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Geometry and composition of ice banks in a macrotidal channelBlack, CarolAnne 17 May 2013 (has links)
Large ice blocks containing enough sediment to be denser than sea water form in the Minas Basin of the Bay of Fundy. The timing of ice block formation and ice block composition were monitored to improve understanding of the potential threat to tidal power generators posed by collision with ice blocks. Large blocks are produced from ice cliffs that form when anchored ice obstructs tidal channels and decreases flow speed. Decreased flow causes the channel cross-sectional area to decrease. In 2012, the Kennetcook River cross- sectional area decreased by 21% due to the formation of ice cliffs. Large ice blocks separated from the walls during the two spring tides following a 20-day time lag of the minimum air temperature. Ten percent of sampled ice blocks were denser than freshwater. Four of twelve ice cores collected from the ice cliffs along the Kennetcook River contained enough sediment to become denser than seawater.
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SEASONAL VARIABILITY OF TOTAL SUSPENDED MATTER IN MINAS BASIN, BAY OF FUNDYTao, Jing 05 July 2013 (has links)
Total suspended matter (TSM) concentrations were derived from ocean colour imagery (MERIS data) in Minas Basin. Analysis of time series of TSM in 1-km2 pixel boxes throughout the Basin revealed an annual cycle in TSM in most parts of the Basin. Higher TSM of up to 85 g/m3 was observed in late-winter (February - March), and lower TSM of 5-10 g/m3 characterized late-summer (July - August). The largest annual variation occurred in the centre of Basin, and the smallest variation occurred in shallow areas. Satellite-derived TSM were compared to predictions using the Delft3D model. Increasing model erosion rate in winter relative to summer was necessary to improve agreement between model and satellite-derived TSM. In comparison with the satellite-derived estimates, the model underestimated TSM in shallow areas in summer and overestimated it in winter. This discrepancy is likely due to inaccurate satellite-derived TSM in shallow, high concentration areas of the Basin.
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Analysis Of Microtextures On Quartz Sand Grains Of Triassic Age, From The Minas Basin - Cobequid Bay Area (Bay of Fundy), Nova ScotiaDavis, Patricia Marian 05 1900 (has links)
<p> Triassic sandstones form rapidly eroding cliffs around much
of the Minas Basin, Nova Scotia. The sand eroded from these cliffs
is one major source of the modern intertidal sands. Wave erosion of
the cliffs locally produces a small sand beach at the high tide level. </p>
<p> Eight samples were examined using the Scanning Electron Microscope:
two from the Triassic sandstones, and six from the high-tide
beach below the cliffs. All samples contained rounded, as well as
subrounded and subangular, quartz grains in the 0.5 - 1.00 mm size fraction. As the samples originated in the cliffs, abrasion by strong tidal currents cannot account for the rounded grain shape. </p>
<p> All grains studied had suffered some degree of diagenesis in
the form of a precipitation coat. This was generally thicker on the
rounded grains than on the more angular ones. The Triassic sandstone grains generally illustrated upturned plates, semiparallel steps,
conchoidal breaks and a fine V-shaped pattern. The high beach grains illustrated upturned plates, V-shaped patterns, conchoidal breaks, greater rounding of featu res present and arc-shaped steps. Wehrfritz (1973) studied quartz grains from intertidal sand bars in the Minas Basin. He concluded that grains were considerably rounded by intertidal processes, and the frequency of V-shapes increased with grain
roundness. </p>
<p> Although some rounding of the beach sands was inherited, wave and tidal action aided in rounding the features further. The initial rounding of the sand grains within the sandstones may have occurred during periods in the Triassic when they were exposed to wind or reworked in the lakes. </p> / Thesis / Bachelor of Arts (BA)
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