scholarly journals Early Holocene sea-level changes in Øresund, southern Scandinavia

1969 ◽  
Vol 26 ◽  
pp. 29-32
Author(s):  
Ole Bennike ◽  
Martin Skov Andreasen ◽  
Jørn Bo Jensen ◽  
Matthias Moros ◽  
Nanna Noe-Nygaard
Keyword(s):  
Sea Level ◽  
Sediment Cores ◽  
Early Holocene ◽  
Sea Level Changes ◽  
Relative Sea Level ◽  
Data Set ◽  
The North ◽  
Global Sea Level ◽  
The Baltic ◽  
Water Depths

The Baltic Sea and Kattegat are connected via three straits: Storebælt, Lillebælt and Øresund (Fig. 1). Øresund is the shallowest with a threshold around 7 m deep and increasing water depths to the north (Fig. 2). In the early Holocene, global sea-level rise led to reflooding of Øresund. It started in northern Øresund which was transformed into a fjord. However, so far the timing of the transgression has not been well determined, but sediment cores collected north of the threshold, at water depths of 12 to 20 m, and a new series of radiocarbon ages help to constrain this. As the relative sea level continued to rise, the threshold in Øresund was also flooded, and Øresund became a strait. In mid-Holocene time, the relative sea level rose until it was 4–5 m higher than at present, and low-lying areas around Øresund became small fjords. During the late Holocene, the relative sea level fell again. Part of the data set discussed here was presented by Andreasen (2005).

Saltmarshes in a time of change

2002 ◽  
Vol 29 (1) ◽  
pp. 39-61 ◽  
Author(s):  
Paul Adam
Keyword(s):  
Sea Level ◽  
Native Species ◽  
Rate Of Change ◽  
Tidal Range ◽  
Direct Result ◽  
Sea Level Changes ◽  
Ecological Value ◽  
Relative Sea Level ◽  
Global Sea Level ◽  
The Tropics

Saltmarshes are a major, widely distributed, intertidal habitat. They are dynamic systems, responding to changing environmental conditions. For centuries, saltmarshes have been subject to modification or destruction because of human activity. In this review, the range of factors influencing the survival of saltmarshes is discussed. Of critical importance are changes in relative sea level and in tidal range. Relative sea level is affected by changes in absolute sea level, changes in land level and the capacity of saltmarshes to accumulate and retain sediment. Many saltmarshes are starved of sediment because of catchment modification and coastal engineering, or exposed to erosive forces, which may be of natural origin or reflect human interference. The geographical distribution of individual saltmarsh species reflects climate, so that global climatic change will be reflected by changes in distribution and abundance of species, although the rate of change in communities dominated by perennial plants is difficult to predict. Humans have the ability to create impacts on saltmarshes at a range of scales from individual sites to globally. Pressures on the environment created by the continued increase in the human population, particularly in developing tropical countries, and the likely consequences of the enhanced greenhouse effect on both temperature and sea level give rise to particular concerns. Given the concentration of population growth and development in the coastal zone, and the potential sensitivity of saltmarsh to change in sea level, it is timely to review the present state of saltmarshes and to assess the likelihood of changes in the near (25 years) future. By 2025, global sea level rise and warming will have impacts on saltmarshes. However, the most extensive changes are likely to be the direct result of human actions at local or regional scales. Despite increasing recognition of the ecological value of saltmarsh, major projects involving loss of saltmarshes but deemed to be in the public interest will be approved. Pressures are likely to be particularly severe in the tropics, where very little is known about saltmarshes. At the local scale the cumulative impacts of activities, which individually have minor effects, may be considerable. Managers of saltmarshes will be faced with difficult choices including questions as to whether traditional uses should be retained, whether invasive alien species or native species increasing in abundance should be controlled, whether planned retreat is an appropriate response to rising relative sea level or whether measures can be taken to reduce erosion. Decisions will need to take into account social and economic as well as ecological concerns.

Holocene relative sea levels and coastal changes in the lower Cree valley and estuary, SW Scotland, U.K.

2002 ◽  
Vol 93 (4) ◽  
pp. 301-331 ◽  
Author(s):  
D. E. Smith ◽  
J. M. Wells ◽  
T. M. Mighall ◽  
R. A. Cullingford ◽  
L. K. Holloway ◽  
...  
Keyword(s):  
Sea Level ◽  
Early Holocene ◽  
Coastal Geomorphology ◽  
Sea Level Changes ◽  
Relative Sea Level ◽  
Sea Levels ◽  
Coastal Changes

ABSTRACTChanges in Holocene (Flandrian) relative sea levels and coastal geomorphology in the lower Cree valley and estuary, SW Scotland, are inferred from detailed morphological and stratigraphical investigations. A graph of relative sea level changes is proposed for the area. Rising relative sea levels during the early Holocene were interrupted at c. 8300–8600 14C years B.P.(c. 9400–9900 calibrated years B.P.), when an extensive estuarine surface was reached at c. −1 m O.D., after which a fluctuating rise culminated at c. 6100–6500 14C B.P. (c. 7000–7500 calibrated years B.P.) in a prominent shoreline and associated estuarine surface measured at 7·7–10·3 m O.D. A subsequent fall in relative sea level was followed by a rise to a shoreline at 7·8–10·1 m O.D., exceeding or reoccupying the earlier shoreline over much of the area after c. 5000 14C B.P. (c. 5,800 calibrated years B.P.), before relative sea level fell to a later shoreline, reached after c. 2900 14C B.P. (c. 3100 calibrated years B.P.) at 5·5–8·0 m O.D., following which relative sea levels fell, ultimately reaching present levels. During these changes, a particular feature of the coastline was the development of a number of barrier systems. The relative sea level changes identified are compared with changes elsewhere in SW Scotland and their wider context is briefly considered.

scholarly journals Past and Future Sea Level Changes and Land Uplift in the Baltic Sea Seen by Geodetic Observations

2020 ◽  
Author(s):  
M. Nordman ◽  
A. Peltola ◽  
M. Bilker-Koivula ◽  
S. Lahtinen
Keyword(s):  
Time Series ◽  
Baltic Sea ◽  
Sea Level Rise ◽  
Sea Level ◽  
Sea Level Changes ◽  
The Baltic Sea ◽  
Relative Sea Level ◽  
Land Uplift ◽  
Considerable Uncertainty ◽  
The Baltic

Abstract We have studied the land uplift and relative sea level changes in the Baltic Sea in northern Europe. To observe the past changes and land uplift, we have used continuous GNSS time series, campaign-wise absolute gravity measurements and continuous tide gauge time series. To predict the future, we have used probabilistic future scenarios tuned for the Baltic Sea. The area we are interested in is Kvarken archipelago in Finland and High Coast in Sweden. These areas form a UNESCO World Heritage Site, where the land uplift process and how it demonstrates itself are the main values. We provide here the latest numbers of land uplift for the area, the current rates from geodetic observations, and probabilistic scenarios for future relative sea level rise. The maximum land uplift rates in Fennoscandia are in the Bothnian Bay of the Baltic Sea, where the maximum values are currently on the order of 10 mm/year with respect to the geoid. During the last 100 years, the land has risen from the sea by approximately 80 cm in this area. Estimates of future relative sea level change have considerable uncertainty, with values for the year 2100 ranging from 75 cm of sea level fall (land emergence) to 30 cm of sea-level rise.

scholarly journals Developing detailed records of relative sea-level change using a foraminiferal transfer function: an example from North Norfolk, UK

2006 ◽  
Vol 364 (1841) ◽  
pp. 973-991 ◽  
Author(s):  
Robin J Edwards ◽  
B.P Horton
Keyword(s):  
Transfer Function ◽  
Sea Level ◽  
Transfer Functions ◽  
Sediment Cores ◽  
Sea Level Change ◽  
Relative Sea Level ◽  
Level Change ◽  
The North ◽  
Level Information ◽  
Coastal Deposits

This paper provides a brief overview of the transfer function approach to sea-level reconstruction. Using the example of two overlapping sediment cores from the North Norfolk coast, UK, the advantages and limitations of the transfer function methodology are examined. While the selected cores are taken from different sites, and display contrasting patterns of sedimentation, the foraminiferal transfer function distils comparable records of relative sea-level change from both sequences. These reconstructions are consistent with existing sea-level index points from the region but produce a more detailed record of relative sea-level change. Transfer functions can extract sea-level information from a wider range of sedimentary sub-environments. This increases the amount of data that can be collected from coastal deposits and improves record resolution. The replicability of the transfer function methodology, coupled with the sequential nature of the data it produces, assists in the compilation and analysis of sea-level records from different sites. This technique has the potential to bridge the gap between short-term (instrumental) and long-term (geological or geophysical) records of sea-level change.

scholarly journals Postglacial, relative shore-level changes in Lillebælt, Denmark

1969 ◽  
Vol 23 ◽  
pp. 37-40 ◽  
Author(s):  
Ole Bennike ◽  
Jørn Bo Jensen
Keyword(s):  
Mass Spectrometry ◽  
Baltic Sea ◽  
Sea Level ◽  
Lake Level ◽  
Sea Level Changes ◽  
The Baltic Sea ◽  
Shore Level ◽  
History Of ◽  
The Baltic ◽  
Water Depths

The brackish Baltic Sea and the more saline Kattegat are connected by three straits, Lillebælt, Storebælt and Øresund (Fig. 1). Of the three straits, Lillebælt is the narrowest, with 700 m at its narrowest point, widening out towards the south to around 25 km (Fig. 2). In the narrow parts of Lillebælt, water depths around 30–50 m are common. In the northern part of Lillebælt the depth is 16–18 m and in the southern part the depth is around 35 m. Storebælt and Øresund have played important roles as outlets during the history of the Baltic Sea, and their histories have been much discussed (Björck 1995; Bennike et al. 2004). In contrast, Lillebælt has received little attention. In this paper we present 11 new radiocarbon accelerator mass spectrometry (AMS) ages and propose a curve for Holocene relative shore-level changes in Lillebælt. We use the term shore-level changes rather than sea-level changes because we have constructed both lake-level and sea-level changes.

scholarly journals Depositional environment of the Branch Sandstone and correlative sequences: Late Cretaceous changes in relative sea level in the East Coast Basin of New Zealand

2021 ◽  
Author(s):  
◽  
Lisa McCarthy
Keyword(s):  
Sea Level ◽  
East Coast ◽  
Depositional Environments ◽  
Passive Margin ◽  
Sea Level Changes ◽  
Relative Sea Level ◽  
Sea Level Fluctuations ◽  
The North ◽  
Tasman Sea ◽  
History Of

<p>The Branch Sandstone is located within an overall transgressive, marine sedimentary succession in Marlborough, on the East Coast of New Zealand’s South Island. It has previously been interpreted as an anomalous sedimentary unit that was inferred to indicate abrupt and dramatic shallowing. The development of a presumed short-lived regressive deposit was thought to reflect a change in relative sea level, which had significant implications for the geological history of the Marlborough region, and regionally for the East Coast Basin.  The distribution and lithology of Branch Sandstone is described in detail from outcrop studies at Branch Stream, and through the compilation of existing regional data. Two approximately correlative sections from the East Coast of the North Island (Tangaruhe Stream and Angora Stream) are also examined to provide regional context. Depositional environments were interpreted using sedimentology and palynology, and age control was developed from dinoflagellate biostratigraphy. Data derived from these methods were combined with the work of previous authors to establish depositional models for each section which were then interpreted in the context of relative sea level fluctuations.  At Branch Stream, Branch Sandstone is interpreted as a shelfal marine sandstone, that disconformably overlies Herring Formation. The Branch Sandstone is interpreted as a more distal deposit than uppermost Herring Formation, whilst the disconformity is suggested to have developed during a fall in relative sea level. At Branch Stream, higher frequency tectonic or eustatic sea-level changes can therefore be distinguished within a passive margin sedimentary sequence, where sedimentation broadly reflects subsidence following rifting of the Tasman Sea. Development of a long-lived disconformity at Tangaruhe Stream and deposition of sediment gravity flow deposits at Angora Stream occurred at similar times to the fall in relative sea level documented at the top of the Herring Formation at Branch Stream. These features may reflect a basin-wide relative sea-level event, that coincides with global records of eustatic sea level fall.</p>

scholarly journals Postglacial rebound and relative sea level changes in the Baltic Sea since the Litorina transgression

Baltica ◽  
2012 ◽  
Vol 25 (2) ◽  
pp. 113-120 ◽  
Author(s):  
Alar Rosentau ◽  
Jan Harff ◽  
Michael Meyer ◽  
Tõnis Oja
Keyword(s):  
Baltic Sea ◽  
Sea Level ◽  
Sea Level Changes ◽  
The Baltic Sea ◽  
Postglacial Rebound ◽  
Relative Sea Level ◽  
The Baltic

scholarly journals The Geology of the Bras d'Or Lakes, Nova Scotia

2002 ◽  
Vol 42 (1) ◽  
Author(s):  
J. Shaw ◽  
D.J.W. Piper ◽  
R.B. Taylor
Keyword(s):  
Sea Level ◽  
Sediment Cores ◽  
Early Holocene ◽  
Multibeam Bathymetry ◽  
Eastern Cape ◽  
River Channels ◽  
Relative Sea Level ◽  
Il Y A ◽  
Ice Retreat ◽  
Seismic Reflection Profiles

The evolution of the Bras d’Or Lakes since the retreat of the last ice sheets c. 15 ka (thousands of radiocarbon years before present, where present is defined as 1950) is inferred from multibeam bathymetry, seismic reflection profiles, and sediment cores. The thickness of stratified sediment in the Lakes overlying glacial till shows that there was a step-like retreat of ice towards a late ice centre in the western part of the Bras d’Or Lakes. As ice retreated, a lake formed in the area of the modern Bras d’Or Lakes and probably drained through Little Bras d’Or Channel. Ice retreat and sea level change on the continental shelf off south-eastern Cape Breton are inferred from multibeam bathymetry that shows proglacial subaerial river channels and suggests that sea level was perhaps 50 m lower than present about 15 ka. Relative sea level appears to have risen subsequently, so that marine conditions existed in Bras d’Or Lakes basin at 10 to 9 ka. Sea level may have risen to -15 m (below modern sea level)before falling again in the early Holocene. This falling early Holocene relative sea level resulted in the creation of freshwater lakes, with a prominent erosion surface at -25 m marking the lake level in some areas. Rising sea level then resulted in a return to marine conditions in the Lakes by 4 to 5 ka. L’évolution des lacs Bras d’Or depuis le retrait des dernières nappes glaciaires il y a 15 000 ans se révèle par la bathymétrie multifaisceaux, les profils de réflexion sismique et les carottes de sédiments. L’épaisseur des sédiments stratifiés dans le till sus-jacent des lacs démontre qu’il y a eu un retrait en escaliers des glaces vers un centre fini-glaciaire situé dans la partie occidentale des lacs Bras d’Or. Les eaux, libérées lors du retrait des glaces, s’échappèrent probablement via le canal du Little Bras d’Or pour former un lac dans le lit actuel des lacs Bras d’Or. Le retrait des glaces et les changements du niveau de la mer sur la plateforme continentale au sud-est de Cap-Breton sont mis en évidence par la bathymétrie multifaisceaux, qui montre des lits de rivière sub-aériens proglaciaires et indiqueque le niveau de la mer se trouvait peut-être à 50 m plus bas qu’aujourd’hui il y a environ 15 milles d’années. La hausse du niveau de la mer depuis cette époque a provoqué l’inondation des lacs Bras d’Or ancestraux il y a de 9 à 10 milles d’années, et le niveau des eaux aurait atteint -15 m avant de chuter au début de l’Holocène. Cette chute relative du début de l’Holocène a résulté en la création de lacs pour une seconde fois, avec une importante surface d’érosion à -25 m qui marque le niveau des eaux dans certaines zones. Ces lacs ont été finalement inondés par la mer il y a de 4 à 5 milles d’années.

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