Traversing the High Sierra on the People’s Paths

When one hears the term “ground cover,” one immediately thinks of “grasses.” This perception is so deep-seated that paleobotanists even have been overheard to proclaim that “there was no ground cover before grasses.” Today grasses are so predominant in many environments that this perception is perpetuated easily. On the other hand, it is difficult to imagine the absence or lack of ground cover prior to the mid-Tertiary. We tested the hypothesis that different forms of ground cover existed in the past against examples from the Recent and the fossil record (Table 1). The Recent data were obtained from a large number of sources including those in the ecological, horticultural, and microbiological literature. Other data were derived from our knowledge of Precambrian life, sedimentology and paleosols, and the plant fossil record, especially in situ floras and fossil “monocultures.” Some of the data are original observations, but many others are from the literature. A detailed account of these results will be presented elsewhere (Pfefferkorn and LePage, in preparation).

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Plutonium in Crystalline Ceramics and Glasses

MRS Bulletin ◽

10.1557/mrs2001.180 ◽

2001 ◽

Vol 26 (9) ◽

pp. 698-706 ◽

Cited By ~ 22

Author(s):

Isabelle Muller ◽

William J. Weber

Keyword(s):

Long Range ◽

Nuclear Waste ◽

Materials Science ◽

Ceramic Matrix ◽

Range Order ◽

Long Range Order ◽

Geologic Time ◽

The Past ◽

Geologic Time Scale ◽

High Flexibility

The investigation of plutonium in glasses (amorphous ceramics lacking long-range order), in crystalline ceramics, and in composite materials composed of multiple crystalline or glass and crystalline phases, relieson multidisciplinary studies of physics, chemistry, and materials science. It involves the study of the plutonium atoms in materials with only short-range periodicity, as in glasses, to materials with long-range periodicity, as in crystals. The materials studied over the past 30 years include simple binary crystals, used to investigate the electronic structure of plutonium, to complex glasses and ceramics selected not only for the safety and durability that they provide for the immobilization of nuclear waste and plutonium, but also for the high flexibility they offer in composition. The lack of long-range order at the atomic level in glasses permits the inclusion of abroad range of waste elements, but it renders more difficult the interpretation of data from many commonly used experimental techniques. Regardless of the challenge, much of the research conducted in this field over the past few decades has been motivated by the use of plutonium as a surrogate for all nuclear-waste actinides or on its own in immobilization studies, in order to develop a durable glass or ceramic matrix that can resist leaching and mobilization of the plutonium on a geologic time scale.

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Harecxs Measurements of Elemental Disordering

Microscopy and Microanalysis ◽

10.1017/s1431927600027847 ◽

2001 ◽

Vol 7 (S2) ◽

pp. 354-355

Author(s):

Nestor J. Zaluzec ◽

Katherine L. Smith

Keyword(s):

Angular Resolution ◽

Alpha Decay ◽

High Angular Resolution ◽

Crystalline Materials ◽

X Ray ◽

Geologic Time ◽

The Past ◽

Selected Area Electron Diffraction ◽

Resolution Electron ◽

High Level

It has been long known that orientation effects in crystalline materials can influence characteristic x-ray emission and microanalysis1-7. High Angular Resolution Electron Channeling X-ray Spectroscopy (HARECXS)6-7. a variation of ALCHEMI4-5, has been used at ANL for the last few years to investigate the effects of channeling on quantitative XEDS analysis of materials. More recently we have also been using HARECXS to carefully measure elemental disordering in a number of systems and have found that it can be used very successfully to elucidate the various stages of disorder.Perovskite (nominally CaTiO3) is a host phase for actinides in various wasteforms for the immobilization of high level radioactive nuclear waste. Over geologic time, alpha decay damage of the actinides in perovskite will cause displacive effects that influence the dimensional and chemical stability of the wasteform. in the past, the progression of damage has been studied by monitoring changes in selected area electron diffraction (SAED) patterns with increasing dose (e.g. 11).

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Will Earth’s Grandest Canyon Keep Getting Grander?

Eos ◽

10.1029/2019eo136537 ◽

2019 ◽

Vol 100 ◽

Author(s):

Mary Morton

Keyword(s):

Colorado River ◽

Grand Canyon ◽

Geologic Time ◽

The Past

Living in Geologic Time: Rafting through the past, present, and future of the Colorado River and the Grand Canyon.

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Seismic geohistory analysis—A case history from the Canning Basin, Western Australia

Geophysics ◽

10.1190/1.1441669 ◽

1984 ◽

Vol 49 (4) ◽

pp. 333-343 ◽

Cited By ~ 4

Author(s):

M. F. Middleton

Keyword(s):

Western Australia ◽

Case History ◽

Fault System ◽

Seismic Section ◽

Canning Basin ◽

Geologic Time ◽

The Past ◽

Middle Carboniferous ◽

Thermal Oil

Seismic geohistory analysis is a method of reconstructing an interpreted seismic section, assuming generalized porosity‐traveltime and depth‐traveltime relations. The method can indicate timing of fault movements, juxtaposition of units across faults in the past, and depth or traveltime to specific reflection horizons throughout geologic time. The method applied to the Lennard shelf of the Canning Basin shows that the major movements of the Pinnacle fault system occurred during the Ordovician and Middle Carboniferous. The movements reflect subsidence of the Fitzroy trough, which is basinward of the Lennard shelf. The analysis also shows a prograding sediment wedge on the margin of the Lennard shelf to have had temperatures in the range 110°–116°C since Permian times. Being within the thermal oil window for the past 280 Ma, the sediment wedge may be a good hydrocarbon prospect.

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Geological Time and Psychological Time

Earth Sciences History ◽

10.17704/eshi.8.2.4102132n21644667 ◽

1989 ◽

Vol 8 (2) ◽

pp. 190-191 ◽

Cited By ~ 3

Author(s):

David Kitts

Keyword(s):

Geological Time ◽

Geologic Time ◽

The Past ◽

The Future ◽

Flow Of Time ◽

Clear Conception

The ‘flow’ of time from the future to the past through a dimensionless present is a dramatic feature of our experience. In this paper I argue that the flow of time has found its way into the practice of stratigraphy where it has been detrimental to our clear conception of geologic time.

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Tectonic forcing of global chemical weathering since the mid-Paleozoic

10.5194/egusphere-egu2020-10623 ◽

2020 ◽

Author(s):

Thomas Gernon ◽

Thea Hincks ◽

Andrew Merdith ◽

Eelco Rohling ◽

Martin Palmer ◽

...

Keyword(s):

Chemical Weathering ◽

Time Lags ◽

Late Cenozoic ◽

Rock Composition ◽

Geologic Time ◽

The Past ◽

The Earth ◽

Continental Arc ◽

Geologic Processes ◽

Tectonic Forcing

Weathering of the Earth&#8217;s surface has commonly been invoked as a driver of global cooling through geologic time. During the Phanerozoic Eon (541&#8211;0 million years ago, Ma), for example, the periodic onset of icehouse conditions has variously been attributed to enhanced weathering fluxes associated with mountain building (e.g. the Himalayas) (1), reductions in the global extent of continental arc volcanoes (e.g. the present-day Andes) (2), and uplift of oceanic crust during arc-continent collisions (e.g. present-day Indonesia and New Guinea) (3). These processes, tied to the global plate tectonic cycle, are inextricably linked.&#160; The resulting collinearity (i.e. independent variables are highly correlated) makes it difficult &#8212; using conventional statistical techniques &#8212; to isolate the contributions of individual geologic processes to global chemical weathering. &#160; An example of this is the Late Cenozoic Ice Age (34&#8211;0 Ma) that corresponds both to uplift of the Tibetan Plateau and Himalaya, and a gradual reduction in the extent of the global continental arc system.&#160;We developed a machine learning framework to analyse the interdependencies between multiple global tectonic and volcanic processes (e.g., continental distribution, extent of volcanic arcs, mid-ocean ridges etc.) and seawater Sr composition (a proxy for weathering flux) over the past 400 million years. We developed a Bayesian network incorporating a novel algorithm that accounts for time lags for each of the predictor variables, and joint conditional dependence (i.e. how variables combine to influence the environmental outcome). Our approach overcomes problems traditionally encountered in geologic time series, such as collinearity and autocorrelation. Our results strongly indicate a first-order role for volcanism in driving chemical weathering fluxes since the mid-Palaeozoic. This is consistent with the strong empirical correlation previously observed between the strontium isotope composition of seawater and continental igneous rocks over the past billion years (4). Our study highlights how geologic processes operate together &#8212; not in isolation &#8212; to perturb the Earth system over ten to hundred million-year timescales.References(1). M. E. Raymo, W. F. Ruddiman, Tectonic forcing of late Cenozoic climate, Nature 359, 117 (1992).(2). N. R. McKenzie, et al., Continental arc volcanism as the principal driver of icehouse greenhouse variability, Science 352, 444 (2016).(3). F. A. Macdonald, N. L. Swanson-Hysell, Y. Park, L. Lisiecki, O. Jagoutz, Arc-continent collisions in the tropics set Earth&#8217;s climate state, Science 364, 181 (2019).(4). C. P. Bataille et al., Continental igneous rock composition: A major control of past global chemical weathering, Science Advances 3, e1602183 (2017). &#160;

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On the declining extinction and origination rates of fossil taxa

Paleobiology ◽

10.1017/s0094837300012239 ◽

1992 ◽

Vol 18 (1) ◽

pp. 89-92 ◽

Cited By ~ 11

Author(s):

Craig M. Pease

Keyword(s):

Present Model ◽

Marine Invertebrate ◽

Extinction Rate ◽

Geologic Time ◽

The Past ◽

Extinction Rates ◽

Rate Versus ◽

Biological Explanation ◽

Length Changes ◽

Sampling Biases

The per-stage extinction rate is the product of the per-taxon extinction rate and stage length, and the per-stage origination rate is defined similarly. These rates decline from ancient to recent times because of the pull of the Recent, because there is more young than old fossiliferous rock, and because average stage length increases from the recent to the past. More specifically, the present model assumes that the graphs of ln(per-stage extinction rate) and ln(per-stage origination rate) versus geologic time have slope zero in the absence of sampling biases, and shows how sampling biases cause both these graphs to appear to have slope min(h,q) + s in the distant past, where h and q are the fossil loss and actual per-taxon extinction rates, and the stratigraphic constant, s, quantifies how stage length changes through time.Although the per-stage rates of bivalve families and marine invertebrate genera decline toward the recent, the magnitudes of these declines are entirely consistent with what the present model predicts sampling biases will produce. Hence there is no need to postulate a biological explanation for these patterns.

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Lithium isotope composition of modern and fossilized Cenozoic brachiopods

Geology ◽

10.1130/g47558.1 ◽

2020 ◽

Vol 48 (11) ◽

pp. 1058-1061

Author(s):

Kirstin E. Washington ◽

A. Joshua West ◽

Boriana Kalderon-Asael ◽

Joachim A.R. Katchinoff ◽

Emily I. Stevenson ◽

...

Keyword(s):

Narrow Range ◽

Isotope Composition ◽

Global Climate ◽

Lithium Isotope ◽

Deep Time ◽

Geologic Time ◽

The Past ◽

Global Cooling ◽

Vital Effects

Abstract Seawater lithium stable isotope ratios, represented by δ 7 Li sw (‰), hold key information about the evolution of global climate and the carbon cycle over geologic time. Reconstructions based on foraminifera suggest an ∼9‰ increase in δ 7 Li sw over the past 60 m.y., interpreted as reflecting changes in the silicate weathering regime that may have contributed to global cooling over this time. However, culture experiments suggest that vital effects in foraminifers might cause varied δ 7 Li fractionation that could have affected past records. Thus, other archives are needed to determine whether the observed rise in foraminifer δ 7 Li values over the Cenozoic indeed reflects secular changes in δ 7 Li sw . Such archives would also open possibilities for robust determination of δ 7 Li sw deeper in geologic time. We analyzed δ 7 Li compositions in modern brachiopods ( n = 34) and found a relatively narrow range of +24.2 ‰ to +28.8‰ (mean = +26.8‰; 1σ = 0.5‰), similar to the range reported for inorganic calcite precipitated from seawater. These results confirm that brachiopods are good candidates for providing a representative record of δ 7 Li sw . We present data from fossil specimens dating from 65 Ma to ca. 700 ka, finding that fossilized brachiopods record a similar magnitude of change in δ 7 Li sw as foraminifers. These results are the first to corroborate the ∼9‰ increase in Cenozoic δ 7 Li sw and open possibilities for generating robust records of δ 7 Li sw in deep time, prior to foraminifer evolution.

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