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75 results on '"Cosmogenic nuclide"'

1. Late Pleistocene slip rate of the central Haiyuan fault constrained from optically stimulated luminescence, 14C, and cosmogenic isotope dating and high-resolution topography

Author

Jinyu Zhang, Peng Wang, Michael E. Oskin, Yanxiu Shao, Wenqian Yao, Jérôme Van der Woerd, Wei Wang, Jing Liu-Zeng, Pengtao Wang, and Yann Klinger

Subjects
010504 meteorology & atmospheric sciences, Pleistocene, Optically stimulated luminescence, Geology, Slip (materials science), Active fault, 010502 geochemistry & geophysics, Collision zone, 01 natural sciences, Fault trace, 13. Climate action, Radiometric dating, Cosmogenic nuclide, Geomorphology, 0105 earth and related environmental sciences
Abstract

The Haiyuan fault is a major left-lateral active fault of the India-Asia collision zone. While the 1000 km-long fault between Hala Lake in the west to Liupan Shan in the east accommodates eastward displacement of northeast Tibet relative to the Gobi-Alashan to the north, the amount of slip accumulated and its slip-rate remain debated. We revisit the site of Daqing (or Sangedun at 102.7°E in Gaudemer et al., 1995), to better constrain the long-term slip-rate of the Haiyuan fault in its central part. We used terrestrial LiDAR to build a high-resolution DEM and Unmanned Aerial Vehicle to build an aerial photomosaic with ~0.1 m resolution to survey the offset terraces, their geomorphology and the fault trace. We refine the geomorphological interpretation of the site, measure riser offsets and determine their relation to terrace formation. The well constrained age of the highest terrace T3 at 13.7 ± 1.5 ka determined from the combination of surface and sub-surface OSL, 14 C, and terrestrial in situ 10 Be cosmogenic nuclide dating, associated with the maximum lower terrace riser offset of 88 m yield a minimum slip-rate of 6.4±1.2 mm/yr over the late Pleistocene. The age of the intermediate terrace (T2) is bracketed between 8.0 ka (14 C) and 12 ka (10 Be). The ages and vertical offsets of the 2 highest terraces is used to infer the age of T2' offset vertically 5-7 m at 5.4±1 ka. Its 29±2 m offset is consistent with a rate of 6.5 mm/yr. Given the vertical offset youngest terrace T1 of 1.3±0.2 m its age is estimated at 1.2±0.2 ka in agreement with the youngest surface exposure age. Overall, a slip rate of 5-8 mm/yr fits all offset and age data at the Daqing site. The smallest offset of a gully incised into T1 of 6.0±0.5 m is potentially associated with the most recent slip event that occurred in the last millennia.

Published
2020

2. Constraints from cosmogenic nuclides on the glaciation and erosion history of Dove Bugt, northeast Greenland

Author

David L. Egholm, Mads Faurschou Knudsen, Jane Lund Andersen, Daniel S. Skov, John D. Jansen, Jesper V. Olsen, Bo Holm Jacobsen, and Nicolaj K. Larsen

Subjects
010504 meteorology & atmospheric sciences, Erosion, Geology, Physical geography, Glacial period, Cosmogenic nuclide, 010502 geochemistry & geophysics, 01 natural sciences, Dove, 0105 earth and related environmental sciences
Abstract

The intricate interplay between subglacial topography and ice-sheet dynamics is key to the evolution of large ice sheets, but in Greenland as elsewhere the effects of long-term glacial history on landscape evolution remain poorly constrained. Here we measure abundances of cosmogenic 10Be and 26Al in bedrock and transported boulders to unveil the glaciation and erosion history of Dove Bugt, northeast Greenland. In agreement with studies of west Greenland, we find that apparent exposure ages increase with elevation from 9 ka to 13 ka in low-lying valleys to 21 ka to 204 ka on high-elevation, blockfield-covered plateaus. We employ a Markov chain Monte Carlo inversion framework to constrain the probability of various erosion histories, and we quantify the residence time of samples within the upper 2 m of the bedrock subsurface—a measure defined as the cosmogenic nuclide memory. This cosmogenic nuclide memory exceeds 600 ka on the highest plateaus but is limited to less than 500 ka in most other high-elevation samples and to less than 100 ka at low-elevations. Our results define maximum limits for the fraction of ice cover during the past 1 Ma to ∼70% on the Store Koldewey peaks and ∼90% farther inland at Pusterdal, respectively. Minimum limits to ice cover, however, cannot be reliably constrained by the data. Finally, we propose that limited erosion on the highest plateaus of Store Koldewey since 0.6–1.0 Ma indicates a minimum age for fjord-plateau formation within this area of northeast Greenland.

Published
2020

4. Arrested development: Erosional equilibrium in the southern Sierra Nevada, California, maintained by feedbacks between channel incision and hillslope sediment production

Author

Jean L. Dixon, Leonard S. Sklar, W. Jesse Hahm, Clifford S. Riebe, Ken L. Ferrier, Barbara S. Jessup, Anthony Dosseto, Scott N. Miller, Dale W. Johnson, Carolyn T. Hunsaker, and R. P. Callahan

Subjects
Canyon, Hydrology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Bedrock, Sediment, Geology, Weathering, 010502 geochemistry & geophysics, 01 natural sciences, Tributary, Erosion, Cosmogenic nuclide, San Joaquin, 0105 earth and related environmental sciences
Abstract

Tributary creeks of the southern Sierra Nevada have pronounced knickpoints that separate the landscape into an alternating sequence of gently sloped treads and steeply sloped risers. These knickpoints and the surrounding “stepped topography” suggest that the landscape is still responding to Pleistocene changes in base level on main-stem rivers. We tested this hypothesis using cosmogenic nuclides and uranium isotopes measured in stream sediment from widely distributed locations. Catchment-scale erosion rates from the cosmogenic nuclides suggest that the treads are relict surfaces that have adjusted to a previous base level. Nevertheless, erosion rates of relict interfluves are similar to canyon incision rates, implying that relief is unchanging in the lower Kings and San Joaquin Rivers. In addition, our results suggest that much of the southern Sierra Nevada is in a state of arrested development: the landscape is not fully adjusted to—and moreover is not responding to— changes in base-level lowering in the canyons. We propose that this can be explained by a paucity of coarse sediment supply, which fails to provide sufficient tools for bedrock channel incision at knickpoints. We hypothesize that the lack of coarse sediment in channels is driven by intense weathering of the local granitic bedrock, which reduces the size of sediment supplied from hillslopes to the channels. Our analysis highlights a feedback in which sediment size reduction due to weathering on hillslopes and transport in channels is both a key response to and control of bedrock channel incision and landscape adjustment to base-level change.

Published
2019

6. Laurentide ice sheet thinning and erosive regimes at Mount Washington, New Hampshire, inferred from multiple cosmogenic nuclides

Author

Jeremy D. Shakun, Susan R. Zimmerman, P. Thompson Davis, Paul R. Bierman, Brent M. Goehring, Lee B. Corbett, Alexandria J. Koester, and Anthony Vickers

Subjects
geography, geography.geographical_feature_category, Thinning, Ice sheet, Cosmogenic nuclide, Geomorphology, Geology
Abstract

The northward retreat history of the Laurentide ice sheet through the lowlands of the northeastern United States during the last deglaciation is well constrained, but its vertical thinning history is less well known because of the lack of direct constraints on ice thickness through time and space. In addition, the highest elevations in New England are characterized by gently sloping upland surfaces and weathered block fields, features with an uncertain history. To better constrain ice-sheet history in this area and its relationship to alpine geomorphology, we present 20 new 10Be and seven in situ 14C cosmogenic nuclide measurements along an elevation transect at Mount Washington, New Hampshire, the highest mountain in the northeastern United States (1917 m above sea level [a.s.l.]). Our results suggest substantially different exposure and erosion histories on the upper and lower parts of the mountain. Above 1600 m a.s.l., 10Be and in situ 14C measurements are consistent with upper reaches of the mountain deglaciating by 18 ka. However, some 10Be ages are up to several times greater than the age of the last deglaciation, consistent with weakly erosive, cold-based ice that did not deeply erode preglacial surfaces. Below 1600 m a.s.l., 10Be ages are indistinguishable over a nearly 900 m range in elevation and imply rapid ice-surface lowering ca. 14.1 ± 1.1 ka (1 standard deviation; n = 9). This shift from slow thinning early in the deglaciation on the upper part of the mountain to abrupt thinning across the lower elevations coincided with accelerated ice-margin retreat through the region recorded by Connecticut River valley varve records during the Bølling interstadial. The Mount Washington cosmogenic nuclide vertical transect and the Connecticut River valley varve record, along with other New England cosmogenic nuclide records, suggest rapid ice-volume loss in the interior northeastern United States in response to Bølling warming.

Published
2021

20. Glacial history and landscape evolution of southern Cumberland Peninsula, Baffin Island, Canada, constrained by cosmogenic10Be and26Al

Author

Lee B. Corbett, Paul R. Bierman, and P. Thompson Davis

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Bedrock, Geology, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, Paleontology, Surface exposure dating, Moraine, Deglaciation, Glacial period, Cosmogenic nuclide, Quaternary, 0105 earth and related environmental sciences
Abstract

Since the first application of cosmogenic nuclides to the study of glacial history and processes in 1990, increasing numbers of studies have used a variety of cosmogenic isotopes to quantify the exposure age and erosion rate of glaciated landscapes. However, obtaining chronological data from glaciated landscapes once covered by cold-based, nonerosive ice is challenging because these surfaces violate assumptions associated with simple cosmogenic exposure dating. Nonerosive glacial ice fails to completely remove nuclides produced during previous periods of exposure, leaving behind rock surfaces with complex, multigenetic nuclide inventories. Here, we constrain the glacial history, landscape evolution, and efficiency of subglacial erosion in the Pangnirtung Fiord region of southern Baffin Island using over 300 paired analyses of in situ cosmogenic 10Be and 26Al. Simple exposure ages are 6.3–160 ka for 10Be ( n = 152) and 4.3–124 ka for 26Al ( n = 153). Paired bedrock-boulder samples have discordant ages, simple exposure ages generally increase with elevation, 10Be and 26Al ages for the same sample disagree, and both boulders and bedrock yield multimodal age distributions—all patterns suggestive of limited subglacial erosion. Measured 26Al/10Be ratios indicate that about one third of the samples in the data set experienced at least one period of pre-Holocene exposure followed by burial with limited erosion. Modeled two-isotope minimum-limiting exposure durations are as high as hundreds of thousands of years, and minimum-limiting burial durations range up to millions of years, implying that parts of southern Baffin Island have been preserved beneath nonerosive glacial ice for much, if not all, of the Quaternary. A subset of the samples contains few nuclides inherited from prior periods of exposure and is thus useful for constraining the chronology of the most recent deglaciation. Using these samples, we infer that deglaciation of most of the landscape occurred ca. 11.7 ka and that the Duval moraines, a prominent feature of the last deglaciation, formed ca. 11.2 ka.

Published
2016

21. Post-tectonic landscape evolution of a coupled basin and range: Pinaleño Mountains and Safford Basin, southeastern Arizona

Author

Arjun M. Heimsath and Matthew C. Jungers

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Physiographic province, Drainage basin, Geology, Structural basin, 010502 geochemistry & geophysics, 01 natural sciences, Paleontology, River terraces, Erosion, Cosmogenic nuclide, Quaternary, Basin and range topography, Geomorphology, geographic locations, 0105 earth and related environmental sciences
Abstract

The Pinaleno Mountains and adjacent Safford Basin are a landscape defined by the extensional tectonics of the Basin and Range physiographic province. However, over the last ∼4 m.y., this coupled basin and range have been actively degrading in the absence of widespread regional extension. While rates of relief generation and upland erosion during active subsidence ca. 12–5 Ma are reflected in the geometry of the basin’s structure and the stratigraphy it contains, rates of post-tectonic landscape evolution from the Pliocene to the present have been heretofore unknown. We combined topographic analyses of the Pinaleno Mountains with cosmogenic nuclide–derived catchment-averaged erosion rates and burial dates of axial and piedmont deposits to quantify rates of post-tectonic landscape evolution and define a chronology for the last stages of deposition and subsequent incision in Safford Basin. In addition to constraining the timing of a deposit’s formation, cosmogenic nuclide burial dates provide paleo-upland erosion rates at the time of deposition. Erosion rates in the Pinaleno Mountains have been generally moderate over the past 4 m.y., ranging between ∼30 and 60 m/m.y. with no strong relationship to the drainage basins’ modern topography. A potential acceleration of erosion rates to 100–250 m/m.y. between 3.5 and 2 Ma correlates with an inferred period of enhanced precipitation as well as the arrival from upstream of the Gila River in Safford Basin sometime shortly before 2.8 Ma. Widespread incision of Safford Basin was under way by ca. 2 Ma, as recorded by the dissection of piedmont basin highstand deposits (Frye Mesa) and two intermediate Gila River terraces on the northeast margin of Safford Basin (dated to 1.8 Ma and 0.64 Ma). Gila River incision rates have ranged from 30 to 60 m/m.y. over the past 3 m.y. Paleo-upland erosion rates and modern millennial-scale upland erosion rates fall within the same range as incision rates of the Gila River in Safford Basin, suggesting that upland erosion rates are predominantly a function of base-level fall driven by axial incision. However, based on similarities between catchment-averaged erosion rates and topography from basins draining into the integrated Safford Basin and the still internally drained Sulphur Springs Basin to the south, it appears that upland erosion rates during the Quaternary are not being driven exclusively by regional incision rates.

Published
2015

22. Paleodischarge of the Mojave River, southwestern United States, investigated with single-pebble measurements of10Be

Author

David M. Miller, Andrew J. Cyr, and Shannon A. Mahan

Subjects
Hydrology, Pleistocene, Discharge, Pluvial, Stratigraphy, Interglacial, Geology, Glacial period, Cosmogenic nuclide, Quaternary, Pebble
Abstract

The paleohydrology of ephemeral stream systems is an important constraint on paleoclimatic conditions in arid environments, but remains difficult to measure quantitatively. For example, sedimentary records of the size and extent of pluvial lakes in the Mojave Desert (southwestern USA) have been used as a proxy for Quaternary climate variability. Although the delivery mechanisms of this additional water are still being debated, it is generally agreed that the discharge of the Mojave River, which supplied water for several Pleistocene pluvial lakes along its course, must have been significantly greater during lake highstands. We used the 10 Be concentrations of 10 individual quartzite pebbles sourced from the San Bernardino Mountains and collected from a ca. 25 ka strath terrace of the Mojave River near Barstow, California, to test whether pebble ages record the timing of large paleodischarge of the Mojave River. Our exposure ages indicate that periods of discharge large enough to transport pebble-sized sediment occurred at least 4 times over the past ∼240 k.y.; individual pebble ages cluster into 4 groups with exposure ages of 24.82 ± 4.36 ka (n = 3), 55.79 ± 3.67 ka (n = 2), 99.14 ± 12.07 ka (n = 4) and 239.9 ± 52.16 ka (n = 1). These inferred large discharge events occurred during both glacial and interglacial conditions. We demonstrate that bedload materials provide information about the frequency and duration of transport events in river systems. This approach could be further improved with additional measurements of one or more cosmogenic nuclides coupled with models of river discharge and pebble transport.

Published
2015

23. Deriving rock uplift histories from data-driven inversion of river profiles

Author

Christoph Glotzbach

Subjects
geography, geography.geographical_feature_category, Inversion (geology), Geology, Geophysics, Massif, Time gap, Synthetic data, Data-driven, Earth surface, Cosmogenic nuclide, Geomorphology, Stream power
Abstract

Reconstructing the evolution of Earth’s landscape is a key to understanding its future evolution and to identifying the driving forces that shape Earth’s surface. Cosmogenic nuclide and thermochronological investigations are routinely used to quantify Earth surface processes over 10 2 –10 4 yr and 10 6 –10 7 yr, respectively. A comparison of the rates of surface processes derived from these methods is, however, hampered by the large difference in their time scales. River profiles bridge this time gap and record the regional uplift history over 10 2 –10 7 yr. Here I present an integrative inverse modeling approach to simultaneously reconstruct river profiles, model thermochronological and cosmogenic nuclide data, and derive robust information about landscape evolution over thousands to millions of years. An efficient inversion routine is used to solve the forward problem and find the best uplift history and erosional parameters (such as the exponents of discharge [ m ] and slope [ n ] in the stream power equation) that reproduce the observed data. I test the performance of the algorithm by inverting a synthetic data set and a data set from the Sila massif (Italy). Results show that even complicated uplift histories can be reliably retrieved by the combined interpretation of river profiles and thermochronological and cosmogenic nuclide data.

Published
2015

24. Age of Matuyama-Brunhes boundary constrained by U-Pb zircon dating of a widespread tephra

Author

Martin J. Head, Jun-Ichi Kimura, Yusuke Suganuma, Kenji Kawamura, Osamu Kazaoka, Yuki Haneda, Ryoko Senda, Makoto Okada, Mami Takehara, Kenji Horie, and Hiroshi Kaiden

Subjects
Paleontology, Stratigraphy, Geologic time scale, Ice core, Geology, Cosmogenic nuclide, Tephra, Isotopes of oxygen, Zircon, Chronology
Abstract

The youngest geomagnetic polarity reversal, the Matuyama-Brunhes boundary (MBB), provides an important datum plane for sediments, ice cores, and lavas. Its frequently cited age of 780 ka is based on orbital tuning of marine sedimentary records, and is supported by 40 Ar/ 39 Ar dating of Hawaiian lavas using recent age calibrations. Challenging this age, how-ever, are reports of younger astrochronological ages based on oxygen isotope stratigraphy of high-sedimentation-rate marine records, and cosmogenic nuclides in marine sediments and an Antarctic ice core. Here, we present a U-Pb zircon age of 772.7 ± 7.2 ka from a marine-deposited tephra just below the MBB in a forearc basin in Japan. U-Pb dating has a distinct advantage over 40 Ar/ 39 Ar dating in that it is relatively free from assumptions regarding stan-dardization and decay constants. This U-Pb zircon age, coupled with a newly obtained oxygen isotope chronology, yields an MBB age of 770.2 ± 7.3 ka. Our MBB age is consistent with those based on the latest orbitally tuned marine sediment records and on an Antarctic ice core. We provide the first direct comparison between orbital tuning, U-Pb dating, and magnetostratig-raphy for the MBB, fulfilling a key requirement in calibrating the geological time scale.INTRODUCTION

Published
2015

25. Active mountain building along the eastern Colombian Subandes: A folding history from deformed terraces across the Tame anticline, Llanos Basin

Author

Andrés Mora, Gabriel Veloza, Michael H. Taylor, and John C. Gosse

Subjects
Critical taper, geography, Mountain formation, geography.geographical_feature_category, Terrace (geology), Pleistocene, Anticline, Geology, Cosmogenic nuclide, Structural basin, Quaternary, Geomorphology
Abstract

Active crustal shortening and surface uplift are vividly expressed in the foothills of the Eastern Cordillera of Colombia. Quaternary alluvial-fan and terrace deposits are folded and uplifted tens to hundreds of meters above the local base level, recording deformation and incision of the landscape. We used geomorphic observations and structural analysis from a 300 km 2 three-dimensional seismic-reflection survey over an actively growing anticline to investigate the relationship between finite shortening and surface uplift, and its effects on landscape evolution. A quantitative description of finite shortening of the pregrowth strata from excess-area and line-length calculations were compared with uplift and shortening estimates obtained from geomorphic strain markers dated using in situ 10 Be cosmogenic nuclide depth profiles. This combined approach provides the first estimates of Quaternary surface uplift and horizontal shortening rates along the foothills of the northeastern Colombian Andes. Finite shortening for the Tame anticline was calculated using two different approaches. Excess-area shortening varies from 530 ± 36 m (2σ) at its southern end, decreasing northward to 404 ± 72 m (2σ), whereas line-length shortening is typically an order of magnitude smaller. Using the maximum horizontal shortening, our results for the Tame anticline reveal a Quaternary uplift rate of 2.8 ± 1.5 mm/yr, and a shortening rate of 2.1 ± 1.2 mm/yr (2σ), with the older terraces located at the highest elevations and recording the highest rotation from the horizontal, indicating growth by limb rotation. Based on these rates, the initiation of folding is estimated to be 0.25 +0.09/–0.05 Ma (2σ). We hypothesize that the discrepancy between shortening estimates from line-length and excess-area calculations can be reconciled by accounting for internal deformation, likely developed during the initial stages of folding, which can be represented by strain hardening, for example. The shortening rates we obtain are comparable to geodetically derived shortening rates but are slightly lower than long-term geologic shortening rates. Slower shortening rates and the presence of a youthful structure at the thrust front suggest that the orogen has been migrating eastward since the late Pleistocene, probably due to reorganization of a supercritical thrust wedge farther west in the hinterland, to attain critical taper.

Published
2015

26. Flood-flipped boulders: In-situ cosmogenic nuclide modeling of flood deposits in the monsoon tropics of Australia

Author

Toshiyuki Fujioka, Gerald C. Nanson, Rainer Wende, Charles Mifsud, and David Fink

Subjects
education.field_of_study, geography, geography.geographical_feature_category, Flood myth, Bedrock, Population, Geology, Monsoon, Paleontology, Cosmogenic nuclide, education, Quaternary, Geomorphology, Holocene, Channel (geography)
Abstract

During the Quaternary, extreme floods along the Durack River, in the Kimberley, northern Australia, dislodged, transported, and stacked massive meter-sized boulders from the underlying bedrock channel floor. Field evidence identified a population of the boulders to have been overturned after detachment. We measured in situ cosmogenic 10 Be and 26 Al concentrations in six imbricated boulders to constrain the timing of flood events. We present a simple numerical model that simultaneously solves the expressions for the predicted nuclide concentrations from the exposed and hidden surfaces of a flipped boulder to calculate the time since it was overturned. The ability of the model to unequivocally discern whether a boulder was overturned depends on boulder thickness and the site-specific steady-state erosion rate. Of the six boulders sampled, our model successfully determined four finite flip ages, whereas the other two boulders indicated steady state and were either not flipped or flipped sufficiently long ago for the nuclide profile to have returned to steady state. While the two older model ages (ca. 150 ka and ca. 260 ka) are strongly sensitive to assumptions made for the local erosion rate correction, the two younger flip ages, 5.6 ± 1.0 ka and 10.3 ± 1.9 ka, are robust against such corrections. Early to mid-Holocene major floods have been recorded in other parts of northern Australia. We suggest that similar Holocene floods occurred in the Kimberley and that such extreme events may have been widespread in northern Australia in the late Quaternary. Our boulder-flip model can be applicable to similar deposits associated with other extreme events such as paleo-tsunamis.

Published
2015

29. AGE-EROSION CONSTRAINTS ON AN EARLY PLEISTOCENE PALEOSOL IN YUKON, CANADA, WITH PROFILES OF 10BE AND 26AL: EVIDENCE FOR A SIGNIFICANT LOESS COVER EFFECT ON COSMOGENIC NUCLIDE PRODUCTION RATES

Author

Duane G. Froese, Paul Sanborn, John C. Gosse, and Alan J. Hidy

Subjects
010506 paleontology, geography, geography.geographical_feature_category, Early Pleistocene, Bedrock, Climate oscillation, 15. Life on land, 01 natural sciences, Paleosol, 13. Climate action, Loess, Physical geography, Glacial period, Cosmogenic nuclide, Ice sheet, Geology, 0105 earth and related environmental sciences
Abstract

Wounded Moose type paleosols developed on remnant deposits of Late Pliocene to Early Pleistocene [pre-Reid] Cordilleran Ice Sheet [CIS] glaciations in central Yukon, Canada. It is an important regional soil-geomorphic marker at the boundary between early CIS advances and the non-glaciated regions of Yukon and Alaska. Yet, at present, its age is poorly constrained between the Reid [0.2 Ma] and earliest [2.84 Ma] CIS advances. Here, we apply depth profiles of in situ-produced cosmogenic 26Al and 10Be to obtain both a minimum exposure age [1.12+0.44/−0.36 Ma, 2σ] and maximum erosion rate [1.1+0.9/−0.5 m Myr−1] for the Wounded Moose paleosol. Our results show that this soil formed under exceptionally stable conditions [max erosion rate similar to polar bedrock erosion rates] and that it pre-dates the emergence of the 100 ka [eccentricity] climate cycle. Contrasting our results from single- and joint-nuclide depth profile models reveals a significant discrepancy between calculated and effective 10Be and 26Al production rates [40–65% of expected values]. We interpret this discrepancy as the result of intermittent loess cover—with a time-averaged depth between 60 and 110 cm—which significantly reduced apparent exposure ages obtained from the single–nuclide model. The observation of such a significant loess-cover effect on cosmogenic nuclide production has implications for exposure dating in glacial and periglacial environments; a multi-nuclide sampling strategy is required to quantify this effect.

Published
2017

32. Knickpoint formation, rapid propagation, and landscape response following coastal cliff retreat at the last interglacial sea-level highstand: Kaua'i, Hawai'i

Author

Benjamin H. Mackey, Joel S. Scheingross, Michael P. Lamb, and Kenneth A. Farley

Subjects
geography, geography.geographical_feature_category, Knickpoint, Interglacial, Geology, Cosmogenic nuclide, Waterfall, Debris, Sediment transport, Geomorphology, Sea level, Submarine landslide
Abstract

Upstream knickpoint propagation is an important mechanism for channel incision, and it communicates changes in climate, sea level, and tectonics throughout a landscape. Few studies have directly measured the long-term rate of knickpoint retreat, however, and the mechanisms for knickpoint initiation are debated. Here, we use cosmogenic ^3He exposure dating to document the retreat rate of a waterfall in Ka’ula’ula Valley, Kaua‘i, Hawai‘i, an often-used site for knickpoint-erosion modeling. Cosmogenic exposure ages of abandoned surfaces are oldest near the coast (120 ka) and systematically decrease with upstream distance toward the waterfall (

Published
2014

33. What does a mean mean? The temporal evolution of detrital cosmogenic denudation rates in a transient landscape

Author

Nicole M. Gasparini, Gilles Brocard, Jane K. Willenbring, and Benjamin T. Crosby

Subjects
geography, geography.geographical_feature_category, Landscape evolution model, Denudation, Landform, River terraces, Tributary, Erosion, Detritus (geology), Geology, Cosmogenic nuclide, Geomorphology
Abstract

In equilibrium landscapes, 10 Be concentrations within detrital quartz grains are expected to quantitatively refl ect basin-wide denudation rates. In transient landscapes, though detrital quartz is derived from both the incising, adjusting lowland and the unadjusted, relict upland, the integrated 10 Be concentrations still provide a denudation rate averaged across the two domains. Because fi eld samples can provide only a snapshot of the current upstream-averaged erosion rate, we employ a numerical landscape evolution model to explore how 10 Be-derived denudation rates vary over time and space during transient adjustment. Model results suggest that the longitudinal pattern of mean denudation rates is generated by the river’s progressive dilution of low-volume, high-concentration detritus from relict uplands by the integration of high-volume, low-concentration detritus from adjusting lowlands. The proportion of these materials in any detrital sample depends on what fraction of the upstream area remains unadjusted. Because the boundary of the adjusting part of the landscape changes over time, the longitudinal trend in cosmogenic nuclide‐derived erosion rates changes over time. These insights are then used to guide our interpretation of geomorphic and longitudinal cosmogenic nuclide data from the South Fork Eel River (SFER) in the California Coast Range (United States). The northward-propagating crustal thickening and rock uplift associated with the passage of the Mendocino triple junction generates a mobile wave of uplift that progressively sweeps longitudinally down the SFER. The consequences of this forcing can be both replicated in the model environment and observed in the fi eld. The SFER contains transient landforms including knickpoints and river terraces along mainstem and tributary channels that defi ne a clear boundary between an incised, adjusting lowland and an unadjusted, relict upland. We report nine nested, basin-wide denudation rates in the mainstem of the SFER using terrestrial cosmogenic 10 Be in river-borne sediment. We fi nd that denudation rates increase in the downstream direction from ~0.2 mm/yr in the upper catchment to ~0.5 mm/yr at the outlet. Using comparisons to the modeled landscape, we show that this pattern of denudation rates, paired with the distribution of relict topography throughout the watershed, refl ect the immaturity of the landscape’s transient adjustment. Later in this modeled transient, the predicted erosion rates decrease downstream before they become uniform. This interpretation of our data has potentially far-reaching implications for quantifying the uplift history and response time of transient landscapes using cosmogenic nuclides.

Published
2013

34. Constraining landscape history and glacial erosivity using paired cosmogenic nuclides in Upernavik, northwest Greenland

Author

Thomas Neumann, Paul R. Bierman, Joseph A. Graly, Dylan H. Rood, and Lee B. Corbett

Subjects
geography, geography.geographical_feature_category, Bedrock, Geology, Glacier, Arctic, Deglaciation, Physical geography, Glacial period, Cosmogenic nuclide, Quaternary, Geomorphology, Sea level
Abstract

High-latitude landscape evolution processes have the potential to preserve old, relict surfaces through burial by cold-based, nonerosive glacial ice. To investigate landscape history and age in the high Arctic, we analyzed in situ cosmogenic Be(sup 10) and Al (sup 26) in 33 rocks from Upernavik, northwest Greenland. We sampled adjacent bedrock-boulder pairs along a 100 km transect at elevations up to 1000 m above sea level. Bedrock samples gave significantly older apparent exposure ages than corresponding boulder samples, and minimum limiting ages increased with elevation. Two-isotope calculations Al(sup26)/B(sup 10) on 20 of the 33 samples yielded minimum limiting exposure durations up to 112 k.y., minimum limiting burial durations up to 900 k.y., and minimum limiting total histories up to 990 k.y. The prevalence of BE(sup 10) and Al(sup 26) inherited from previous periods of exposure, especially in bedrock samples at high elevation, indicates that these areas record long and complex surface exposure histories, including significant periods of burial with little subglacial erosion. The long total histories suggest that these high elevation surfaces were largely preserved beneath cold-based, nonerosive ice or snowfields for at least the latter half of the Quaternary. Because of high concentrations of inherited nuclides, only the six youngest boulder samples appear to record the timing of ice retreat. These six samples suggest deglaciation of the Upernavik coast at 11.3 +/- 0.5 ka (average +/- 1 standard deviation). There is no difference in deglaciation age along the 100 km sample transect, indicating that the ice-marginal position retreated rapidly at rates of approx.120 m yr(sup−1).

Published
2013

35. A cosmic trip: 25 years of cosmogenic nuclides in geology

Author

Darryl E. Granger, Jane K. Willenbring, and Nathaniel A. Lifton

Subjects
geography, geography.geographical_feature_category, Surface exposure dating, Denudation, Landform, Earth science, Geology, Weathering, Nuclide, Cosmogenic nuclide, Quaternary, Accelerator mass spectrometry
Abstract

Terrestrial cosmogenic nuclides, produced by secondary cosmic-ray interactions in the atmosphere and in situ within minerals in the shallow lithosphere, are widely used to date surface exposure of rocks and sediments, to estimate erosion and weathering rates, and to date sediment deposition or burial. Their use has transformed geomorphology and Quaternary geology, for the first time allowing landforms to be dated and denudation rates to be measured over soil-forming time scales. The application of cosmogenic nuclides to geology began soon after the invention of accelerator mass spectrometry (AMS) in 1977 and increased dramatically with the measurement of in situ–produced nuclides in mineral grains near Earth’s surface in the 1980s. The past 25 yr have witnessed the development of cosmogenic nuclides from their initial detection to their prevalence today as a standard geochronological and geochemical tool. This review covers the major developments of the past 25 yr by comparing the state of the field in 1988 with that of today, and by identifying key advances in that period that moved the field forward. We emphasize the most commonly used in situ–produced nuclides measured by AMS for geological applications, but we also discuss other nuclides where their applications overlap. Our review covers AMS instrumentation, cosmogenic nuclide production rates, the methods of surface exposure dating, measurement of erosion and weathering, and burial dating, and meteoric 10 Be. —In memoriam: Devendra Lal (1929–2012), whose vision inspired the field.

Published
2013

36. Strong rocks sustain ancient postorogenic topography in southern Africa

Author

Alexandru T. Codilean, Peter W. Kubik, Taryn E. Scharf, John D. Jansen, and Maarten J. de Wit

Subjects
geography, geography.geographical_feature_category, Bedrock, 550 - Earth sciences, Geology, Sedimentation, Thermochronology, Tectonics, Denudation, Submarine pipeline, Cosmogenic nuclide, Cenozoic, Geomorphology
Abstract

The Cape Mountains of southern Africa exhibit an alpine-like topography in conjunction with some of the lowest denudation rates in the world. This presents an exception to the often-cited coupling of topography and denudation rates and suggests that steep slopes alone are not sufficient to incite the high denudation rates with which they are commonly associated. Within the Cape Mountains, slope angles are often in excess of 30 degrees and relief frequently exceeds 1 km, yet Be-10-based catchment-averaged denudation rates vary between 2.32 +/- 0.29 m/m.y. and 7.95 +/- 0.90 m/m.y. We attribute the maintenance of rugged topography and suppression of denudation rates primarily to the presence of physically robust and chemically inert quartzites that constitute the backbone of the mountains. Be-10-based bedrock denudation rates on the interfluves of the mountains vary between 1.98 +/- 0.23 m/m.y. and 4.61 +/- 0.53 m/m.y. The close agreement between the rates of catchment-averaged and interfluve denudation indicates topography in steady state. These low denudation rates, in conjunction with the suggestion of geomorphic stability, are in agreement with the low denudation rates (

Published
2013

41. COMBINED USE OF COSMOGENIC NUCLIDE, U-SERIES DISEQUILIBRIUM, PALEOMAGNETISM, AND OPTICALLY STIMULATED LUMINESCENCE WITHIN FITTON CAVE TO EVALUATE THE LANDSCAPE EVOLUTION OF THE BUFFALO NATIONAL RIVER, ARKANSAS

Author

Amanda Keen-Zebert, James B. Paces, Darryl E. Granger, Chuck Bitting, and Mark R. Hudson

Subjects
Series (stratigraphy), Paleomagnetism, geography, geography.geographical_feature_category, Optically stimulated luminescence, Combined use, Disequilibrium, Geochemistry, Cave, medicine, Cosmogenic nuclide, medicine.symptom, Geomorphology, Geology
Published
2016

42. Debris-flow–dependent variation of cosmogenically derived catchment-wide denudation rates

Author

Peter W. Kubik, Kristina Hippe, Susan Ivy-Ochs, N. Hählen, Bernhard Salcher, Florian Kober, and Lukas Wacker

Subjects
Hydrology, geography, geography.geographical_feature_category, Drainage basin, Sediment, Geology, Atmospheric sciences, Debris, Debris flow, Denudation, Cosmogenic nuclide, Holocene, Colluvium
Abstract

Catchment-wide denudation rates (CWDRs) obtained from cosmogenic nuclides are an efficient way to determine geomorphic processes quantitatively in alpine mountain ranges over Holocene time scales. These rate estimations assume steady geomorphic processes. Here we use a time series (3 yr) in the Aare catchment (central Swiss Alps) to test the impact of spatially heterogeneous stochastic sediment supply on CWDRs. Our results show that low-frequency, high-magnitude debris-flow events significantly perturb cosmogenic nuclide ( 10 Be, 14 C) concentrations and thus CWDRs. The 10 Be concentrations decrease by a factor of two following debris-flow events, resulting in a doubling of inferred CWDRs. The variability indicates a clear time and source dependency on sediment supply, with restricted area-weighted mixing of sediment. Accordingly, in transient environments, it is critical to have an understanding of the history of geomorphic processes to derive meaningful CWDRs. We hypothesize that the size of debris flows, their connectivity with the trunk stream, and the ability of the system to sufficiently mix sediment from low- and high-order catchments control the magnitude of CWDR perturbations. We also determined in situ 14 C in a few samples. In conjunction with 10 Be, these data suggest partial storage for colluvium of a few thousand years within the catchment prior to debris-flow initiation.

Published
2012

43. Constant cosmogenic nuclide concentrations in sand supplied from the Nile River over the past 2.5 m.y

Author

Michael Davis, Dylan H. Rood, Simona Avnaim-Katav, and Ari Matmon

Subjects
geography, geography.geographical_feature_category, Pleistocene, Coastal plain, Geochemistry, Geology, Tectonics, Longshore drift, Aeolian processes, Nuclide, Cosmogenic nuclide, Quartz, Geomorphology
Abstract

Quartz sand in the eastern Mediterranean coastal plain is supplied through an extended transport system, which includes the Nile River, east Mediterranean longshore currents, and inland eolian transport. While the concentrations of cosmogenic nuclides ( 26 Al and 10 Be), and their ratio, in modern sand deposited along the coast of the eastern Mediterranean reflect the combined effect of exposure and burial during transport, the concentrations of these nuclides in buried sands are the result of decay of this initial dosing. Samples of modern exposed sand (n = 3) collected from the coastal plain of Israel yield an average 26 Al/ 10 Be ratio of 4.8 ± 0.2, significantly lower than the expected ratio of 6.8 for exposed quartz grains at the surface. A similar ratio of 4.5 ± 0.3 was measured in a late Pleistocene sand sample, indicating similar exposure-burial histories during transport in spite of the difference in climatic conditions. The results imply a steady, preburial cosmogenic nuclide ratio related to the Nile River9s ability, through storage and recycling, to buffer the effects of climatic and tectonic perturbations on cosmogenic nuclide concentrations in the transported quartz. All ancient and buried sand samples (n = 11) fall on a decay path that originates from the concentrations and ratio of 26 Al and 10 Be in modern sand, suggesting steady preburial concentrations of cosmogenic nuclides in quartz sand over the past 2.5 m.y.

Published
2012

44. Peneplain formation in southern Tibet predates the India-Asia collision and plateau uplift

Author

Dirk Frei, Ralf Hetzel, Vicky L. Haider, István Dunkl, Marcus Strobl, Lin Ding, and H. von Eynatten

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Bedrock, Geology, 15. Life on land, 010502 geochemistry & geophysics, Fission track dating, 01 natural sciences, Unconformity, Cretaceous, Thermochronology, Peneplain, Paleontology, 13. Climate action, Cosmogenic nuclide, 0105 earth and related environmental sciences, Zircon
Abstract

The uplift history of Tibet is crucial for understanding the geodynamic and paleoclimatologic evolution of Asia; however, it remains controversial whether Tibet attained its high elevation before or after India collided with Asia ∼50 m.y. ago. Here we use thermochronologic and cosmogenic nuclide data from a large bedrock peneplain in southern Tibet to shed light on the timing of the uplift. The studied peneplain, which was carved into Cretaceous granitoids and Jurassic metasediments, is located in the northern Lhasa block at an altitude of ∼5300 m. Thermal modeling based on (U-Th)/He ages of apatite and zircon, and apatite fission track data, indicate cooling and exhumation of the granitoids between ca. 70 and ca. 55 Ma, followed by a rapid decline in exhumation rate from ∼300 m/m.y. to ∼10 m/m.y. between ca. 55 and ca. 48 Ma. Since then, the peneplain has been a rather stable geomorphic feature, as indicated by low local and catchment-wide erosion rates of 6–11 m/m.y. and 11–16 m/m.y., respectively, which were derived from cosmogenic 10 Be concentrations in bedrock, grus, and stream sediment. The prolonged phase of erosion and planation that ended ca. 50 Ma removed 3–6 km of rock from the peneplain region, likely accomplished by laterally migrating rivers. The lack of equivalent sediments in the northern Lhasa block and the presence of a regional unconformity in the southern Lhasa block indicate that the rivers delivered this material to the ocean. This implies that erosion and peneplanation proceeded at low elevation until India9s collision with Asia induced crustal thickening, surface uplift, and long-term preservation of the peneplain.

Published
2011

45. Cosmogenic burial ages reveal sediment reservoir dynamics along the Yellow River, China

Author

Darryl E. Granger, Xiaofei Hu, Baotian Pan, Eric Kirby, and Huai Su

Subjects
geography, Provenance, geography.geographical_feature_category, Bedrock, fungi, Sediment, Fluvial, Geology, Sedimentary basin, Neogene, Paleontology, Terrace (geology), Cosmogenic nuclide
Abstract

Burial dating using cosmogenic Al-26 and Be-10 is an emerging technique for establishing chronologies of fluvial deposits ranging in age from ca. 0.5 Ma to 5 Ma. The determination of burial age, however, requires an assumption that sediment is buried with a known initial Al-26/Be-10 ratio. Using a sequence of well-dated fluvial terraces along the Yellow River in Lanzhou, China, we demonstrate that this assumption may be violated when upstream sediment sources include Neogene sedimentary basins. Samples of fluvial gravel from six terraces yield burial ages ranging from ca. 0.83 Ma to 2.81 Ma. Comparison of these results to independent ages determined from magneto stratigraphic and loess-paleosol studies demonstrates a high degree of correspondence between ages in the lower three terraces. In the higher terraces, however, burial ages are systematically too old, implying a previous burial history. These results can be exploited to place quantitative constraints on the provenance of sediment in the terrace deposits. Our results reveal that rapid incision and excavation of late Neogene sedimentary basins ca. 1.7 Ma led to injection of fluvial sediment with low initial Al-26/Be-10 ratios. Dilution of this source through time occurred as incision progressed into upstream bedrock ranges. Our results suggest that cosmogenic nuclides can illuminate the timing of long-term storage and remobilization of sediment in continental-scale river systems.

Published
2011

46. Rock avalanches and the pace of late Quaternary development of river valleys in the Karakoram Himalaya

Author

Kenneth Hewitt, John C. Gosse, and John J. Clague

Subjects
geography, geography.geographical_feature_category, Earth science, Bedrock, Geology, Landslide, Moraine, River terraces, Erosion, Glacial period, Cosmogenic nuclide, Quaternary, Geomorphology
Abstract

We discuss the implications of a set of terrestrial cosmogenic nuclide (TCN) ages on blocky, cross-valley deposits of large rock avalanches along upper Indus streams. The dated deposits are key to understanding late Quaternary events that play a major role in landscape evolution in the Karakoram Himalaya. The landslides occurred between 3 and 8 ka ago, challenging existing chronologies of events along Indus streams. The TCN ages may support a mid-Holocene climatic role in preparing slopes for failure, but the balance of evidence suggests that large earthquakes triggered the landslides. Each landslide dammed the Indus or a major tributary and controlled base level and sedimentation for millennia. They produced landforms long regarded as characteristic of the region, including extensive lacustrine deposits, flights of river terraces, epigenetic gorges, and sediment fans. Until the 1990s, most of the landslides were interpreted as moraines; related lacustrine and other sediments continue to be attributed to glacial damming, and stream terraces to tectonic processes. Generally they were seen to originate tens of thousands to hundreds of thousands of years earlier than the new ages require. Instead we argue that they record interactions among different geomorphic processes in landslide-fragmented valleys during the Holocene. Rather than being geomorphic markers of tectonic and climatic events, the landslides have buffered or redirected climatic and tectonic forcing. In such an active orogen, millennia-long episodes of zero net bedrock incision at each site are surprising. However, rates of sedimentation above landslide barriers and erosion controlled by their breaching are close to today9s high measured rates for geomorphic activity. We propose that landslide-fragmented rivers may, in fact, characterize interglaciations and future patterns of upper Indus landscape evolution at time scales of 10 3 to 10 4 years.

Published
2011

47. Cosmogenic nuclide and uranium-series dating of old, high shorelines in the western Great Basin, USA

Author

Joanna L. Redwine, James B. Paces, Marith C. Reheis, Gabrielle Kurth, and Fred M. Phillips

Subjects
Marine isotope stage, Paleontology, Pleistocene, law, Pluvial, Geology, Radiocarbon dating, Cosmogenic nuclide, Structural basin, Quaternary, Uranium-thorium dating, law.invention
Abstract

Closed-basin pluvial lakes are sensitive recorders of effective moisture, and they provide a terrestrial signal of climate change that can be compared to marine and ice records of glacial-interglacial cycles. Although the most recent deep-lake cycle in the western Great Basin (at ca. 16 ka) has been studied intensively, comparatively little is known about the longer-term Quaternary lacustrine history of the region. Lacustrine features higher than those of the most recent highstand have been discovered in many locations throughout the western Great Basin. Qualitative geomorphic and soil studies of shoreline sequences above the latest Pleistocene level suggest that their ages increase as a function of increasing altitude. The results of cosmogenic nuclide dating using chlorine-36 depth profiles from three sites in Nevada (Walker Lake, Columbus Salt Marsh, and Newark Valley), combined with uranium-series and radiocarbon ages, corroborate the geomorphic and soil evidence. The 36 Cl results are consistent with available 14 C ages and together indicate that the most recent highstands of all three lakes occurred ca. 20–15 ka, late in marine isotope stage (MIS) 2, as shown by previous ages. The 36 Cl ages indicate that older lakes in all three basins reached highstands between 100 and 50 ka, and most likely during MIS 4. Shorelines of this age are at about the same or higher altitudes as the younger, MIS 2 shorelines in those basins. The 36 Cl results combined with uranium-series ages and one tephra correlation obtained on shorelines higher in altitude than those of MIS 4 and 2 lakes suggest that there were also major lake highstands in the western Great Basin at ca. 100-200 ka, likely corresponding with MIS 6, and during at least two older periods. From these results, we conclude that the preserved shorelines show an apparent decrease in maximum levels with time, suggesting long-term drying of the region since the early middle Pleistocene.

Published
2010

48. Enigmatic boulder trains, supraglacial rock avalanches, and the origin of 'Darwin's boulders,' Tierra del Fuego

Author

Edward B. Evenson, Ian W. D. Dalziel, Andres Meglioli, Claudio Berti, Patrick A. Burkhart, Gregory S. Baker, Dan Jackofsky, John C. Gosse, Stefan Kraus, and Richard B. Alley

Subjects
geography, geography.geographical_feature_category, Geology, Crust, Glacier, Tierra, Petrography, Paleontology, Oceanography, Moraine, Glacial period, Cosmogenic nuclide, Ice rafting
Abstract

Charles Darwin considered himself to be a geologist and published extensively on many geologic phenomena. He was intrigued with the distribution of erratic boulders and speculated upon their origins. In his accounts of the voyage of the HMS Beagle, Darwin described crystalline boulders of notable size and abundance near Bahia San Sebastian, south of the Strait of Magellan, Tierra del Fuego. Influenced by Charles Lyell’s reflections upon slow, vertical movements of crust, submer gence, and ice rafting to explain drift, Darwin proposed that the boulders of Bahia San Sebastian were ice-rafted. Benefiting from 170 years of subsequent study of the glacial history of Tierra del Fuego, petrography, and terrestrial cosmogenic nuclide measurements, we revisit the origin of “Darwin’s Boulders” at Bahia San Sebastian. We suggest that they, as well as another train of boulders to the west, at Bahia Inutil, represent rock falls of Beagle-type granite from the Cordillera Darwin onto glacial ice flowing into the Bahia Inutil–Bahia San Sebas tian lobe. These supraglacial rock avalanche deposits were subsequently elongated into boulder trains by glacial strain during transport and then deposited upon moraines. The cosmogenic nuclide exposure dates support the correlation of Andean glaciations with the marine oxygen isotope record and the glacial chronologies recently proposed for Tierra del Fuego.

Published
2009

49. Orbital forcing of mid-latitude Southern Hemisphere glaciation since 100 ka inferred from cosmogenic nuclide ages of moraine boulders from the Cascade Plateau, southwest New Zealand

Author

Kyeong Ja Kim, Albert Zondervan, Rupert Sutherland, and Mauri McSaveney

Subjects
geography, Plateau, geography.geographical_feature_category, Orbital forcing, Sediment, Geology, Last Glacial Maximum, Paleontology, Moraine, Glacial period, Cosmogenic nuclide, Geomorphology, Southern Hemisphere
Abstract

Cosmogenic nuclide (Be-10) exposure dating of moraine boulders in the Cascade Valley, southwest New Zealand, reveals three phases of glaciation with similar maximum magnitude since 100 ka. In this area, 8–10 lateral moraines were deposited during the Last Glacial Maximum (LGM) at 22–19 ka, and >15 lateral moraines and three end moraines were deposited during recession after the LGM. Also, three exposure ages of 29–33 ka from pre-LGM deposits may indicate increased weathering and erosion at the onset of the LGM in New Zealand, as has been suggested by other studies. An exposure age of 57.8 ± 2.7 ka from one of the highest moraines, combined with previous studies of cave speleothems, glacial features offset by the Alpine fault, the Vostok dust record, and sediment cores, supports the inference that a significant glacial phase culminated at 66–58 ka. A cluster of five exposure ages from older moraines reveals a glacial phase with at least three advance-retreat cycles at 79.0 ± 3.9 ka. Correlation between the ages of glacial periods and the timing of Southern Hemisphere summer insolation minima suggests that orbital forcing has played a first-order role in regulating glacial extent in New Zealand.

Published
2007

50. Accelerator mass spectrometry in geologic research

Author

David Elmore, Paul Muzikar, and Darryl E. Granger

Subjects
Tectonics, Surface exposure dating, Earth science, accelerator mass spectrometry, cosmogenic nuclides, geochronology, surface-exposure dating, isotope geology, geomagnetic-field intensity, nuclide production-rates, bomb-produced cl-36, eastern baffin-island, situ cosmogenic c-14, in-situ, erosion rates, ion-source, sediment production, alluvial sediment, Geology, Nuclide, Cosmogenic nuclide, Alluvial sediment, Accelerator mass spectrometry, Hydrosphere
Abstract

The ability of accelerator mass spectrometry (AMS) to measure very small concentrations of the nuclides Be-10, C-14, Al-26, Cl-36, and I-129 has led to many innovative applications in geologic research. To take advantage of this opportunity in the geosciences, it is important to understand how AMS works, how these nuclides are produced, and how they can be applied to geologic problems. We first discuss the basics of AMS, explaining what gives the method its ability to count small numbers of these nuclides. We review how these nuclides are produced and transported in the atmosphere, hydrosphere, and lithosphere. We then explain the ways that AMS is being used to solve a wide range of problems in geologic research by discussing specific applications in areas such as geomorphology, tectonics, climatology, hydrology, and geochronology.

Published
2003

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