10 research outputs found
Asynchronous glacier dynamics during the Antarctic Cold Reversal in central Patagonia
We present 14 new 10Be cosmogenic nuclide exposure ages quantifying asynchronous readvances during the Antarctic Cold Reversal from glaciers in the Baker Valley region of central Patagonia. We constrain glacier and ice-dammed palaeolake dynamics using a landsystems approach, concentrating on outlet glaciers from the eastern Northern Patagonian Icefield (NPI) and Monte San Lorenzo (MSL). Soler Glacier (NPI) produced lateral moraines above Lago Bertrand from 15.1 ± 0.7 to 14.0 ± 0.6 ka, when it dammed the drainage of Lago General Carrera/Buenos Aires through Río Baker at a bedrock pinning point. At this time, Soler Glacier terminated into the 400 m “Deseado” level of the ice-dammed palaeolake. Later, Calluqueo Glacier (MSL) deposited subaerial and subaqueous moraines in the Salto Valley near Cochrane at 13.0 ± 0.6 ka. These moraines were deposited in an ice-dammed palaeolake unified through the Baker Valley (Lago Chalenko; 350 m asl). The Salto Valley glaciolacustrine landsystem includes subaqueous morainal banks, ice-scoured bedrock, glacial diamicton plastered onto valley sides, perched delta terraces, kame terraces, ice-contact fans, palaeoshorelines and subaerial push and lateral moraines. Boulders from the subaqueous Salto Moraine became exposed at 12.1 ± 0.6 years, indicating palaeolake drainage. These data show an asynchronous advance of outlet glaciers from the Northern Patagonian Icefield and Monte San Lorenzo during the Antarctic Cold Reversal. These advances occurred during a period of regional climatic cooling, but differential moraine extent and timing of advance was controlled by topography and calving processes
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The micromorphology of glaciolacustrine varve sediments and their use for reconstructing palaeoglaciological and palaeoenvironmental change
Former glaciolacustrine systems are an important archive of palaeoglaciological, palaeoenvironmental and palaeoclimatic change. The annually laminated (varved) sediments that, under certain conditions, accumulate in former glacial lakes, offer a rare opportunity to reconstruct such changes (e.g. glacier advance and retreat cycles, glacier ablation trends, permafrost melt, nival events) at annual or even sub-annual temporal resolution. Data of this kind are desirable for their ability to guide and test numerical model simulations of glacier dynamics and palaeoclimatic change that occur over rapid time intervals, with implications for predicting future glacier response to climatic change, or the effects of weather and climate events on lake sedimentation. The most valuable records preserved in glaciolacustrine systems are continuous varved sequences formed in the distal parts of glacial lakes, where microscale lamination structures can accumulate relatively undisturbed. Technological advances, in the last few decades, have enabled improved characterisation of glaciolacustrine varve microfacies and the precise measurement of varve thickness at the micrometre scale. However, unlike in cognate fields (e.g. soil science), protocols for the robust and consistent description and interpretation of glaciolacustrine varve sediments are lacking. To fill this gap, and to provide a resource for future studies of glaciolacustrine varved sediments, this paper reviews the processes of sedimentation in glacial lake basins, and presents the defining microfacies characteristics of glacial varves using a descriptive protocol that uses consistent examination of grain size, sorting, structure, nature of contacts, development of plasmic fabrics and features such as dropgrains and intraclasts within individual laminations. These lamination types are then combined into lamination sets, whose structures can be interpreted as glaciolacustrine varves. Within this framework, we define five principal assemblages of glaciolacustrine varve microfacies which, if clearly identified in palaeoglaciolacustrine settings, enable more detailed palaeoenvironmental interpretations to be made. Finally, we discuss the utility and complexities of reconstructing the evolution of former glacial lake systems using varve microfacies and thickness datasets
The archaeology of tin mining on Dartmoor A sedimentary approach
SIGLEAvailable from British Library Document Supply Centre-DSC:DXN031803 / BLDSC - British Library Document Supply CentreGBUnited Kingdo
Human impact on fluvial regimes and sediment flux during the Holocene: review and future research agenda
There is a long history of human–riverine interactions throughout the period of agriculture that in some
regions of the world started several thousand years ago. These interactions have altered rivers to human
dominated systems with often negative impacts on fluvial environments. To achieve a good ecological and
chemical status of rivers, as intended in the European Water Framework Directive (WFD), a better
understanding of the natural status of rivers and an improved quantification of human–riverine interactions
is necessary. Over the last decade the PAGES-LUCIFS (Land Use and Climate Impact on Fluvial Systems)
program has been investigating both contemporary and long-term (centuries tomillennia) river responses to
global change with the principal aims of: 1) quantifying land use and climate change impacts of river-borne
fluxes of water, sediment, C, N and P; 2) identification of key controls on these fluxes at the catchment scale;
and 3) identification of the feedback on both human society and biogeochemical cycles of long-termchanges in
the fluxes of these materials. Here, we review recent progress on identifying fluvial system baselines and
quantifying the response of long-term sediment budgets, biogeochemical fluxes and flood magnitude and
frequency to Holocene global change. Based on this review, we outline the future LUCIFS research agenda
within the scope of the PAGES-PHAROS (Past Human-Climate-Ecological Interactions) research program. Key
research strategies should be focused on: 1) synthesising the data available from existing case studies;
2) targeting research in data-poor regions; 3) integrating sediment, C, N and P fluxes; 4) quantifying the
relative roles of allogenic and autogenic forcing on fluvial regimes, extreme events and sediment fluxes;
5) improving long-term river basin modelling; and 6) integration of LUCIFS with other research communities
within PHAROS, namely HITE (land cover) and LIMPACS (water quality and biodiversity).status: publishe
Hydrological response of a dryland ephemeral river to southern African climatic variability during the last millennium
A long-term flood record from the Buffels River, the largest ephemeral river of NW South Africa (9250 km2), was reconstructed based on interpretation of palaeoflood, documentary and instrumental rainfall data. Palaeoflood data were obtained at three study reaches, with preserved sedimentary evidence indicating at least 25 large floods during the last 700yr. Geochronological control for the palaeoflood record was provided by radiocarbon and optically stimulated luminescence (OSL) dating. Annual resolution was obtained since the 19th century using the overlapping documentary and instrumental records. Large floods coincided in the past within three main hydroclimatic settings: (1) periods of regular large flood occurrence (1 large flood/~30yr) under wetter and cooler prevailing climatic conditions (AD 1600-1800), (2) decreasing occurrence of large floods (1 large flood/~100yr) during warmer conditions (e.g., AD 1425-1600 and after 1925), and (3) periods of high frequency of large floods (~4-5 large floods in 20-30yr) coinciding with wetter conditions of decadal duration, namely at AD 1390-1425, 1800-1825 and 1915-1925. These decadal-scale periods of the highest flood frequency seem to correspond in time with changes in atmospheric circulation patterns, as inferred when comparing their onset and distribution with temperature proxies in southern Africa. © 2011 University of Washington
The Geomorphology of The Anthropocene: Emergence, Status and Implications
The Anthropocene is proposed as a new interval of geological time in which human influence on Earth and its geological record dominates over natural processes. A major challenge in demarcating the Anthropocene is that the balance between human-influenced and natural processes varies over spatial and temporal scales owing to the inherent variability of both human activities (as associated with culture and modes of development) and natural drivers (e.g. tectonic activity and sea level variation). Against this backdrop, we consider how geomorphology might contribute towards the Anthropocene debate focussing on human impact on aeolian, fluvial, cryospheric and coastal process domains, and how evidence of this impact is preserved in landforms and sedimentary records. We also consider the evidence for an explicitly anthropogenic geomorphology that includes artificial slopes and other human-created landforms. This provides the basis for discussing the theoretical and practical contributions that geomorphology can make to defining an Anthropocene stratigraphy. It is clear that the relevance of the Anthropocene concept varies considerably amongst different branches of geomorphology, depending on the history of human actions in different process domains. For example, evidence of human dominance is more widespread in fluvial and coastal records than in aeolian and cryospheric records, so geomorphologically the Anthropocene would inevitably comprise a highly diachronous lower boundary. Even to identify this lower boundary, research would need to focus on the disambiguation of human effects on geomorphological and sedimentological signatures. This would require robust data, derived from a combination of modelling and new empirical work rather than an arbitrary ‘war of possible boundaries’ associated with convenient, but disputed, `golden spikes’. Rather than being drawn into stratigraphical debates, the primary concern of geomorphology should be with the investigation of processes and landform development, so providing the underpinning science for the study of this time of critical geological transition