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Komplexní geofyzikální průzkum pro archeologické účely v prostoru Zámecké zahrady v Teplicích / Complex geophysical survey for archaeological purposes in the area of the Chateau Garden in TepliceVošvrdová, Eliška January 2021 (has links)
This diploma thesis deals with application of geophysical methods in archeology, in the first part by an overview of the methods used for localization and analysis of historical anthropogenic cavities for archeological purposes. In the second part of the thesis, the application of selected methods on a specific locality is described. The initial part of the work summarizes information regarding the geophysical localization of historical anthropogenic cavities, thus underground objects, created by human activity. Their general and physical characteristics are introduced, as well as the specifics associated with their geophysical search, and the principles for choosing a method based on the parameters of the given object. The most frequently used methods in the survey of anthropogenic cavities include gravimetry, geoelectrical DC resistivity methods (symmetric resistivity profiling and electrical resistivity tomography), electromagnetic methods (ground penetrating radar and dipole electromagnetic profiling) and thermometry. A fundamental part of the diploma thesis is devoted to a comprehensive geophysical examination of the archaeological site. The location of the exploration work was the Chateau Garden in Teplice (North Bohemia), below which there are historical cellars. Ground penetrating radar,...
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Lacustrine records of Holocene climate and environmental change from the Lofoten Islands, NorwayBalascio, Nicholas L 01 January 2011 (has links)
Lakes sediments from the Lofoten Islands, Norway, can be used to generate well resolved records of past climate and environmental change. This dissertation presents three lacustrine paleoenvironmental reconstructions that show evidence for Holocene climate changes associated with North Atlantic climate dynamics and relative sea-level variations driven by glacio-isostatic adjustment. This study also uses distal tephra deposits (cryptotephra) from Icelandic volcanic eruptions to improve the chronologies of these reconstructions and explores new approaches to crypto-tephrochronology. Past and present conditions at Vikjordvatnet, Fiskebølvatnet, and Heimerdalsvatnet were studied during four field seasons conducted from 2007–2010. Initially, each lake was characterized by measuring water column chemistry, logging annual temperature fluctuations, and conducting bathymetric and seismic surveys. Sediment cores were then collected and analyzed using multiple techniques, including: sediment density, magnetic susceptibility, loss-on-ignition, total carbon and nitrogen, δ13C and δ 15N of organic matter, and elemental compositions acquired by scanning X-ray fluorescence. Chronologies were established using radiocarbon dating and tephrochronology. A 13.8 cal ka BP record from Vikjordvatnet provides evidence for glacial activity during the Younger Dryas cold interval and exhibits trends in Ti, Fe, and organic content during the Holocene that correlate with regional millennial-scale climate trends and provide evidence for more rapid events. A 9.7 cal ka BP record from Fiskebølvatnet shows a strong signal of sediment inwashing likely driven by local geomorphic conditions, although there is evidence that increased inwashing at the onset of the Neoglacial could have been associated with increased precipitation. Heimerdalsvatnet provides a record of relative sea-level change. A 7.8 cal ka BP sedimentary record reflects changes in salinity and water column conditions as the lake was isolated and defines sea-level regression following the Tapes transgression. Cryptotephra horizons were identified in sediments of Heimerdalsvatnet, Vikjordvatnet, and Sverigedalsvatn. They were also found in a Viking-age boathouse excavated along the shore of Inner Borgpollen. These include the GA4-85, BIP-24a, SILK-N2, Askja, 860 Layer B, Hekla 1158, Hekla 1104, Vedde Ash, and Saksunarvatn tephra. This research project also explored the use of scanning XRF to locate cryptotephra in lacustrine sediments and presents experimental results of XRF scans of tephra-spiked synthetic sediment cores.
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Arctic lake sediments as records of climate change using rock magnetic properties and paleomagnetic dataMurdock, Kathryn J 01 January 2013 (has links)
Two lakes were studied in detail for rock magnetic properties: Lake El'gygytgyn, a crater lake formed 3.6Ma in the Far Eastern Russian Arctic, and Heimerdalsvatnet, a Holocene coastal lake located in the Lofotens off the coast of northern Norway. These two lakes have vastly different environmental histories, the former a terrestrial lake formed from a meteor impact and never covered by continental ice sheets whereas the latter went from a coastal marine setting to a completely lacustrine environment due to isostatic rebound and sea level fluctuations. Their differences are considerable, however they provide the opportunity to compare Arctic lake systems to discern similarities and differences in their magnetic properties for application to future climatic investigations. Paleomagnetic measurements and down-core magnetic susceptibility were performed at the GFZ German Research Centre for Geosciences in Potsdam for Lake El'gygytgyn and at the Laboratoire de paleomagnétisme sédimentaire at ISMER for Heimerdalsvatnet. Rock magnetic properties were measured at the University of Massachusetts Amherst, Institute of Rock Magnetism, and/or Trinity College. These measurements included: magnetic susceptibility, hysteresis parameters, Curie temperatures, and low-temperature magnetic behavior. Imaging of magnetite grains was also performed. Magnetic susceptibility measurements in Lake El'gygytgyn suggested a correlation between glacials (interglacials) and low (high) susceptibility. The large range in susceptibility indicated there could be magnetite dissolution. The first study supported this hypothesis with evidence at low temperatures (10-35K) of minerals such as siderite, rhodochrosite, and/or vivianite which could form from iron released during dissolution. Marine Isotope Stage 31 was investigated for rock magnetic properties that could continue to support or oppose findings from the first study. It was determined the presence of siderite only occurred in interglacial periods whereas its absence (and probably presence of vivianite) related to glacial periods, indicating more reduced environments during glacials versus interglacials. Heimerdalsvatnet paleomagnetic data from the marine environment (lower part of the core) revealed scattered directions whereas data from the upper part of the core (lacustrine environment) showed better consistency. Rock magnetic measurements showed some variation downcore, however the measurements are not dependable since the amount of paramagnetic material was overwhelming compared to any ferromagnetic mineral present.
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The Form and Extent of the Grenville Front Tectonic Zone in Proximity to Coniston, Ontario as Defined by Aeromagnetic and Paleomagnetic Studies of the Sudbury Olivine Diabase Dikes.Manning, Susanne 04 1900 (has links)
<p> Geophysical studies of the northwest trending Sudbury olivine
diabase dikes, to the south of Coniston, Ontario establish a
deformation zone, within the Southern province up to 10 km from the
Grenville Front. Paleomagnetics reveal two directional groups
within the dikes; those with a NRM direction of 300°/32°
representing the primary magnetization of the dikes and those dikes
with a Grenville overprint direction of 116°/56°. The deviation in
direction of the two groups, in relation to previous studies
(Palmer et al., 1977) is interpreted to be due to fault block
movement. Aeromagnetics reveal extensive ductile and brittle
deformation in the dikes as they approach the front. The general
orientation of deformation is to the northeast. </p> / Thesis / Bachelor of Science (BSc)
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Before Biology: Geologic Habitability and Setting the Chemical and Physical Foundations for LifeUnterborn, Cayman Thomas 10 August 2016 (has links)
No description available.
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Changes in the Marine-Terminating Glaciers of Central East Greenland, 2000-2010, and Potential Connections to Ocean CirculationWalsh, Kaitlin M. 25 July 2011 (has links)
No description available.
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Interpretation of the horizontal loop : EM survey with multiple separation.Kim, Kwang-Kook January 1973 (has links)
No description available.
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Prospecting with multi-frequency telluricsDoborzynski, Zbigniew Bronislaw January 1974 (has links)
No description available.
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A Rayleigh wave dispersion technique for geoexploration /Yu, Thiann-R., 1933- January 1974 (has links)
No description available.
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EAC Guidelines for the use of Geophysics in Archaeology: Questions to Ask and Points to Consider.Schmidt, Armin R., Linford, P., Linford, N., David, A., Gaffney, Christopher F., Sarris, A., Fassbinder, J. January 2015 (has links)
These guidelines provide an overview of the issues to
be considered when undertaking or commissioning
geophysical survey in archaeology. As every project diff ers
in its requirements (e.g. from fi nding sites to creating
detailed maps of individual structures) and variations in
geological and environmental conditions lead to diff erent
geophysical responses, there is no single ‘best’ survey
technique or methodology. Th is guide, in its European
approach, highlights the various questions to be asked
before a survey is undertaken. It does not provide recipebook
advice on how to do a geophysical survey or a tick
list of which technique is suitable under what conditions.
Experienced archaeological geophysicists should be
consulted to address the questions that are being posed.
Using geophysical techniques and methods inappropriately
will lead to disappointment and may, ultimately, result
in archaeologists not using them at all. “If all you have is
a hammer (or magnetometer), driving a screw becomes
impossible”.
Especially in the American literature the term ‘remote
sensing’ is oft en used to describe geophysical as well as
air and space based exploration of underground features
(e.g. Wiseman and El-Baz 2007). By contrast, and in line
with European traditions, a clear distinction is made
here between ground-based geophysical techniques and
remote sensing techniques. Th is is based on the imaging
principles underlying the respective technologies. Ground
based systems usually collect one spatially registered data
sample from each sensor location (e.g. a single reading
for each magnetometer, or a single trace from each GPR
antenna). Remote sensing techniques, by contrast, collect
spatially resolved data from a whole area of investigation
from each sensor location, using either the system’s optical
aperture (e.g. photography) or a scanning device (e.g. laser
sampling).
These guidelines are based on the experience of the authors
in archaeological geophysics and infl uenced by various
published sources.
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