Early-Middle Pleistocene Beheading of the River Thames

Colin A. Whiteman; James Rose

doi:10.7202/033131ar

Early-Middle Pleistocene Beheading of the River Thames

Géographie physique et Quaternaire ◽

10.7202/033131ar ◽

2007 ◽

Vol 51 (3) ◽

pp. 327-336 ◽

Cited By ~ 7

Author(s):

Colin A. Whiteman ◽

James Rose

Keyword(s):

Climate Change ◽

Recent Work ◽

Landscape Evolution ◽

Middle Pleistocene ◽

Glacial Erosion ◽

Quaternary Period ◽

Quaternary Climate ◽

River Capture ◽

River Thames

ABSTRACT This paper marks the centenary of the first of three articles by W.M. Davis on the beheading of the Thames, beginning with a statement of his capture hypothesis in 1895 and concluding with attempts to explain anomalous misfit streams in 1899 and 1909. It discusses Davis's classic thesis of river capture by slow, long-term landscape evolution and his apparent reluctance to accept the fact of rapid Quaternary climate change. In contrast, recent work based on lithostratigraphy, biostratigraphy and morphostratigraphy emphasises the dynamism of the Quaternary Period and its influence on river capture. Possible mechanisms for the beheading of the Thames, tectonism, glacial erosion and conventional Davisian river capture, and the timing of the event, are discussed. In conclusion, the paper summarises known and unknown components of the problem of the beheading of the Thames, and discusses the extent of Davis's influence on later Thames studies.

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Introduction

The Phanerozoic Carbon Cycle ◽

10.1093/oso/9780195173338.003.0003 ◽

2004 ◽

Author(s):

Robert A. Berner

Keyword(s):

Climate Change ◽

Carbon Dioxide ◽

Carbon Cycle ◽

Global Climate ◽

Geological Time ◽

Short Term ◽

Quaternary Period ◽

Geological Time Scale ◽

The Earth

The cycle of carbon is essential to the maintenance of life, to climate, and to the composition of the atmosphere and oceans. What is normally thought of as the “carbon cycle” is the transfer of carbon between the atmosphere, the oceans, and life. This is not the subject of interest of this book. To understand this apparently confusing statement, it is necessary to separate the carbon cycle into two cycles: the short-term cycle and the long-term cycle. The “carbon cycle,” as most people understand it, is represented in figure 1.1. Carbon dioxide is taken up via photosynthesis by green plants on the continents or phytoplankton in the ocean. On land carbon is transferred to soils by the dropping of leaves, root growth, and respiration, the death of plants, and the development of soil biota. Land herbivores eat the plants, and carnivores eat the herbivores. In the oceans the phytoplankton are eaten by zooplankton that are in turn eaten by larger and larger organisms. The plants, plankton, and animals respire CO2. Upon death the plants and animals are decomposed by microorganisms with the ultimate production of CO2. Carbon dioxide is exchanged between the oceans and atmosphere, and dissolved organic matter is carried in solution by rivers from soils to the sea. This all constitutes the shortterm carbon cycle. The word “short-term” is used because the characteristic times for transferring carbon between reservoirs range from days to tens of thousands of years. Because the earth is more than four billion years old, this is short on a geological time scale. As the short-term cycle proceeds, concentrations of the two principal atmospheric gases, CO2 and CH4, can change as a result of perturbations of the cycle. Because these two are both greenhouse gases—in other words, they adsorb outgoing infrared radiation from the earth surface—changes in their concentrations can involve global warming and cooling over centuries and many millennia. Such changes have accompanied global climate change over the Quaternary period (past 2 million years), although other factors, such as variations in the receipt of solar radiation due to changes in characteristics of the earth’s orbit, have also contributed to climate change.

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Long-term landscape evolution of the Molise sector of the central-southern Apennines, Italy

Geologica Carpathica ◽

10.1515/geoca-2017-0003 ◽

2017 ◽

Vol 68 (1) ◽

pp. 29-42 ◽

Cited By ~ 9

Author(s):

Vincenzo Amato ◽

Pietro P.C. Aucelli ◽

Vito Bracone ◽

Massimo Cesarano ◽

Carmen Maria Rosskopf

Keyword(s):

Late Pleistocene ◽

Landscape Evolution ◽

Temporal Distribution ◽

Structural Data ◽

Early Pleistocene ◽

Middle Pleistocene ◽

Southern Apennines ◽

Geomorphological Evolution ◽

Present Setting

AbstractThis paper concerns the reconstruction of the main stages of the long-term landscape evolution of the Molise portion of the central-southern Apennines along a transect divided into three sectors (SW, Central and NE). Analysis mainly focused on geomorphological, stratigraphical and structural data supported by chronological constraints, coming from an overall review of past literature and several studies carried out by the authors of the paper during the last 20 years. The results obtained allowed the elaboration of a conceptual model of the long-term evolution of the Molise sector of the central-southern Apennines. Starting from the Pliocene, the emersion of the Molise area occurred gradually from SW to NE, allowing a polycyclic landscape to evolve under the major controls first of compression then transtensional to extensional tectonics as well as climatic variations. Principal markers of the Quaternary geomorphological evolution of the Molise area are represented by the infill successions of the intermontane tectonic depressions located in its internal, SW sector and by four orders of palaeosurfaces that developed between the Early Pleistocene and the beginning of the Late Pleistocene across the region. These markers testify to the alternation of phases of substantial tectonic stability and uplift whose spatial-temporal distribution could be assessed along the investigated transect. Results highlight that the most important stages of landscape evolution occurred during the Early and Middle Pleistocene. At the beginning of the Late Pleistocene, the Molise sector of the Apennine chain had already reached its present setting and further landscape evolution occurred under the major control of climate and land-use.

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Morphotectonic evidence for widespread active faulting in southern Mongolia

10.5194/egusphere-egu21-13578 ◽

2021 ◽

Author(s):

Jorien L.N. van der Wal ◽

Veit Nottebaum ◽

Georg Stauch ◽

Steven A. Binnie ◽

Ochirbat Batkhishig ◽

...

Keyword(s):

Seismic Reflection ◽

Landscape Evolution ◽

Fault System ◽

Middle Pleistocene ◽

Active Deformation ◽

Seismic Reflection Data ◽

Northern Margin ◽

Exposure Dating ◽

Reflection Data ◽

Quaternary Climate

<p>Four M~8 earthquakes in the 20<sup>th</sup> century reflect active deformation in western Mongolia as a result of far-field stresses related to the India-Eurasia collision. Historic seismicity indicates that deformation localises around the relatively rigid Hangay dome in central Mongolia, however, tectonic lineaments in the surrounding Valley of Lakes basins suggest more widespread and diffuse deformation. In southern Mongolia, seismicity clusters around the Bogd fault, which ruptured during the 1957 Mw 8.1 Gobi Altai earthquake. To determine whether the kinematics interpreted from this earthquake are regionally representative, especially in consideration of the heterogeneity of intraplate tectonics, we expand the spatial scale of tectonic studies to range between the Gobi Altai and Hangay massifs. We do this by combining observations from regional and local digital elevation models, ground-penetrating radar analyses, geological and geomorphological field data, and seismic reflection data. Additionally, we increase the temporal scale of palaeoseismic studies up until the Middle Pleistocene through OSL and surface exposure dating, to compare the effects of tectonic processes to those of Quaternary climate variations on landscape evolution. We show that reverse and oblique strands of the Bogd fault accommodate <0.3 mm/yr vertical slip rates along the northern margin of the transpressive Gobi Altai massif. Four ~E-W striking faults in the seismically quiescent Valley of Gobi Lakes each have the potential for M~7 earthquakes and they are likely part of a left-lateral strike-slip system rooted at depth. Although cumulatively, the Valley of Gobi Lakes faults are deforming at a regionally representative ~0.3 mm/yr vertical slip rate, recurrence intervals of major earthquakes are much longer than those determined along the Bogd fault (~5-80 ka vs. 3-5 ka). Overall, we interpret the Valley of Gobi Lakes faults to have played a large role in drainage reorganisation and Middle Pleistocene to modern landscape evolution. Sub-surface faults interpreted from seismic reflection data and associated geomorphological irregularities in the Orog Nuur Basin indicate two NW-SE striking lineaments that may connect the Valley of Gobi Lakes fault system to the Bogd fault system. Our observations suggest a more complex and extensive fault system in southern Mongolia than previously expected and the geometry and potential connectivity of faults indicates a continuing northward progression of transpressive deformation from the Gobi Altai towards the Hangay. The obscurity of active deformation in the Valley of Gobi Lakes is likely due to faster erosion and deposition rates and this highlights the importance of understanding the interplay between tectonic, climatic and geomorphological processes and their effects on the landscape system. We suggest that, especially in slowly deforming, intraplate regions, an increase of spatial and temporal scales of active tectonic research is necessary to improve interpretations of tectonically altered landforms, palaeo-environmental reconstructions, and seismic hazard assessments.</p>

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SEDIMENTOLOGICAL ANALYSIS OF THE STONEMAN LAKE, AZ, CORE: IMPLICATIONS FOR LONG-TERM QUATERNARY CLIMATE CHANGE IN THE SOUTHWEST

10.1130/abs/2017am-307055 ◽

2017 ◽

Author(s):

Spencer E. Staley ◽

◽

Peter J. Fawcett ◽

R. Scott Anderson ◽

Erik T. Brown ◽

...

Keyword(s):

Climate Change ◽

Quaternary Climate

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Using Single-Forcing GCM Simulations to Reconstruct and Interpret Quaternary Climate Change

Journal of Climate ◽

10.1175/jcli-d-15-0329.1 ◽

2015 ◽

Vol 28 (24) ◽

pp. 9746-9767 ◽

Cited By ~ 11

Author(s):

Michael P. Erb ◽

Charles S. Jackson ◽

Anthony J. Broccoli

Keyword(s):

Climate Change ◽

Greenhouse Gases ◽

Ice Sheets ◽

Meridional Overturning Circulation ◽

Climate Response ◽

Climate Variations ◽

Past Climate ◽

Quaternary Climate ◽

Temperature Records

Abstract The long-term climate variations of the Quaternary were primarily influenced by concurrent changes in Earth’s orbit, greenhouse gases, and ice sheets. However, because climate changes over the coming century will largely be driven by changes in greenhouse gases alone, it is important to better understand the separate contributions of each of these forcings in the past. To investigate this, idealized equilibrium simulations are conducted in which the climate is driven by separate changes in obliquity, precession, CO2, and ice sheets. To test the linearity of past climate change, anomalies from these single-forcing experiments are scaled and summed to compute linear reconstructions of past climate, which are then compared to mid-Holocene and last glacial maximum (LGM) snapshot simulations, where all forcings are applied together, as well as proxy climate records. This comparison shows that much of the climate response may be approximated as a linear response to forcings, while some features, such as modeled changes in sea ice and Atlantic meridional overturning circulation (AMOC), appear to be heavily influenced by nonlinearities. In regions where the linear reconstructions replicate the full-forcing experiments well, this analysis can help identify how each forcing contributes to the climate response. Monsoons at the mid-Holocene respond strongly to precession, while LGM monsoons are heavily influenced by the altered greenhouse gases and ice sheets. Contrary to previous studies, ice sheets produce pronounced tropical cooling at the LGM. Compared to proxy temperature records, the linear reconstructions replicate long-term changes well and also show which climate variations are not easily explained as direct responses to long-term forcings.

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Drainage rearrangement by river capture, beheading and diversion

Progress in Physical Geography Earth and Environment ◽

10.1177/030913339501900402 ◽

1995 ◽

Vol 19 (4) ◽

pp. 449-473 ◽

Cited By ~ 210

Author(s):

Paul Bishop

Keyword(s):

Landscape Evolution ◽

Rare Event ◽

Sediment Provenance ◽

Sediment Budgets ◽

Normal Part ◽

River Capture ◽

Stream Capture

Drainage rearrangement, involving stream piracy (capture), drainage diversion and/or beheading, may be significant for sediment budgets (including sediment provenance) and biotic distributions, as well as for its more usually considered role in landscape evolution. The processes involved in drainage rearrangement are not as self-evident as its abundant literature indicates. This is especially the case with the commonly invoked stream capture. The key process in stream capture, namely, drainage head retreat, is difficult to envisage as a normal part of drainage net evolution, especially in the light of recent findings on drainage hollow evolution. Stream capture may therefore be a relatively rare event in drainage net evolution. This, and uncertainties with interpretations of supposed elbows of capture, mean that stream capture should not be routinely invoked in interpretations of long-term drainage evolution. Further uncertainties associated with the maintenance of drainage lines during the erosion of significant crustal sections, especially in faulted and folded terrains, diminish the likelihood of many supposed examples of stream capture. It is more likely that examples of drainage rearrangement attributed to stream capture were generated by drainage diversion, but even this may involve special conditions.

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The (mis)conception of average Quaternary conditions

Quaternary Research ◽

10.1017/qua.2021.48 ◽

2021 ◽

pp. 1-6

Author(s):

Matteo Spagnolo ◽

Brice R. Rea ◽

Iestyn Barr

Keyword(s):

Landscape Evolution ◽

Middle Pleistocene ◽

Extreme Caution ◽

The Past ◽

Isotope Record ◽

Middle Pleistocene Transition ◽

Clear Change

Abstract The concept of Quaternary average conditions has gained popularity over the past few decades, especially with studies of long-term landscape evolution. In this paper, we critically assess this concept by analyzing the marine isotope record (LR04 δ18O stack) relative to the Quaternary. This shows that the frequency and amplitude of climate glacial-interglacial cycles are not constant throughout the Quaternary, with a clear change during the Middle Pleistocene Transition (MPT), and that many minor oscillations exist within each cycle. For this reason, the identification of pre- and post-MPT most-frequent and, cumulatively, longest-lasting (rather than average) conditions is recommended. The most-frequent pre-MPT δ18O value of 3.725 ± 0.025‰ last occurred during 11.31–11.47 ka, while the most-frequent post-MPT δ18O value of 4.475 ± 0.025‰ last occurred during 14.81–15.04 ka. However, many other δ18O values were almost as frequent throughout the Quaternary and we present geomorphological reasons as to why it is unlikely that the present-day landscape reflects Quaternary average or, indeed, most-frequent conditions. Collectively, our results indicate that extreme caution should be taken when attempting to infer long-term landscape evolution processes (including the buzzsaw hypothesis) based on average Quaternary conditions.

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Ancient Rivers and Critical Minerals in Eastern Alaska

Eos ◽

10.1029/2020eo147385 ◽

2020 ◽

Vol 101 ◽

Author(s):

Adrian Bender ◽

Richard Lease ◽

James Jones III ◽

Doug Kreiner

Keyword(s):

Climate Change ◽

Landscape Evolution ◽

Mineral Resources ◽

The Past ◽

River Capture ◽

History Of ◽

Critical Mineral ◽

Critical Minerals

Fieldwork is revealing a history of landscape evolution over the past 5 million years that links climate change and river capture to critical mineral resources across the Alaska-Yukon border.

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