github

https://aredakau.github.io/Isotope_Geology/slides/lecture_7.html

[2] Geochronological principles and methods - aredakau.github.io — Summary. Geochronology: The science of determining the age of rocks and minerals, crucial for understanding Earth's history and geological events. Fundamental Principles: Radiometric Dating: Based on radioactive decay of isotopes (e.g., Rb-Sr, U-Pb, K-Ar). Key Assumptions: Closed system behavior and known initial isotopic conditions. Geochronological Methods:

geologyscience

https://geologyscience.com/geology/how-do-geologists-determine-the-age-of-rocks/

[3] How do geologists determine the age of rocks? - Geology Science — Modified date: 26/11/2023 FacebookTwitterWhatsAppLinkedinEmail Telegram Geologists determine the age of rocks through a field of study known as geochronology, which involves various methods to quantify the timing of geological events and the rates of Earth processes. Understanding the age of rocks is crucial for reconstructing Earth’s history, deciphering past environmental conditions, and unraveling the evolution of life on our planet. There are two main types of geochronology methods: relative dating and absolute dating. On the other hand, absolute dating provides numerical ages for rocks and minerals by determining the radioactive decay of certain isotopes or measuring the accumulation of specific products resulting from radioactive decay.

britannica

https://www.britannica.com/science/geochronology

[4] Geochronology | Definition, History, Dating, Importance, & Facts ... — geochronology, field of scientific investigation concerned with determining the age and history of Earth's rocks and rock assemblages. Such time determinations are made and the record of past geologic events is deciphered by studying the distribution and succession of rock strata, as well as the character of the fossil organisms preserved within the strata.

springer

https://link.springer.com/content/pdf/10.1007/978-3-642-67161-6_1.pdf

[5] PDF — This shows the wide application and the importance of geochronology to geology. This is not only true for Precambrian terranes for which geochronology is the only key to their evolutionary history. Also in geologically well-studied young areas, such as the Japanese islands or the Alpine chain, geochronology has contributed much to the fun-

newworldencyclopedia

https://www.newworldencyclopedia.org/entry/Geochronology

[6] Geochronology - New World Encyclopedia — Geochronology and chronostratigraphy. The science of geochronology is the prime tool used in the discipline of chronostratigraphy, which attempts to arrange the sequence and time of deposition of all rocks in a geological region, and eventually, the entire geologic record of the Earth.

geoscienceworld

https://pubs.geoscienceworld.org/sepm/books/edited-volume/1041/chapter/10528799/A-Revised-Cenozoic-Geochronology-and

[8] A Revised Cenozoic Geochronology and Chronostratigraphy — A Revised Cenozoic Geochronology and Chronostratigraphy Author(s) William A. Berggren William A. Berggren ... (IMBTS) based on an assessment and integration of data from several sources. Biostratigraphic events are correlated to the recently revised global polarity time scale (CK95). The construction of the new GPTS is outlined with emphasis on

sciencedirect

https://www.sciencedirect.com/science/article/pii/B9780443188039000110

[9] A method and application for the integration of geology, geochronology ... — Geochronology has become a foundational approach in the study of Earth's history. Significant developments over the past 3 decades in both U-Pb and 40 Ar/ 39 Ar methods allow for unprecedented levels of precision and reinterpretation of geological, climatic, and biological events (Renne et al., 1994; Condon et al., 2005; Simon et al., 2008; Smith et al., 2010; Mundil et al., 2010).

discovermagazine

https://www.discovermagazine.com/planet-earth/chronostratigraphy-how-scientists-unlock-deep-time

[10] Chronostratigraphy: How Scientists Unlock Deep Time — Chronostratigraphy gives researchers a framework of how our planet, and life on it, has changed over time. ... The Phanerozoic, for example, is divided into three erathems, or eras: Paleozoic ("old life," from rapidly diversifying multicellular organisms to the first land vertebrates), Mesozoic ("middle life," including dinosaurs, early

geoscienceworld

https://pubs.geoscienceworld.org/msa/elements/article/19/5/302/630645/High-Precision-Geochronology-of-LIP-Intrusions

[14] High-Precision Geochronology of LIP Intrusions: Records of Magma ... — The history of global climate and ocean chemistry during mass extinction events is stored in the sedimentary record, which documents changes in paleo-biodiversity (colloqui-ally termed "mass extinctions"), shifts in carbon isotopes indicative of global climate change, and evidence for anoxic or stratified oceanic depositional environments (e.g., Lindström et al. 2021; Heimdal et al. 2021).

sciencedirect

https://www.sciencedirect.com/topics/earth-and-planetary-sciences/geochronology

[17] Geochronology - an overview | ScienceDirect Topics — Geochronology is the science of dating the age of rocks, minerals, fossils, and geologic events, using isotopic concentrations of parent and daughter nuclei in minerals. Geochronology is the science of age dating earth materials (rocks, minerals, fossils) and geologic events (Fig. 2). For recent events the main isotopic methods utilized are radiocarbon geochronology using the 14C radioisotope (for ages up to 50,000–60,000 y) and U-series dating (for ages up to 2 Ma). Although geochronological, petrological, and structural geological data were sporadically produced before the 1980s, it is mainly after the first ideas of an Alpine metamorphic history (Burchfiel, 1980), the first report of Eocene metamorphic K–Ar ages (Liati, 1986; Liati & Kreuzer, 1990) and the first identification of eclogite-facies metamorphism (Kolceva et al., 1986; Liati, 1986, 1988) that the Rhodope zone started attracting the interest of more and more geoscientists.

newworldencyclopedia

https://www.newworldencyclopedia.org/entry/Geochronology

[18] Geochronology - New World Encyclopedia — As noted above, various dating methods are used in geochronology. Each method has a certain degree of uncertainty, but the reliability of the results can be enhanced by using several techniques. ... An overview. The following table gives an overview of geologic time periods. The second timeline expands on the last subsection of the first

geoscience

https://geoscience.blog/unchanging-clockwork-unveiling-the-consistency-of-radiometric-datings-decay-rate/

[21] Unchanging Clockwork: Unveiling the Consistency of Radiometric Dating's ... — Understanding the constancy of decay rates is essential for accurate dating. If the rate of decay were not constant, it would undermine the reliability of radiometric dating methods and jeopardize our understanding of Earth's history. Therefore, scientists have conducted extensive research to investigate the constancy of decay rates and have

geoscience

https://geoscience.blog/the-role-of-assumptions-in-isotopic-radiometric-dating-an-earth-science-perspective/

[23] The Role of Assumptions in Isotopic Radiometric Dating: An Earth ... — Radiometric dating relies on a number of assumptions, some of which are more critical than others. One of the most important assumptions is that the rate of decay of the radioactive isotopes being measured has remained constant over time. This assumption is known as the constancy of decay rate, or the principle of uniformitarianism.

usgs

https://www.usgs.gov/centers/geosciences-and-environmental-change-science-center/science/science-topics/geochronology

[26] Geochronology | U.S. Geological Survey - USGS.gov — The objectives of this project are to reconstruct detailed histories of Holocene hydroclimate and corresponding environmental change from geological archives such as lake sediment, peat, and wood to more fully understand past, ongoing, and future change and its impacts.

geological-digressions

https://www.geological-digressions.com/a-timeline-of-stratigraphic-principles-15th-18th-c/

[48] A timeline of stratigraphic principles; 15th-18th C — But inquisitive people have been recording and unraveling stratigraphic problems for at least 500 years. The evolution of stratigraphic principle is a fascinating story in itself, told by folk who had to battle religious and political repression (sometimes at great personal cost), the prejudice of class, and the egos of fellow scientists.

researchgate

https://www.researchgate.net/publication/228605887_Principles_of_stratigraphy

[49] (PDF) Principles of stratigraphy - ResearchGate — Modern principles of stratigraphic analysis were worked out in the 18 th and 19 th centuries by geologists such as Niels Stensen, James Hutton, Georges Cu-vier, William Smith and Charles Lyell.

gelogia

https://gelogia.com/principles-of-stratigraphy/

[50] Principles of Stratigraphy - Gelogia — Stratigraphy is the branch of geology that sheds light on strata formation, composition, distribution, and succession. Stratigraphy is concerned with the description, organization, and classification of stratified rock. In addition, it is the study of temporal relationships in sedimentary rock bodies. Grabau (1913) defined stratigraphy as: "The inorganic side of historical geology, or the

nps

https://www.nps.gov/articles/geologic-principles-faunal-succession.htm

[51] Geologic Principles—Faunal Succession - U.S. National Park Service — Fossil Correlation After Smith's discovery, fossils became a new tool by which geologists could distinguish rock units of different ages from one another. Faunal succession became a unifying principle by which rock units are categorized and recognized widely. This important principle raised questions about ancient life that were not easily answered at Smith's time, but even without answers

fiveable

https://library.fiveable.me/key-terms/introduction-geology/principle-of-faunal-succession

[52] Principle of faunal succession - (Intro to Geology) - Fiveable — The principle of faunal succession is a fundamental concept in geology stating that different fossil species appear and disappear in a consistent, recognizable order through geological time. This principle allows geologists to use the presence of specific fossils to identify and correlate the age of rock layers, helping to piece together the history of life on Earth.

scolary

https://scolary.blog/faunal-succession-evolution-biostratigraphy/

[53] Faunal Succession: Fossil Evolution And Biostratigraphy — The principle of faunal succession describes the regular and predictable changes in the composition of fossil assemblages over time. These changes are driven by a complex interplay of factors, including environmental conditions, ecological interactions, and evolutionary processes. The principle of faunal succession forms the basis for biostratigraphy, the study of the distribution of fossils

sciencedirect

https://www.sciencedirect.com/science/article/pii/B9780443188039000110

[54] A method and application for the integration of geology, geochronology ... — The fossil record demonstrates that at least 92 taxa of gymnosperms flourished when the Lanqi Formation was deposited (Jiang et al., 2008). The fossils represent a significant record of floral evolution and diversification and a snapshot of a terrestrial ecosystem in the middle Mesozoic.

science

https://www.science.org/doi/10.1126/sciadv.1603076

[55] The timetable of evolution | Science Advances - AAAS — The integration of fossils, phylogeny, and geochronology has resulted in an increasingly well-resolved timetable of evolution. ... Like the evolutionary timeline itself, geologic inferences of evolutionary rate depend on a well-documented fossil record, high-resolution geochronology to establish a timeframe, and, increasingly, well-resolved

sciencedirect

https://www.sciencedirect.com/science/article/abs/pii/B9780443188039000110

[56] A method and application for the integration of geology, geochronology ... — The Mesozoic was a critical time in Earth's history that witnessed the breakup of Pangea, the biological recovery from the most severe mass extinction in Earth's history, a warm climate, and the radiation of dinosaurs and flowering plants in terrestrial environments. Establishing geochronologic dates for critical fossils helps to advance new ideas relating to biological evolution and the

mit

https://news.mit.edu/2006/earthtime

[57] Clock in the rock: MIT geologist leads effort to measure Earth's ... — The two methods produce slightly different results, but with correct correlation and using data from fossil record from all over the world, they are helping to generate a more accurate time scale. "We are working on the age of the K-T boundary right now using zircon and we think we can constrain it to within about 50,000 years," Bowring said.

wikipedia

https://en.wikipedia.org/wiki/Radiometric_dating

[58] Radiometric dating - Wikipedia — Jump to content Main menu Search Donate Create account Log in Personal tools Toggle the table of contents Radiometric dating 38 languages Article Talk Read Edit View history Tools From Wikipedia, the free encyclopedia Radiometric dating, radioactive dating or radioisotope dating is a technique which is used to date materials such as rocks or carbon, in which trace radioactive impurities were selectively incorporated when they were formed. The method compares the abundance of a naturally occurring radioactive isotope within the material to the abundance of its decay products, which form at a known constant rate of decay. Radiometric dating is now the principal source of information about the absolute age of rocks and other geological features, including the age of fossilized life forms or the age of Earth itself, and can also be used to date a wide range of natural and man-made materials. Among the best-known techniques are radiocarbon dating, potassium–argon dating and uranium–lead dating.

infogeo

https://infogeo.org/dating-techniques-methods-for-determining-the-age-of-rocks-and-fossils/

[60] Dating Techniques: Methods for Determining the Age of Rocks ... - InfoGeo — Dating Techniques: Methods for Determining the Age of Rocks and Fossils Dating Techniques: Methods for Determining the Age of Rocks and Fossils Absolute dating methods give exact dates for when rocks and fossils formed. Absolute dating methods give exact dates for when geological materials and fossils formed. In archaeological dating, relative methods are key for knowing the age order of findings. Absolute dating methods help figure out precise times and dates. Dating Techniques: Methods for Determining the Age of Rocks and Fossils Luminescence dating fits materials aged 1,000 to 1,000,000 years. It helps date archaeological finds and fossils linked to volcanic layers. But, methods like potassium-argon or uranium-lead date various items, even billions of years old. Dating Method https://www.nature.com/scitable/knowledge/library/dating-rocks-and-fossils-using-geologic-methods-107924044/

eartharxiv

https://eartharxiv.org/repository/object/1492/download/3312/

[61] Isotope Geology Part I: Radiometric Geochronology - EarthArXiv — The use of naturally occurring radioactive isotopes to date min-erals and rocks is the oldest and best known branch of isotope geol-ogy. The foundations of these so-called isotopic or radiometric dating methods were laid shortly after the turn of the XXth century with the discovery of the laws of radioactive decay by eminent physicists such as Ernest Rutherford and Frederick Soddy (Rutherford

science

https://spj.science.org/doi/10.34133/space.0170

[62] Isotopic Geochronological Constraints on the Formation and Evolution of ... — Since the returns of Apollo lunar samples, their potential crystallization ages have been studied extensively with the whole-rock and mineral U-Pb, 147 Sm-143 Nd, 87 Rb-87 Sr, 146 Sm-142 Nd, and 40 Ar-39 Ar isotopic systematics, and the U-Pb systematics in U-bearing minerals . However, unlike most terrestrial rocks, most lunar rocks

pnas

https://www.pnas.org/doi/10.1073/pnas.2404254121

[63] Fundamental constraints and questions from the study of martian ... - PNAS — Zircons—resilient minerals frequently leveraged for geochronology—from NWA 7034 are unaffected by the life-limiting shock pressures seen in ancient terrestrial and lunar samples , meaning that the surface of Mars could have been quiescent and possibly habitable from 4.2 Ga to 3.5 Ga, as water largely dissipated . Lithologically diverse

usgs

https://pubs.usgs.gov/gip/fossils/succession.html

[96] Fossils, Rocks, and Time: Fossil Succession - USGS Publications Warehouse — Fossils, Rocks, and Time: Fossil Succession (3) The kinds of fossils found in rocks of different ages differ because life on Earth has changed through time. When we find the same kinds of fossils in rocks from different places, we know that the rocks are the same age.Scientists look for ancestors and descendants through geologic time. His explanation gave scientific meaning to the observed succession of once-living species seen as fossils in the record of Earth's history preserved in the rocks. The Law of Fossil Succession is very important to geologists who need to know the ages of the rocks they are studying. Detailed studies of many rocks from many places reveal that some fossils have a short, well-known time of existence.

wikipedia

https://en.wikipedia.org/wiki/Law_of_superposition

[97] Law of superposition - Wikipedia — The law of superposition is an axiom that forms one of the bases of the sciences of geology, archaeology, and other fields pertaining to geological stratigraphy. In its plainest form, it states that in undeformed stratigraphic sequences, the oldest strata will lie at the bottom of the sequence, while newer material stacks upon the surface to form new deposits over time. This is paramount to

earthsci

https://earthsci.org/space/space/geotime/radate/radate.html

[98] Radioactive Dating - Earth Sci — The procedures used to isolate and analyze the parent and daughter nuclides must be precise and accurate. This normally involves isotope ratio mass spectrometry. The precision of a dating method depends in part on the half-life of the radioactive isotope involved. For instance, carbon-14 has a half-life of 5,730 years.

sciencing

https://www.sciencing.com/radiometric-dating-definition-how-does-it-work-uses-examples-13719056/

[99] Radiometric Dating: Definition, How Does It Work, Uses & Examples — Calculations involving radioactive isotopes are more formal but follow the same basic principle: If you know the half-life of the radioactive element and can measure how much of each isotope is present, you can figure out the age of the fossil, rock or other entity it comes from. Because these differ by a factor of almost seven (recall that a billion is 1,000 times a million), it proves a "check" to make sure you're calculating the age of the rock or fossil properly, making this among the most precise radiometric dating methods. The half-life of potassium is 1.25 billion years, making this technique useful for dating rock samples ranging from about 100,000 years ago (during the age of early humans) to around 4.3 billion years ago.

geoscience

https://geoscience.blog/the-role-of-assumptions-in-isotopic-radiometric-dating-an-earth-science-perspective/

[100] The Role of Assumptions in Isotopic Radiometric Dating: An Earth ... — For the general public, understanding the role of assumptions in radiometric dating can help demystify the process and reduce misconceptions about the accuracy and reliability of dating results. In summary, assumptions play a critical role in radiometric dating, and it is important to understand their impact on the accuracy and reliability of dating results. Scientists use a range of techniques to test and verify their radiometric dating results, including cross-checks with other dating methods, analyzing multiple samples from the same location, and measuring the isotopic composition of individual minerals within the sample. | viewed_cookie_policy | 11 months | The cookie is set by the GDPR Cookie Consent plugin and is used to store whether or not user has consented to the use of cookies.

modern-physics

https://modern-physics.org/radiometric-dating/

[101] Radiometric Dating | Accuracy, Methods & Applications — Radiometric Dating | Accuracy, Methods & Applications Mechanics Waves and Acoustics Wave Mechanics First Law of Thermodynamics Third Law of Thermodynamics Radiometric Dating Explore the accuracy, methods, and applications of radiometric dating, a key technique for determining Earth’s age and understanding geological and archaeological timelines. Understanding the principles and applications of radiometric dating not only enriches our knowledge of Earth’s history but also underscores the precision and reliability of science in deciphering the natural world. Methods of Radiometric Dating Applications of Radiometric Dating Additionally, the development of new dating methods, such as luminescence dating, expands the scope of radiometric techniques to materials previously undatable. Radiometric dating remains a fundamental technique in the geosciences, offering a reliable method for determining the age of rocks, minerals, and archaeological finds.

sciencenews

https://www.sciencenews.org/article/radiometric-dating-history-carbon-century-science

[102] Radiometric dating puts pieces of the past in context. Here's how — Published Time: 2021-10-05T09:30:39-04:00 Radiometric dating puts pieces of the past in context. Here’s how The famous skeleton Lucy is too old for radiocarbon dating. But using argon-argon dating on tiny crystals in layers of volcanic ash sandwiching the sediments where Lucy was found, researchers have put the fossils at 3.18 million years old. It helps place the object in its proper archaeological, geologic or cosmological context. Read more The discovery of radioactivity in the mid-1890s paved the way for scientists to ascertain the absolute ages of some objects, says Doug Macdougall, a geochemist formerly at the Scripps Institution of Oceanography and the author of Nature’s Clocks.

britannica

https://www.britannica.com/summary/dating-geochronology

[110] Basic principles of relative and absolute dating | Britannica — dating, In geology and archaeology, the process of determining an object's or event's place within a chronological scheme.Scientists may use either relative dating, in which items are sequenced on the basis of stratigraphic clues (see stratigraphy) or a presumed evolution in form or structure, or absolute dating, in which items are assigned a date independent of context.

socratic

https://socratic.org/questions/what-are-some-of-the-limits-of-radiometric-dating-techniques

[124] What are some of the limits of radiometric dating techniques? — What are some of the limits of radiometric dating techniques? What are some of the limits of radiometric dating techniques? The limitations of radiometric dating can be split into two general categories, analytical limitations and natural limitations. Analytical limitations encompass the limitations of the machinery that is being used to date a material. The reason it isn't 1 million year old is because the half-life of 14-C is about 5 730 years, which means after about 50 000 years there is no more 14-C to measure, hence the limit of that dating technique is about 50 000 years. So the million year old object was incorrectly dated using a decay series not suited to it. How can radioactive decay be used to date rocks?

medium

https://medium.com/global-science-news/critical-analysis-of-radiometric-dating-of-meteorites-accuracy-assumptions-and-potential-a88aba53209f

[125] Critical Analysis of Radiometric Dating of Meteorites ... - Medium — Radiometric dating, meteorites, uranium-lead dating, radioactive decay rates, isochron method, geochronology, isotopic analysis This article critically evaluates the assumptions underlying radiometric dating, particularly the constancy of radioactive decay rates over geological time, and explores potential limitations, including the role of extreme astrophysical events, natural nuclear reactions, and chemical alterations in sample preservation. Despite its widespread acceptance, radiometric dating is based on several key assumptions: (1) radioactive decay rates have remained constant over billions of years, (2) initial isotopic compositions can be accurately determined, and (3) samples have remained closed systems, free from contamination or loss of parent or daughter isotopes (Faure & Mensing, 2005). A fundamental assumption in radiometric dating is that decay rates remain unchanged over geological time.

usgs

https://www.usgs.gov/observatories/yvo/news/a-beginners-guide-dating-rocks

[131] A beginner's guide to dating (rocks) | U.S. Geological Survey - USGS.gov — The most commonly used include: (1) radiometric dating, which measures the proportions of parent and daughter material left after the decay of radioactive atoms naturally present in rocks and minerals, (2) cosmogenic surface exposure dating, which measures the concentration of elements produced when cosmic rays interact with rocks and minerals, and (3) paleomagnetism, which measures the magnetic properties of rocks to determine their absolute or relative age. The method cannot date rocks directly and is most useful for material that is only a few tens of thousands of years old, so it is less commonly used in volcanological studies of the Yellowstone region. In volcanic systems like Yellowstone, combining eruption age information from 40Ar/39Ar geochronology with the timing of crystal formation from U-series dating can inform how long magmas sit in the crust before erupting.

nature

https://www.nature.com/articles/s41586-024-07679-4

[134] Extreme solar storms and the quest for exact dating with radiocarbon — This work has been facilitated by advances in accelerator mass spectrometry (AMS) instrumentation 33,34,35, which means that high-precision 14 C measurements (less than 2‰ in Δ 14 C

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0165993624004497

[135] Stable Isotope Ratio Mass Spectrometry and Site-Specific Natural ... — Accelerator mass spectrometry (AMS) is a modern radiocarbon dating method that is considered to be the more efficient way to measure a sample radiocarbon content. In this method, the carbon-14 content is directly measured in relation to the carbon-12 and carbon-13 ones.

iaea

https://inis.iaea.org/records/rzvtk-ypr33

[136] U-series dating using thermal ionisation mass spectrometry (TIMS) — U-series dating is based on the decay of the two long-lived isotopes238U(τ1/2=4.47 x 109 years) and 235U (τ1/2 0.7 x 109 years). 238U and its intermediate daughter isotopes 234U (τ1/2 = 245.4 ka) and 230Th (τ1/2 = 75.4 ka) have been the main focus of recently developed mass spectrometric techniques (Edwards et al., 1987) while the other less frequently used decay chain is based on the

iahs

https://iahs.info/uploads/dms/14489.05-3-12-keynote-325-lang.pdf

[137] PDF — dating. More recently, MC ICPMS (Multi Collector Inductively Coupled Plasma Mass Spectrometry) has also been used, having a precision at a comparable level to TIMS (Goldstein & Stirling, 2003). Based on the mass spectrometry techniques the age-range accessible with U-series dating stretches from less than 1 ka to more than 500 ka.

cambridge

https://www.cambridge.org/core/journals/the-paleontological-society-papers/article/abs/opportunities-and-challenges-of-a-highly-resolved-geological-timescale/108577C48C871F08C1BC744E60101046

[148] Opportunities and Challenges of a Highly Resolved Geological Timescale — The advent of greatly improved radiometric dating techniques with lower uncertainties, the development of new dating and correlation techniques, including vastly expanded quantitative biostratigraphic methods, and the possibility of reliable extension of orbital cyclostratigraphy into the Paleozoic all promise a great improvement in the ability of geologists to construct high-resolution

wiley

https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2024EF004540

[151] How Interpretable Machine Learning Can Benefit Process Understanding in ... — 1 Introduction. The widespread application of machine learning (ML) in the geosciences, particularly for predictive modeling, represents a significant technological advance (e.g., Bi et al., 2023; Ham et al., 2019).While their predictive capabilities are widely acknowledged, ML methods are often considered separate from the fundamental scientific methodologies of the geosciences, typically

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0016703799003889

[152] Quantitative comparison of large sets of geochronological data using ... — Any provenance analysis is dependent on sampling statistics and probability. In the case of detrital geochronology a large quantity of data must be gathered to be reasonably certain that all significant protosource components contributing to the sediment have been sampled.

wikipedia

https://en.wikipedia.org/wiki/Geochronology

[168] Geochronology - Wikipedia — The science of geochronology is the prime tool used in the discipline of chronostratigraphy, which attempts to derive absolute age dates for all fossil assemblages and determine the geologic history of the Earth and extraterrestrial bodies. A number of radioactive isotopes are used for this purpose, and depending on the rate of decay, are used for dating different geological periods. For paleomagnetic dating, it is suggested to use the APWP in order to date a pole obtained from rocks or sediments of unknown age by linking the paleopole to the nearest point on the APWP.

britannica

https://www.britannica.com/science/geochronology

[169] Geochronology | Definition, History, Dating, Importance, & Facts ... — geochronology, field of scientific investigation concerned with determining the age and history of Earth's rocks and rock assemblages. Such time determinations are made and the record of past geologic events is deciphered by studying the distribution and succession of rock strata, as well as the character of the fossil organisms preserved within the strata.

sciencedirect

https://www.sciencedirect.com/topics/earth-and-planetary-sciences/geochronology

[170] Geochronology - an overview | ScienceDirect Topics — Geochronology is the science of dating the age of rocks, minerals, fossils, and geologic events, using isotopic concentrations of parent and daughter nuclei in minerals. Geochronology is the science of age dating earth materials (rocks, minerals, fossils) and geologic events (Fig. 2). For recent events the main isotopic methods utilized are radiocarbon geochronology using the 14C radioisotope (for ages up to 50,000–60,000 y) and U-series dating (for ages up to 2 Ma). Although geochronological, petrological, and structural geological data were sporadically produced before the 1980s, it is mainly after the first ideas of an Alpine metamorphic history (Burchfiel, 1980), the first report of Eocene metamorphic K–Ar ages (Liati, 1986; Liati & Kreuzer, 1990) and the first identification of eclogite-facies metamorphism (Kolceva et al., 1986; Liati, 1986, 1988) that the Rhodope zone started attracting the interest of more and more geoscientists.

sciencedirect

https://www.sciencedirect.com/book/9780443188039/methods-and-applications-of-geochronology

[171] Methods and Applications of Geochronology | ScienceDirect — J. Gregory Shellnutt, Steven W. About the book J. Gregory Shellnutt, Steven W. About the book Select Chapter 1 - Introduction to methods and applications of geochronology: A perspective on geological time J. Gregory Shellnutt, Steven W. Select Chapter 5 - Zircon fission-track and U–Pb multi-method geochronology using laser ablation-ICP-mass spectrometry Select Chapter 6 - U–Th–Pb phosphate geochronology by LA-ICP-MS Select Chapter 8 - In situ beta decay dating by LA-ICP-MS/MS: applications Select Chapter 13 - A method and application for the integration of geology, geochronology, and paleontology: Case studies for important Mesozoic evolutionary events in East Asia About the book Book Cookies are used by this site. Cookie settings These cookies may be set through our site by our advertising partners.

britannica

https://www.britannica.com/science/dating-geochronology

[172] Dating | Definition, Geology, Methods, & Facts | Britannica — The Editors of Encyclopaedia Britannica Article History Table of Contents Table of Contents Ask the Chatbot Key People: Loren Eiseley Sir Flinders Petrie Édouard Lartet Jacques Boucher de Perthes Esther Boise Van Deman (Show more) Related Topics: tephrochronology obsidian–hydration–rind dating Blytt–Sernander system absolute dating varve analysis (Show more) See all related content dating, in geology, determining a chronology or calendar of events in the history of Earth, using to a large degree the evidence of organic evolution in the sedimentary rocks accumulated through geologic time in marine and continental environments. To date past events, processes, formations, and fossil organisms, geologists employ a variety of techniques. These include some that establish a relative chronology in which occurrences can be placed in the correct sequence relative to one another or to some known succession of events. Radiometric dating and certain other approaches are used to provide absolute chronologies in terms of years before the present. The two approaches are often complementary, as when a sequence of occurrences in one context can be correlated with an absolute chronology elsewhere.

geologyforinvestors

https://www.geologyforinvestors.com/geochronology-the-how-and-why-of-dating-rocks/

[174] Geochronology: The How and Why of Dating Rocks - Geology for Investors — Thorium, a radioactive element common in many rare Earth element deposits, also decays to lead, enabling thorium minerals to be dated via similar methods. LA-ICPMS U-Pb dating of zircons dates granites in the area to 118-113 Ma. Re-Os dating of molybdenite from ore-bearing veins yielded ages of 115.23 ± 0.46 and 114.86 ± 0.47 Ma. This indicates that ore deposition in the area is linked to the formation of these granites. Furthermore, these ages are nearly identical to the 114.8 ± 1.0 Ma U-Pb and 113.3 ± 1.3 Ma Ar/Ar dates from two nearby copper-gold deposits. If the deposits are placer-style, the gold would have to be older than the host conglomerates (the age of which is known through SHRIMP U-Pb dating of zircons).

academie-sciences

https://comptes-rendus.academie-sciences.fr/geoscience/articles/10.5802/crgeos.234/

[177] Recent advances in petrochronology: from dates to ages and rates of ... — Thanks to the development of in situ analysis, modern geochronology techniques allow to date various texturally and chemically constrained mineral generations and estimate the duration of the processes associated with successive crystallization events. For example, dating the overall activation interval of shear zones is possible thanks to

cide

https://conocer.cide.edu/Download_PDFS/fulldisplay/4000019/Geochronology_Time_Scales_And_Global_Stratigraphic_Correlation_Special_Publication_Sepm_Society_For_Sedimentary_Geology_No_54.pdf

[202] PDF — What are the limitations of current geochronological techniques, and how can these be overcome? Limitations include sample availability, potential for contamination, and inherent uncertainties in dating methods. Advancements in analytical techniques and improved sample preparation protocols are helping to mitigate these challenges.

princeton

https://timslab.princeton.edu/document/63

[203] It's About Time: Opportunities & Challenges for U.S. Geochronology — But generating enhanced geochronologic data is only the first step. Application of geochronology requires not just knowledge of both the resolving power and limitations of the technique, but also an equivalent understanding of the underlying geophysical processes with which to predict the geochronologic observables.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S1569843224002383

[205] The influence of changing moisture content on laboratory acquired ... — The moisture content of soil and rock samples has a significant effect on infrared reflectance values and diagnostic absorption features (Bishop et al., 1994, Verpoorter et al., 2014, Bablet et al., 2018).Moisture content can vary due to environmental factors such as rain or air humidity, before and during the acquisition of hyperspectral field data (Murphy, 2015, Bablet et al., 2018).

nih

https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE85097

[206] GEO Accession viewer - National Center for Biotechnology Information — Influence of temperature fluctuations during cryopreservation on vital parameters, plasticity, and transgene expression of placental multipotent stromal cells ... mimicking long-term preservation in practical biobanking, transportation, and temporal storage. ... Each sample was tested once. Contributor(s) Pogozhykh O, Pogozhykh D, Mueller T

springer

https://link.springer.com/content/pdf/10.1186/s13287-017-0512-7.pdf

[207] PDF — According to previously obtained data, temperature fluctuations in the steam storage device can range within -180 °C to -150 °C; rarely, in emergency situations, the temperature can rise to -130 °C. Moreover, the dry ice temperature of -78.5 °C or refrigeration equipment with a temperature of -80 °C are often used for transporta-

geoscienceworld

https://pubs.geoscienceworld.org/msa/elements/article-abstract/9/1/19/137936/Precision-and-Accuracy-in-Geochronology

[208] Precision and Accuracy in Geochronology - GeoScienceWorld — At the same time, both enhanced spatial resolution through microbeam geochronology and creative uses of disparate data sets to inform age interpretations have helped explain complexities in age data. Quantifying random and systematic sources of instrumental and geological uncertainty is vital, and requires transparency in methodology, data

geoscienceworld

https://pubs.geoscienceworld.org/gsa/gsabulletin/article/136/9-10/4233/637253/Recommendations-for-the-reporting-and

[209] Recommendations for the reporting and interpretation of isotope ... — U-Pb geochronology is used to date commonly occurring U-bearing minerals for inferring the ages of geological materials and processes in a wide range of environments across Earth history (e.g., the Geologic Time Scale 2020; Davis et al., 2003; Mattinson, 2013; Schoene, 2014).The decay of 238 U and 235 U (t 1/2 238 U, ca. 4.47 Ga; 235 U, ca. 0.704 Ga) to their stable daughter products, 206 Pb

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0009254124006429

[210] Allanite U-Th-Pb geochronology by laser ablation inductively coupled ... — Therefore, in-situ allanite U-Th-Pb geochronology is substantially hindered by the scarcity of matrix-matched allanite reference materials with low common Pb. To address the shortage of high-quality reference materials, several studies have investigated non-matrix-matched approaches for allanite U-Th-Pb dating ( Burn et al., 2017 ; El Korh

academia

https://www.academia.edu/90072212/Strengths_and_limitations_of_in_situ_U_Pb_titanite_petrochronology_in_polymetamorphic_rocks_An_example_from_western_Maine_USA

[217] (PDF) Strengths and limitations of in situ U-Pb titanite ... — One of the pitfalls of titanite U-Pb geochronology is that significant Pb may be incorporated upon crystallization and a correction for the initial common Pb composition is often required (see discussions in Kirkland et al., 2018; Bomamici & Blum, 2020).

typeset

https://typeset.io/papers/exploring-the-advantages-and-limitations-of-in-situ-u-pb-b0pqh3pr51

[218] (PDF) Exploring the advantages and limitations of in situ U-Pb ... — The high spatial resolution of LA-ICP-MS U-Pb carbonate geochronology has benefits over traditional isotope dilution methods, particularly for diagenetic and hydrothermal calcite, because uranium and lead are heterogeneously distributed on the sub-millimetre scale.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S187110142030042X

[220] Challenges and limitations of the - ScienceDirect — The exercise highlighted the relevance of solid understanding of the fundamentals, assumptions and limitations of the 210Pb dating method and its validation, and allowed identifying key aspects to improve the reliability of 210Pb dating process, including: a critical examination and interpretation of the 210Pb activity depth profile; an appropriate selection of the 210Pb dating model according to the characteristics of the 210Pb activity profile and the environmental setting taking into account sediment compaction in the calculations; a sound identification of the 210Pb equilibrium depth and the estimation of the 210Pb inventory ensuring the best possible estimation of interpolated 210Pb values when needed; and the use of independent markers to corroborate the age models.

harvard

https://ui.adsabs.harvard.edu/abs/2020QuGeo..5901093B/abstract

[221] Challenges and limitations of the 210 Pb sediment dating method ... — The 210Pb sediment dating is the most widely used method to determine recent (~100-150 years) chronologies and sediment accumulation rates in aquatic environments and has been used effectively for reconstruction of diverse environmental processes associated with global change. Owing to the relative accessibility of the 210Pb methodology, many environmental chronologies

royalsocietypublishing

https://royalsocietypublishing.org/doi/10.1098/rsta.2010.0296

[223] Humans as major geological and geomorphological agents in the ... — It is estimated that the worldwide deliberate annual shift of sediment by human activity is 57 000 Mt (million tonnes) and exceeds that of transport by rivers to the oceans (22 000 Mt) almost by a factor of three. ... Deng Q, Tong K and Li J (2020) An indicator system for assessing the impact of human activities on river structure, Journal of

geologywithfun

https://geologywithfun.com/the-impact-of-human-activities-on-geomorphology/

[224] The Impact of Human Activities on Geomorphology — Discover how the impact of human activities on geomorphology of our planet in profound ways. Explore the impact of deforestation, urbanization, mining, and climate change on geomorphology. In the grand tapestry of Earth's history, the field of geomorphology stands as a testament to the ever-changing face of our planet. It delves into the

harvard

https://ui.adsabs.harvard.edu/abs/2016AGUFM.V43B3145S/abstract

[232] Washing, Leaching, and Other Ways to Disturb Geochronological Samples — Contamination effects in geochronology depend on the mass fraction of contaminant and how much its composition differs from that of the sample. Attempts to remove contamination range from gentle washing of grains in cold water or dilute acids to harsh leaching of powders in hot, concentrated acids. It is often assumed that 1) for the element(s) of interest, the portion contributed by

ga

https://ecat.ga.gov.au/geonetwork/srv/api/records/eb2d6eee-f019-170b-e044-00144fdd4fa6

[234] Handbook of Geochronology Mineral Separation Laboratory Techniques — Rock samples collected for geochronological analysis from outcrop, drill core or dredges can range in size from 100 grams to 30 kilograms. Variations in sample type, sample size and target minerals affect the approach to sample preparation. ... Cleaning processes throughout the laboratory are very rigorous due to the risk of contamination

lab-training

https://lab-training.com/causes-of-contamination-of-laboratory-samples-and-their-prevention/

[235] Causes of Contamination of Laboratory Samples and their Prevention — The present article covers the potential sources of contamination and offers some remedial measures. To start with you should be aware of such sources of contamination. Sample environment; Sample container; Sampling Tools; Contamination from other laboratory samples; Contamination from substandard reagents; Contamination from analyst

bepress

https://works.bepress.com/mark_schmitz/13/

[241] Online Activities for Teaching the Science of Geochronology — We are developing a series of engaging, effective, and usable virtual labs/online activities to teach the science of geochronology. These labs will be available to all students and teachers through digital libraries of teaching resources, but are being designed in partnership with the Idaho Digital Learning Academy for implementation and evaluation in their 8th-9th grade on-line Earth Science

boisestate

https://experts.boisestate.edu/en/projects/k-12-virtual-labs-for-teaching-the-science-of-geochronology

[242] K-12 Virtual Labs for Teaching the Science of Geochronology — In cooperation with the Idaho Digital Learning Academy, the following objectives are being met: 1) Development of a series of virtual labs and field experiences (learning objects) for use by middle and high school students that can be strung together as part of a comprehensive curriculum on the science of geochronology or used separately to

bookwidgets

https://www.bookwidgets.com/blog/2023/05/explore-the-world-with-these-15-top-edtech-tools-for-geography-teachers

[243] Explore the World with these 15 Top EdTech Tools for Geography Teachers ... — Educational technology tools like Google Docs and Microsoft Teams can help students to collaborate on projects and assignments in real time. This can help to foster teamwork and communication skills. 6. Follow-up on student results 💯. Different IT tools allow teachers to track and monitor their students' progress.

asuprepglobal

https://www.asuprepglobal.org/news/digital-tools-for-teachers-in-the-classroom/

[244] Explore the top 10 digital tools for teachers in the classroom — Whether students flourish through visual presentations or collaborating with others, digital tools assist teachers in online classroom management. Poll Everywhere, a digital tool, enables teachers to create live polls for online student assessment. Some digital tools offer a platform for interactive online discussions, connecting teachers and students with real-time communication. From quizzes to interactive presentations to collaborative platforms, digital tools enrich online education with engaging elements for both students and teachers. Digital tools offer teachers the opportunity to create more dynamic and personalized lessons, as well as track student progress and provide instant feedback. The use of digital materials allows teachers to incorporate multimedia and interactive elements into their lessons, making learning more engaging and dynamic for students.

geoscienceworld

https://pubs.geoscienceworld.org/gsa/geology/article/52/3/193/632536/High-precision-U-Pb-geochronology-links-magmatism

[245] High-precision U-Pb geochronology links magmatism in the Southwestern ... — High-precision U-Pb zircon geochronology of Stenian (1.2-1.0 Ga) mafic rocks in California and Arizona significantly refines the timing of SWLLIP magmatism and its relationship to other Laurentian tectonic and magmatic events.

researchgate

https://www.researchgate.net/publication/346149111_Dating_mafic_magmatism_by_integrating_baddeleyite_zircon_and_apatite_U-Pb_geochronology_A_case_study_of_Proterozoic_mafic_dykessills_in_the_North_China_Craton

[246] Dating mafic magmatism by integrating baddeleyite, zircon and apatite U ... — By combining U-Pb dating and elemental mapping, this study provides a novel approach to the geochronology of mafic rocks, by highlighting the potential of ubiquitous apatite, offering additional

usgif

https://usgif.org/ai-and-the-future-of-geospatial-intelligence/

[249] AI and the Future of Geospatial Intelligence - USGIF — For example, the white paper highlights the potential of AI and machine learning (ML) to enable GEOINT analysts to fuse together large volumes of data from disparate sources in compiling their analysis. AI/ML tools could also facilitate or perform higher-order tasks such as pattern recognition.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2772883825000214

[250] Integration of geospatial techniques and machine learning in land ... — Integration of geospatial techniques and machine learning in land parcel prediction - ScienceDirect Integration of geospatial techniques and machine learning in land parcel prediction Predicted land cover changes using mixing machine learning from geospatial data. The integration of geospatial techniques and machine learning algorithms has revolutionized our ability to analyze and predict changes in land parcels. Our research will highlight the key components of this plan including data acquisition, preprocessing, feature engineering, and the application of machine learning models. These insights are used to train and fine-tune our machine learning models, which will subsequently forecast future land parcel developments. For all open access content, the relevant licensing terms apply.

wiley

https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2024EF004540

[251] How Interpretable Machine Learning Can Benefit Process Understanding in ... — 1 Introduction. The widespread application of machine learning (ML) in the geosciences, particularly for predictive modeling, represents a significant technological advance (e.g., Bi et al., 2023; Ham et al., 2019).While their predictive capabilities are widely acknowledged, ML methods are often considered separate from the fundamental scientific methodologies of the geosciences, typically

geosociety

https://www.geosociety.org/GSA/GSA/GSAToday/groundwork/G549GW/article.aspx

[267] AGeS - Geological Society of America — AGeS 3 plans to fund ~20 TRaCE projects over two proposal cycles. A common element of the three activities is making small investments that cumulatively advance the field. The well-established AGeS-Grad program will promote interdisciplinary science between graduate students and geochronology labs.

geosociety

https://www.geosociety.org/gsatoday/groundwork/G392GW/article.htm

[268] The AGeS2 (Awards for Geochronology Student research 2) Program ... — However, the impact of AGeS1 extends far beyond the funded projects. The AGeS1 funding opportunity provided a specific reason for geochronology users to reach out to the data producers annually, amounting to >40-50 contacts each year between students and labs regarding potential collaborative, interdisciplinary research projects.

tandfonline

https://www.tandfonline.com/doi/full/10.1080/00206814.2010.496163

[269] The evolution of texture and layering in layered intrusions — Mineral segregation in igneous systems, and igneous layering in particular, can occur during ageing of crystal assemblages because areas composed of nominally larger grains or texturally favoured regions grow at the expense of adjacent unfavoured regions owing to the concentration gradients in the liquid that arise from surface energy effects.