TY - CHAP
T1 - Rock magnetic characterization through an intact sequence of oceanic crust, IODP Hole 1256D
AU - Herrero-Bervera, E.
AU - Acton, G.
AU - Krasá, D.
AU - Rodriguez, S.
AU - Dekkers, M.J.
PY - 2011
Y1 - 2011
N2 - Coring at Site 1256 (6.736◦N, 91.934◦W, 3635 m water depth) during Ocean Drilling
Program (ODP) Leg 206 and Integrated Ocean Drilling Program (IODP) Expeditions
309 and 312 successfully sampled a complete section of in situ oceanic crust, including
sediments of Seismic Layer 1, lavas and dikes of Layer 2, and the uppermost
gabbros of Layer 3. The crust at this site was generated by superfast seafloor spreading
(>200 mm/yr full spreading rate) along the East Pacific Rise some 15 Ma ago.
One goal of drilling a complete oceanic crust section is to determine the source of
marine magnetic anomalies. For crust generated by fast seafloor spreading, is the
signal dominated by the upper extrusive layer, do the sheeted dikes play any role,
how significant is the magnetic signal from gabbros relative to that at slow spreading
centers and what is the timing of acquisition of the magnetization? To address
these questions, we have made a comprehensive set of rock magnetic and paleomagnetic
measurements that extend through the igneous interval. Continuous downhole
variations in magnetic grain size, coercivity, mass-normalized susceptibility, Curie
temperatures, and composition have been mapped. Compositionally, we have found
that the iron oxides vary from being titanium-rich titanomagnetite (TM60), which
are commonly partially oxidized to titanomaghemites, to titanium-poor magnetite
as determined semi-quantitatively from Curie temperature analyses and microscopy
studies. Skeletal titanomagnetite with varying degrees of alteration is the most common
magnetic mineral throughout the section and is often bordered by large iron
sulfide grains. The low-Ti magnetite or stoichiometric magnetite is present mainly
in the dikes and gabbros and is associated with higher Curie temperatures (550◦C
to near 580◦C) and higher coercivities than in the extrusive section. Magnetic grain
sizes predominantly fall in the pseudo single domain (PSD) grain size region on Day
diagrams, with only a small numbers of samples falling within the single domain (SD) or multi-domain (MD) regions. Overall the magnetic properties of this
hole are strongly influenced by post-emplacement alteration, particularly the lower
part of the section from the gabbros up into the transition zone. Some of the more
prominent features of the rock magnetic data are the gradual increase in Curie
temperatures with depth from about 200–350◦C at the top of the extrusives to about
425◦C just above the transition zone, the more variable Curie temperatures and less
variable susceptibility and coercivity of remanence in the upper half of the extrusives
relative to the lower half the near constant composition (x = 0.6) and oxidation
(z = 0.6) of the iron oxide grains (>5νm) in the extrusives (Chapter 12 this volume),
the highly irreversible nature of thermomagnetic curves in the extrusives, in which
the cooling curve has Curie temperatures higher (generally > 500◦C) than indicated
by the heating curve, the abrupt change in rock magnetic properties across the
transition zone, particularly the Curie temperature., a somewhat finer grain size and
increased intensity in the sheeted dike zone relative to the extrusives and gabbros,
and the nearly constant Curie temperatures (530 and 585◦C) for the dikes and
gabbros
AB - Coring at Site 1256 (6.736◦N, 91.934◦W, 3635 m water depth) during Ocean Drilling
Program (ODP) Leg 206 and Integrated Ocean Drilling Program (IODP) Expeditions
309 and 312 successfully sampled a complete section of in situ oceanic crust, including
sediments of Seismic Layer 1, lavas and dikes of Layer 2, and the uppermost
gabbros of Layer 3. The crust at this site was generated by superfast seafloor spreading
(>200 mm/yr full spreading rate) along the East Pacific Rise some 15 Ma ago.
One goal of drilling a complete oceanic crust section is to determine the source of
marine magnetic anomalies. For crust generated by fast seafloor spreading, is the
signal dominated by the upper extrusive layer, do the sheeted dikes play any role,
how significant is the magnetic signal from gabbros relative to that at slow spreading
centers and what is the timing of acquisition of the magnetization? To address
these questions, we have made a comprehensive set of rock magnetic and paleomagnetic
measurements that extend through the igneous interval. Continuous downhole
variations in magnetic grain size, coercivity, mass-normalized susceptibility, Curie
temperatures, and composition have been mapped. Compositionally, we have found
that the iron oxides vary from being titanium-rich titanomagnetite (TM60), which
are commonly partially oxidized to titanomaghemites, to titanium-poor magnetite
as determined semi-quantitatively from Curie temperature analyses and microscopy
studies. Skeletal titanomagnetite with varying degrees of alteration is the most common
magnetic mineral throughout the section and is often bordered by large iron
sulfide grains. The low-Ti magnetite or stoichiometric magnetite is present mainly
in the dikes and gabbros and is associated with higher Curie temperatures (550◦C
to near 580◦C) and higher coercivities than in the extrusive section. Magnetic grain
sizes predominantly fall in the pseudo single domain (PSD) grain size region on Day
diagrams, with only a small numbers of samples falling within the single domain (SD) or multi-domain (MD) regions. Overall the magnetic properties of this
hole are strongly influenced by post-emplacement alteration, particularly the lower
part of the section from the gabbros up into the transition zone. Some of the more
prominent features of the rock magnetic data are the gradual increase in Curie
temperatures with depth from about 200–350◦C at the top of the extrusives to about
425◦C just above the transition zone, the more variable Curie temperatures and less
variable susceptibility and coercivity of remanence in the upper half of the extrusives
relative to the lower half the near constant composition (x = 0.6) and oxidation
(z = 0.6) of the iron oxide grains (>5νm) in the extrusives (Chapter 12 this volume),
the highly irreversible nature of thermomagnetic curves in the extrusives, in which
the cooling curve has Curie temperatures higher (generally > 500◦C) than indicated
by the heating curve, the abrupt change in rock magnetic properties across the
transition zone, particularly the Curie temperature., a somewhat finer grain size and
increased intensity in the sheeted dike zone relative to the extrusives and gabbros,
and the nearly constant Curie temperatures (530 and 585◦C) for the dikes and
gabbros
U2 - 10.1007/978-94-007-0323-0_11
DO - 10.1007/978-94-007-0323-0_11
M3 - Chapter
SN - 978-94-007-0322-3
T3 - IAGA Special Sopron Book
SP - 153
EP - 168
BT - The Earth's Magnetic Interior
A2 - Petrovsky, E.
A2 - Herrero-Bervera, E.
A2 - Harinarayana, T.
A2 - Ivers, D.
PB - Springer
ER -