LAND MAMMAL HIGH-RESOLUTION GEOCHRONOLOGY, INTERCONTINENTAL OVERLAND DISPERSALS, SEA LEVEL, CLIMATE, AND VICARIANCE

The Lower Ordovician St. George Group of western Newfoundland consists mainly of shallow-marine-platform carbonates (∼500 m thick). It is formed, from bottom to top, of the Watts Bight, Boat Harbour, Catoche, and Aguathuna formations. The top boundary of the group is marked by the regional St. George Unconformity. Outcrops and a few cores from western Newfoundland were sampled at high resolution and the extracted micritic materials were investigated for their petrographic and geochemical criteria to evaluate their degree of preservation. The δ13C and δ18O values of well-preserved micrite microsamples range from –4.2‰ to 0‰ (VPDB) and from –11.3‰ to –2.9‰ (VPDB), respectively. The δ13Ccarb profile of the St. George Group carbonates reveals several negative shifts, which vary between ∼2‰ and 3‰ and are generally associated with unconformities–disconformities or thin shale interbeds, thus reflecting the effect of or link with significant sea-level changes. The St. George Unconformity is associated with a negative δ13Ccarb shift (∼2‰) on the profile and correlated with major lowstand (around the end of Arenig) on the local sea-level reconstruction and also on those from the Baltic region and central Australia, thus suggesting that the St. George Group Unconformity might have likely had an eustatic component that contributed to the development–enhancement of the paleomargin. Other similar δ13Ccarb shifts have been recorded on the St. George profile, but it is hard to evaluate their global extension due to the low resolution of the documented global Lower Ordovician (Tremadoc – middle Arenig) δ13Ccarb profile.

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Present and future mass balance of the ice sheets simulated with GCM

Annals of Glaciology ◽

10.1017/s0260305500013434 ◽

1996 ◽

Vol 23 ◽

pp. 187-193 ◽

Cited By ~ 9

Author(s):

Atsumu Ohmura ◽

Martin Wild ◽

Lennart Bengtsson

Keyword(s):

High Resolution ◽

Mass Balance ◽

Sea Level ◽

Sea Water ◽

Ice Sheets ◽

Internal Surface ◽

Surface Fluxes ◽

Specific Mass ◽

Mountain Glaciers ◽

Equivalent Time

A high-resolution GCM ECHAM3 T106 was used to simulate the climates of the present and of the future under doubled CO2The ECHAM3 T106 was integrated for an equivalent time of 5 years (1) with the observed SST of the 1980s and (2) with the SST for the 2 × CO2climate generated from the ECHAM1 T21 coupled transient experiment. The main motivation for using the GCM to simulate the mass balance is the level of skill in simulating precipitation and accumulation recently achieved in the high-resolution GCM experiment. The ablation is computed, based on the GCM internal surface fluxes and the temperature/ablation relationship formulated on the Greenland field data. The two ice sheets show very different reactions towards doubling the CO2. As the decrease in accumulation and the increase in ablation in Greenland cause an annual mean specific mass balance of −225 mm (eq. −390 km3), the increase in accumulation and virtually non-melt conditions in Antarctica result in a mean annual specific mass balance of + 23 mm (eq. + 325 km3). The sum of the mass balance on both ice sheets is equivalent to the annual sea-level rise of 0.2 mm. This experiment shows that other mechanisms for sea-level change, such as the thermal expansion of the sea water and the melt of small mountain glaciers, will remain important in the coming century.

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Supra-glacial debris cover changes in the Greater Caucasus from 1986 to 2014

The Cryosphere ◽

10.5194/tc-14-585-2020 ◽

2020 ◽

Vol 14 (2) ◽

pp. 585-598 ◽

Cited By ~ 8

Author(s):

Levan G. Tielidze ◽

Tobias Bolch ◽

Roger D. Wheate ◽

Stanislav S. Kutuzov ◽

Ivan I. Lavrentiev ◽

...

Keyword(s):

High Resolution ◽

Sea Level ◽

Google Earth ◽

Gps Data ◽

Glacier Area ◽

Greater Caucasus ◽

Abstract Knowledge ◽

Covered Area ◽

Debris Cover ◽

Automated Methods

Abstract. Knowledge of supra-glacial debris cover and its changes remain incomplete in the Greater Caucasus, in spite of recent glacier studies. Here we present data of supra-glacial debris cover for 659 glaciers across the Greater Caucasus based on Landsat and SPOT images from the years 1986, 2000 and 2014. We combined semi-automated methods for mapping the clean ice with manual digitization of debris-covered glacier parts and calculated supra-glacial debris-covered area as the residual between these two maps. The accuracy of the results was assessed by using high-resolution Google Earth imagery and GPS data for selected glaciers. From 1986 to 2014, the total glacier area decreased from 691.5±29.0 to 590.0±25.8 km2 (15.8±4.1 %, or ∼0.52 % yr−1), while the clean-ice area reduced from 643.2±25.9 to 511.0±20.9 km2 (20.1±4.0 %, or ∼0.73 % yr−1). In contrast supra-glacial debris cover increased from 7.0±6.4 %, or 48.3±3.1 km2, in 1986 to 13.4±6.2 % (∼0.22 % yr−1), or 79.0±4.9 km2, in 2014. Debris-free glaciers exhibited higher area and length reductions than debris-covered glaciers. The distribution of the supra-glacial debris cover differs between the northern and southern and between the western, central and eastern Greater Caucasus. The observed increase in supra-glacial debris cover is significantly stronger on the northern slopes. Overall, we have observed up-glacier average migration of supra-glacial debris cover from about 3015 to 3130 m a.s.l. (metres above sea level) during the investigated period.

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High-Resolution Coastal Elevation Data: The Key to Planning for Storm Surge and Sea Level Rise

Geospatial Technologies and Homeland Security - The GeoJournal Library ◽

10.1007/978-1-4020-8507-9_11 ◽

2008 ◽

pp. 229-240

Author(s):

Mark Monmonier

Keyword(s):

High Resolution ◽

Sea Level Rise ◽

Sea Level ◽

Storm Surge ◽

Elevation Data ◽

And Sea Level

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High-Resolution Digital Elevation and Bathymetry Model for Tsunami Run-Up and Inundation Simulation in Penang

Journal of Earthquake and Tsunami ◽

10.1142/s179343111941001x ◽

2019 ◽

Vol 13 (05n06) ◽

pp. 1941001

Author(s):

Su Yean Teh ◽

Hock Lye Koh ◽

Yong Hui Lim

Keyword(s):

High Resolution ◽

Indian Ocean ◽

Sea Level ◽

Interpolation Method ◽

Topographic Maps ◽

Seamless Integration ◽

Topographic Data ◽

Digital Elevation ◽

Run Up ◽

Tsunami Run Up

Many beaches in Penang island were severely inundated by the 26 December 2004 Indian Ocean mega tsunami with 57 deaths recorded. It is anticipated that the next big tsunami will cause even more damages to beaches in Penang. Hence, developing community resilience against the risks of the next tsunami is essential. Resilience entails many interlinked components, beginning with a good understanding of the inundation scenarios critical to community evacuation and resilience preparation. Inundation scenarios are developed from tsunami simulations involving all three phases of tsunami generation, propagation and run-up. Accurate and high-resolution bathymetric–topographic maps are essential for simulations of tsunami wave inundation along beaches. Bathymetric maps contain information on the depths of landforms below sea level while topographic maps reveal the elevation of landforms above sea level. Bathymetric and topographic datasets for Malaysia are, however, currently not integrated and are available separately and in different formats, not suitable for inundation simulations. Bathymetric data are controlled by the National Hydrographic Centre (NHC) of the Royal Malaysian Navy while topographic data are serviced by the Department of Survey and Mapping Malaysia (JUPEM). It is highly desirable to have seamless integration of high-resolution bathymetric and topographic data for tsunami simulations and for other scientific studies. In this paper, we develop a robust method for integrating the NHC bathymetric and JUPEM topographic data into a regularly-spaced grid system essential for tsunami simulation. A primary objective of this paper is to develop the best Digital Elevation and Bathymetry Model (DEBM) for Penang based upon the most suitable and accurate interpolation method for integrating bathymetric and topographic data with minimal interpolation errors. We analyze four commonly used interpolation methods for generating gridded topographic and bathymetric surfaces, namely (i) Kriging, (ii) Multiquadric (MQ), (iii) Thin Plate Spline (TPS) and (iv) Inverse Distance to Power (IDP). The study illustrated that the Kriging interpolation method produces an integrated bathymetric and topographic surface that best approximates the admiralty nautical chart of Penang essential for tsunami run-up and inundation simulations. Tsunami inundation scenarios critical to risk analysis and mitigation could then be developed using this DEBM for various earthquake scenarios, as presented in this paper for the 2004 Indian Ocean Tsunami.

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00/00074 High-resolution sequence statigraphic analysis and sea-level interpretation of the middle and upper Jurassic strata of the Nyurolskaya depression and vicinity (southeastern West Siberia, Russia)

Fuel and Energy Abstracts ◽

10.1016/0140-6701(00)94869-0 ◽

2000 ◽

Vol 41 (1) ◽

pp. 8

Keyword(s):

High Resolution ◽

Sea Level ◽

West Siberia ◽

Upper Jurassic ◽

And Sea Level

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DETERMINING RESERVOIR CONTINUITY IN THE LAMINARIA FORMATION BY INTEGRATED GEOLOGICAL STUDY

The APPEA Journal ◽

10.1071/aj00019 ◽

2001 ◽

Vol 41 (1) ◽

pp. 415 ◽

Cited By ~ 3

Author(s):

D.C. Barr ◽

A.F. Kennaird ◽

J. Fowles ◽

N.G. Marshall ◽

V.L. Cutten

Keyword(s):

Grain Size ◽

High Resolution ◽

Sea Level ◽

Clay Content ◽

Coarse Grained ◽

Log Data ◽

Reservoir Performance ◽

Subaqueous Dunes ◽

Reservoir Sandstones ◽

Reservoir Potential

A recent geological study, integrating sedimentological core-derived descriptions with ichnofacies, high resolution biostratigraphy and wireline log data, establishes the lateral continuity of reservoir sandstones in the Laminaria Formation. By defining a hierarchy of bedding surfaces and correlating this hierarchy with major correlation surfaces, and lateral and vertical facies patterns, it was possible to identify genetically related sediment packages between 12 wells in the study area.The Laminaria Formation is interpreted to have been deposited on a tide and storm-influenced marine shelf, and was strongly influenced by fluctuations in sea level. The formation consists of a series of progradational parasequences, each dominated by good quality, fine- to medium-grained sandstone. These sandstones are believed to have formed as subaqueous dunes or sand banks, exhibiting blanket-like geometry over much of the area. Several sandstones are capped by thin, intraclast-rich layers that mark transgressive surfaces of erosion. These surfaces can be traced across the study area and, therefore, act as important correlative markers.Evidence of gradual transgression, which ultimately led to the drowning of the system, is seen near the top of the formation. Clay content increases upward, while grain size and bedding thickness generally decrease. However, several thin, laterally extensive, medium- to coarse-grained sandstones exist, improving reservoir potential in this part of the formation.The results of this study are being used to estimate reserves and assess reservoir performance, and will serve as a basis for future geological and petrophysical modelling work.

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Integration of HF Radar Observations for an Enhanced Coastal Mean Dynamic Topography

Frontiers in Marine Science ◽

10.3389/fmars.2020.588713 ◽

2020 ◽

Vol 7 ◽

Author(s):

Ainhoa Caballero ◽

Sandrine Mulet ◽

Nadia Ayoub ◽

Ivan Manso-Narvarte ◽

Xabier Davila ◽

...

Keyword(s):

High Resolution ◽

Sea Level ◽

Satellite Data ◽

Coastal Areas ◽

Hf Radar ◽

Global Ocean ◽

Dynamic Topography ◽

Mean Dynamic Topography ◽

Radar Measurements

Satellite altimeters provide continuous information of the sea level variability and mesoscale processes for the global ocean. For estimating the sea level above the geoid and monitoring the full ocean dynamics from altimeters measurements, a key reference surface is needed: The Mean Dynamic Topography (MDT). However, in coastal areas, where, in situ measurements are sparse and the typical scales of the motion are generally smaller than in the deep ocean, the global MDT solutions are less accurate than in the open ocean, even if significant improvement has been done in the past years. An opportunity to fill in this gap has arisen with the growing availability of long time-series of high-resolution HF radar surface velocity measurements in some areas, such as the south-eastern Bay of Biscay. The prerequisite for the computation of a coastal MDT, using the newly available data of surface velocities, was to obtain a robust methodology to remove the ageostrophic signal from the HF radar measurements, in coherence with the scales resolved by the altimetry. To that end, we first filtered out the tidal and inertial motions, and then, we developed and tested a method that removed the Ekman component and the remaining divergent part of the flow. A regional high-resolution hindcast simulation was used to assess the method. Then, the processed HF radar geostrophic velocities were used in synergy with additional in situ data, altimetry, and gravimetry to compute a new coastal MDT, which shows significant improvement compared with the global MDT. This study showcases the benefit of combining satellite data with continuous, high-frequency, and synoptic in situ velocity data from coastal radar measurements; taking advantage of the different scales resolved by each of the measuring systems. The integrated analysis of in situ observations, satellite data, and numerical simulations has provided a further step in the understanding of the local ocean processes, and the new MDT a basis for more reliable monitoring of the study area. Recommendations for the replicability of the methodology in other coastal areas are also provided. Finally, the methods developed in this study and the more accurate regional MDT could benefit present and future high-resolution altimetric missions.

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Storm Surge Inundation Analysis with Consideration of Building Shape and Layout at Ise Bay by Maximum Potential Typhoon

Journal of Marine Science and Engineering ◽

10.3390/jmse8121024 ◽

2020 ◽

Vol 8 (12) ◽

pp. 1024

Author(s):

Masaki Nimura ◽

Shuzo Nishida ◽

Koji Kawasaki ◽

Tomokazu Murakami ◽

Shinya Shimokawa

Keyword(s):

Global Warming ◽

High Resolution ◽

Sea Level ◽

Storm Surge ◽

High Velocity ◽

High Tide ◽

Disaster Mitigation ◽

Ise Bay ◽

Building Shape ◽

Tide Level

Global warming is feared to cause sea-level rise and intensification of typhoons, and these changes will lead to an increase in storm surge levels. For that reason, it is essential to predict the inundation areas for the maximum potential typhoon and evaluate the disaster mitigation effect of seawalls. In this study, we analyzed storm surge inundation of the inner part of Ise Bay (coast of Aichi and Mie Prefecture, Japan) due to the maximum potential typhoon in the future climate with global warming. In the analysis, a high-resolution topographical model was constructed considering buildings’ shape and arrangement and investigated the inundation process inside the seawall in detail. The results showed that buildings strongly influence the storm surge inundation process inside the seawall, and a high-velocity current is generated in some areas. It is also found that closing the seawall door delays the inundation inside the seawall, but the evacuation after inundation is more difficult under the seawall doors closed condition than opened condition when the high tide level exceeds the seawall.

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