Biblioteca Digital

An environmental magnetic study, sedimentological and numerical methods around Tauranga Harbour, New Zealand

**Autoria(s):** Badesab, Firoz Kadar; von Dobeneck, Tilo; Bryan, Karin R; Müller, Hendrik; Briggs, Roger M; Frederichs, Thomas; Kwoll, Eva
Cobertura	MEDIAN LATITUDE: -37.534812 * MEDIAN LONGITUDE: 176.100115 * SOUTH-BOUND LATITUDE: -37.664270 * WEST-BOUND LONGITUDE: 175.955208 * NORTH-BOUND LATITUDE: -37.397000 * EAST-BOUND LONGITUDE: 176.248910
Data(s)	25/02/2012
Resumo	Magnetic iron minerals are widespread and indicative sediment constituents in estuarine, coastal and shelf systems. We combine environmental magnetic, sedimentological and numerical methods to identify magnetite-enriched placer-like zones in a complex coastal system and delineate their formation mechanisms. Magnetic susceptibility and remanence measurements on 245 surficial sediment samples collected in and around Tauranga Harbour, the largest barrier-enclosed tidal estuary of New Zealand, reveal several discrete enrichment zones controlled by local hydrodynamic conditions. Active magnetite enrichment takes place in tidal channels, which feed into two coast-parallel nearshore magnetite-enriched belts centered at water depths of 6-10 m and 10-20 m. A close correlation between magnetite content and magnetic grain size was found, where higher susceptibility values are associated within coarser magnetic crystal sizes. Two key mechanisms for magnetite enrichment are identified. First, tide-induced residual currents primarily enable magnetite enrichment within the estuarine channel network. A coast-parallel, fine sand magnetite enrichment belt in water depths of less than 10 m along the barrier island has a strong decrease in magnetite content away from the southern tidal inlet and is apparently related to active coast-parallel transport combined with mobilizing surf zone processes. A second, less pronounced, but more uniform magnetite enrichment belt at 10-20 m water depth is composed of non-mobile, medium-coarse-grained relict sands, which have been reworked during post-glacial sea level transgression. We demonstrate the potential of magnetic methods to reveal and differentiate coastal magnetite enrichment patterns and investigate their formative mechanisms.
Formato	application/zip, 7 datasets
Identificador	https://doi.pangaea.de/10.1594/PANGAEA.807896 doi:10.1594/PANGAEA.807896
Idioma(s)	en
Publicador	PANGAEA
Relação	Badesab, Firoz Kadar (2012): Magnetic mineral enrichment and transport in coastal environments: Tauranga Harbour, Northeastern, New Zealand. PhD Thesis, Elektronische Dissertationen an der Staats- und Universitätsbibliothek Bremen, Germany, 116 pp, urn:nbn:de:gbv:46-00102927-10
Direitos	CC-BY: Creative Commons Attribution 3.0 Unported Access constraints: unrestricted
Fonte	Supplement to: Badesab, Firoz Kadar; von Dobeneck, Tilo; Bryan, Karin R; Müller, Hendrik; Briggs, Roger M; Frederichs, Thomas; Kwoll, Eva (2012): Formation of magnetite-enriched zones in and offshore of a mesotidal estuarine lagoon: An environmental magnetic study of Tauranga Harbour and Bay of Plenty, New Zealand. Geochemistry, Geophysics, Geosystems, 13, doi:10.1029/2012GC004125
Palavras-Chave	#0.412-0.375 µm; 0.452-0.412 µm; 0.496-0.452 µm; 0.545-0.496 µm; 0.598-0.545 µm; 0.656-0.598 µm; 0.721-0.656 µm; 0.791-0.721 µm; 0.868-0.791 µm; 0.948-1.041 mm; 0.953-0.868 µm; 1.041-1.143 mm; 1.047-0.953 µm; 1.143-1.255 mm; 1.149-1.047 µm; 1.255-1.377 mm; 1.261-1.149 µm; 1.377-1.512 mm; 1.384 -1.261 µm; 1.512-1.66 mm; 1.520-1.384 µm; 1.668-1.520 µm; 1.822-1.660 mm; 1.832-1.668 µm; 10.78-9.818 µm; 10%; 101.1-92.09 µm; 11.83-10.78 µm; 111.0-101.1 µm; 12.99-11.83 µm; 121.8-111.0 µm; 133.7-121.8 µm; 14.26-12.99 µm; 146.8-133.7 µm; 15.65-14.26 µm; 161.2-146.8 µm; 17.18-15.65 µm; 176.9 -161.2 µm; 18.86-17.18 µm; 194.2 -176.9 µm; 2.010-1.832 µm; 2.207-2.010 µm; 2.423-2.207 µm; 2.660-2.423 µm; 2.920-2.660 µm; 20.70-18.86 µm; 2000-1822 µm; 213.2-194.2 µm; 213.2-234.1 µm; 22.73-20.70 µm; 234.1-256.8 µm; 24.95-22.73 µm; 256.8-282.1 µm; 27.38-24.95 µm; 282.1-309.6 µm; 3.205-2.920 µm; 3.519-3.205 µm; 3.862-3.519 µm; 30.07-27.38 µm; 309.6-339.8 µm; 33.01-30.07 µm; 339.8-373.1 µm; 36.24-33.01 µm; 373.1-409.6 µm; 39.77-36.24 µm; 4.240-3.863 µm; 4.655-4.240 µm; 409.6-449.7 µm; 43.67-39.78 µm; 449.7-493.6 µm; 47.94-43.67 µm; 493.6-541.9 µm; 5.110-4.655 µm; 5.610-5.110 µm; 50% average; 52.62-47.94 µm; 541.9-594.9 µm; 57.77-52.62 µm; 594.9-653 µm; 6.158-5.611 µm; 6.761-6.158 µm; 63.41-57.77 µm; 653.0-716.9 µm; 69.62-63.41 µm; 7.421-6.760 µm; 716.9-786.9 µm; 76.42-69.61 µm; 786.9-863.9 µm; 8.147-7.421 µm; 8.943-8.147 µm; 83.89-76.42 µm; 863.9-948.2 µm; 9.818-8.943 µm; 90%; 92.09-83.90 µm; Anhysteretic remanent magnetization; ARM; ARM/IRM; Bartington MS2B bulk sensor; Beckman Coulter Laser diffraction particle size analyzer LS 200; Center for Marine Environmental Sciences; chi; Comment; Critical velocity; Depth; DEPTH, sediment/rock; DEPTH, water; Depth water; Distance; Event; low frequency 0.47 kHz; Magnetometer, cryogenic, pass-through, 2G Enterprises 755 R; MARUM; Profile; Sea bed orbital velocity; Size fraction 0.412-0.375 µm; Size fraction 0.452-0.412 µm; Size fraction 0.496-0.452 µm; Size fraction 0.545-0.496 µm; Size fraction 0.598-0.545 µm; Size fraction 0.656-0.598 µm; Size fraction 0.721-0.656 µm; Size fraction 0.791-0.721 µm; Size fraction 0.868-0.791 µm; Size fraction 0.948-1.041 mm; Size fraction 0.953-0.868 µm; Size fraction 1.041-1.143 mm; Size fraction 1.047-0.953 µm; Size fraction 1.143-1.255 mm; Size fraction 1.149-1.047 µm; Size fraction 1.255-1.377 mm; Size fraction 1.261-1.149 µm; Size fraction 1.377-1.512 mm; Size fraction 1.384 -1.261 µm; Size fraction 1.512-1.660 mm; Size fraction 1.520-1.384 µm; Size fraction 1.668-1.520 µm; Size fraction 1.822-1.660 mm; Size fraction 1.832-1.668 µm; Size fraction 10.78-9.818 µm; Size fraction 101.1-92.09 µm; Size fraction 11.83-10.78 µm; Size fraction 111.0-101.1 µm; Size fraction 12.99-11.83 µm; Size fraction 121.8-111.0 µm; Size fraction 133.7-121.8 µm; Size fraction 14.26-12.99 µm; Size fraction 146.8-133.7 µm; Size fraction 15.65-14.26 µm; Size fraction 161.2-146.8 µm; Size fraction 17.18-15.65 µm; Size fraction 176.9 -161.2 µm; Size fraction 18.86-17.18 µm; Size fraction 194.2 -176.9 µm; Size fraction 2.000-1.822 mm; Size fraction 2.010-1.832 µm; Size fraction 2.207-2.010 µm; Size fraction 2.423-2.207 µm; Size fraction 2.660-2.423 µm; Size fraction 2.920-2.660 µm; Size fraction 20.70-18.86 µm; Size fraction 213.2-194.2 µm; Size fraction 213.2-234.1 µm; Size fraction 22.73-20.70 µm; Size fraction 234.1-256.8 µm; Size fraction 24.95-22.73 µm; Size fraction 256.8-282.1 µm; Size fraction 27.38-24.95 µm; Size fraction 282.1-309.6 µm; Size fraction 3.205-2.920 µm; Size fraction 3.519-3.205 µm; Size fraction 3.862-3.519 µm; Size fraction 30.07-27.38 µm; Size fraction 309.6-339.8 µm; Size fraction 33.01-30.07 µm; Size fraction 339.8-373.1 µm; Size fraction 36.24-33.01 µm; Size fraction 373.1-409.6 µm; Size fraction 39.77-36.24 µm; Size fraction 4.240-3.863 µm; Size fraction 4.655-4.240 µm; Size fraction 409.6-449.7 µm; Size fraction 43.67-39.78 µm; Size fraction 449.7-493.6 µm; Size fraction 47.94-43.67 µm; Size fraction 493.6-541.9 µm; Size fraction 5.110-4.655 µm; Size fraction 5.610-5.110 µm; Size fraction 52.62-47.94 µm; Size fraction 541.9-594.9 µm; Size fraction 57.77-52.62 µm; Size fraction 594.9-653.0 µm; Size fraction 6.158-5.611 µm; Size fraction 6.761-6.158 µm; Size fraction 63.41-57.77 µm; Size fraction 653.0-716.9 µm; Size fraction 69.62-63.41 µm; Size fraction 7.421-6.760 µm; Size fraction 716.9-786.9 µm; Size fraction 76.42-69.61 µm; Size fraction 786.9-863.9 µm; Size fraction 8.147-7.421 µm; Size fraction 8.943-8.147 µm; Size fraction 83.89-76.42 µm; Size fraction 863.9-948.2 µm; Size fraction 9.818-8.943 µm; Size fraction 92.09-83.90 µm; Susceptibility, specific; u; Ucr; Ucr 150 µm; Ucr 400 µm
Tipo	Dataset

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