital parameters and cycle stratigraphy
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- List of contributors
- Preface
- Acknowledgments
- List of abbreviations and acronyms
- Part I INTRODUCTION
- Part II CONCEPTS AND METHODS
- 3 Biostratigraphy: time scales from graphic and quantitative methods
- 4 Earth's orbital parameters and cycle stratigraphy
- 5 The geomagnetic polarity time scale
- 6 Radiogenic isotope geochronology
- 7 Strontium isotope stratigraphy
- 8 Geomathematics
- PART III GEOLOGIC PERIODS
- Part IV SUMMARY
- Appendix 1 Recommended color coding of stages
- Appendix 2 Orbital tuning calibrations and conversions for the Neogene Period
- Appendix 3 Geomathematics
- Bibliography
- Stratigraphic Index
- General Index
Summary
The Milankovitch theory that quasi-periodic oscillations in the Sun-Earth position have induced significant 104–106-year-scale variations in the Earth's stratigraphic record of climate is widely acknowledged. This chapter discusses the Earth's orbital parameters, the nature of orbitally forced incoming solar radiation, fossil orbital signals in Phanerozoic stratigraphy, and the use of these orbital signals in calibrating geologic time.
INTRODUCTION
Over the past century, paleoclimatological research has led to wide acceptance that quasi-periodic oscillations in the Sun—Earth position have induced significant variations in the Earth's past climate. These orbitally forced variations influenced climate-sensitive sedimentation, and thereby came to be fossilized in the Earth's cyclic stratigraphic record. The detection of orbital variations in Earth's cycle stratigraphy was progressively facilitated by advancements in celestial mechanics, which have provided more accurate models of the Earth's orbital—rotational behavior through geological time, and by improvements in data collection and analysis.
A principal outcome of the research has been the recognition that cycle stratigraphy, when shown to carry the signal specific to Earth's orbital behavior, serves as a powerful geochronometer. High-quality data collected over the past decade, in particular, have proven to have faithfully recorded all of the orbital cycles predicted by modern celestial mechanics over 0–23 Ma.
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- A Geologic Time Scale 2004 , pp. 55 - 62Publisher: Cambridge University PressPrint publication year: 2005
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