The evolution of western Scandinavian topography: A review of Neogene uplift versus the ICE (isostasy–climate–erosion) hypothesis

Nielsen, Søren B.; Gallagher, Kerry; Leighton, Callum; Balling, Niels; Svenningsen, L.; Jacobsen, Bo Holm; Thomsen, Erik; Nielsen, Ole Bækgaard; Heilmann‐Clausen, Claus; Egholm, David Lundbek; Summerfield, Michael A.; Clausen, Ole Rønø; Piotrowski, Jan A.; Thorsen, Marianne R.; Huuse, Mads; Abrahamsen, Niels; King, Chris; Lykke‐Andersen, Holger

doi:10.1016/j.jog.2008.09.001

Cited by 176 publications

(226 citation statements)

References 111 publications

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“…The role of continued regional and local tectonic activity into the late Cenozoic is still debated. Most evidence favours a model of passive thermal subsidence enhanced by sediment loading in the central North Sea and marginal uplift owing to denudation and unloading of the Norwegian landmass (Huuse 2002;Nielsen et al 2009;Anell et al 2010;Goledowski et al 2012).…”

Section: Regional Settingmentioning

confidence: 82%

The early Quaternary North Sea Basin

Lamb

Harding

Huuse

et al. 2017

JGS

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The onset of the Quaternary (2.58 Ma) corresponds to significant paleo-environmental events, such as the intensification and southward extension of Northern Hemisphere glaciation. In the North Sea Basin a significant late Cenozoic succession has been identified as a high-resolution archive of paleo-environmental changes during the Pliocene and Pleistocene. However, the identification of the base of the Quaternary has been a long-standing issue owing to lack of stratigraphic calibration. This study incorporates continuous, regional 3D seismic data with high-quality chronostratigraphic markers to map the base-Quaternary surface at high resolution across the entire North Sea. Depth conversion, backstripping, seismic geomorphology and sedimentation rate calculations are integrated to analyse the paleogeographical evolution of the North Sea Basin and its infill of c. 83 × 10 3 km 3 of northward prograding marine to deltaic sediments. The basin is 600 km long from SSE to NNW and largely localized above residual topography of the Mesozoic graben system. During the earliest Quaternary (2.58 -2.35 Ma) paleo-water depths were c. 300 ± 50 m and solid sedimentation rates (calculated from 0% porosity) c. 32 km 3 ka −1 . The base-Quaternary provides an important marker for further studies of the changing environment of the Quaternary of NW Europe as well as resource and shallow geohazard analysis.Supplementary material: A base Quaternary two-way travel time structure map is available at https://doi.org/10.6084/m9. figshare.c.3900343

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Section: Regional Settingmentioning

confidence: 82%

The early Quaternary North Sea Basin

Lamb

Harding

Huuse

et al. 2017

JGS

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“…Low-relief areas at high elevations have been traditionally interpreted as evidence for accelerated rock uplift following peneplanation at base level (Lidmar-Bergström et al, 2000;Japsen et al, 2009). Our experiments provide a viable alternative: low-relief areas may develop more or less in situ via mechanisms unrelated to either base level or tectonism (Anderson, 2002;Nielsen et al, 2009;Steer et al, 2012). Whether high summit flats in the mountains of Norway and Greenland are uplifted remnants of peneplains (LidmarBergström et al, 2000;Japsen et al, 2009, e.g.…”

Section: Implications For Glaciated Passive Continental Marginsmentioning

confidence: 86%

“…Small and Anderson, 1998;Anderson, 2002;Anderson et al, 2006;Munroe, 2006) and the Caledonian mountains in Scotland, Scandinavia, and Greenland (e.g. Rea et al, 1996;Fabel et al, 2002;Phillips et al, 2006;Nielsen et al, 2009;Goodfellow, 2012). Summit flats are typically mantled thinly with regolith that is widely held to be the product of frost-driven physical weathering (Anderson, 2002;Ballantyne, 2010;Goodfellow, 2012), although there is disagreement concerning the timing of their formation, the contribution of chemical weathering, and relationships to climate (Rea et al, 1996;Whalley et al, 2004;Strømsøe and Paasche, 2011;Goodfellow, 2012).…”

Section: Introductionmentioning

confidence: 99%

“…Recent studies of the Norwegian mountains suggest that, although characterised by low erosional activity during recent glacial cycles, high-elevation, low-relief areas may have contributed notable sediment volumes to offshore basins over the last 2.8 Myr (Steer et al, 2012). It seems that accounting for the long-term development of the summit flats requires the processes at play to be integrated throughout the Quaternary period, and possibly even further back because periglacial erosion may have been active several million years before glaciers were introduced into the landscape (Nielsen et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

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The periglacial engine of mountain erosion – Part 2: Modelling large-scale landscape evolution

et al. 2015

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Abstract. There is growing recognition of strong periglacial control on bedrock erosion in mountain landscapes, including the shaping of low-relief surfaces at high elevations (summit flats). But, as yet, the hypothesis that frost action was crucial to the assumed Late Cenozoic rise in erosion rates remains compelling and untested. Here we present a landscape evolution model incorporating two key periglacial processes -regolith production via frost cracking and sediment transport via frost creep -which together are harnessed to variations in temperature and the evolving thickness of sediment cover. Our computational experiments time-integrate the contribution of frost action to shaping mountain topography over million-year timescales, with the primary and highly reproducible outcome being the development of flattish or gently convex summit flats. A simple scaling of temperature to marine δ 18 O records spanning the past 14 Myr indicates that the highest summit flats in mid-to high-latitude mountains may have formed via frost action prior to the Quaternary. We suggest that deep cooling in the Quaternary accelerated mechanical weathering globally by significantly expanding the area subject to frost. Further, the inclusion of subglacial erosion alongside periglacial processes in our computational experiments points to alpine glaciers increasing the long-term efficiency of frost-driven erosion by steepening hillslopes.

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“…Nielsen et al 2008). In west Greenland, Japsen et al (2006) describe three separate phases of uplift: broadly Oligocene (36-30 Ma), Miocene (11 Ma) and Pliocene (7-2 Ma), all clearly post-dating the classical rift shoulder-related uplift in the Eocene.…”

Section: Subtle Migration Pathsmentioning

confidence: 96%

Passive margins: overview

Levell

Argent

Doré³

et al. 2010

PGC

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Passive margins have been the reliable, accessible mainstay of exploration success worldwide for the last 25 years, and have hosted the spectacularly fast exploitation of deepwater resources (Angola, Nigeria, Brazil, Trinidad, USA Gulf of Mexico, Egypt, Australia and India). Despite, or perhaps because of this, there is still much to learn about the variety of hydrocarbon habitats they present.For example: (1) deep seismic observations and deep sea drilling have revealed more of the diversity of passive margins geodynamics. This liberates explorationists from simple geodynamic models, with consequences not only for new views of thermal history but also for the whole tectonic and stratigraphic evolution. For example, the time significance assigned to the geometries traditionally labelled 'pre-rift, syn-rift and sag' may be misleading. This has implications for correlations, the significance assigned to unconformities and sequence boundaries, heat flow and structural history. (2) New deep imaging of the sedimentary sections has revealed mistaken assumptions about the importance of 'mobile substrate' in major deltas and allowed the detailed unravelling of salt and shale movement and its implications for reservoir and trap. (3) Depositional models for deepwater reservoirs have increased in predictive capability and modern seismic imaging supports new models for shallow water sequences. (4) Discoveries of very large amounts of dry bacterial methane in stratigraphic traps have challenged old assumptions about prospectivity based on thermally matured source rocks. (5) New engineering and development technologies are opening up the commercialization of remote frontiers. As a consequence there is legitimate scope to re-visit old 'dogmas' and to propose that each passive margin segment is best regarded as unique, with analysis and interpretation rooted in observation rather than models (at least while the newly proposed models evolve to stability). Many of these themes were visited in the Passive Margins session of the Seventh Petroleum Geology Conference, held in London in 2009. This paper outlines some of these ideas, and considers how exploration along passive margins in the next decade can use new geoscience thinking.

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The evolution of western Scandinavian topography: A review of Neogene uplift versus the ICE (isostasy–climate–erosion) hypothesis

Cited by 176 publications

References 111 publications

The early Quaternary North Sea Basin

The early Quaternary North Sea Basin

The periglacial engine of mountain erosion – Part 2: Modelling large-scale landscape evolution

Passive margins: overview

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